Safety and Colonization of Two Novel virG(icsA)-based Live Shigella sonnei Vaccine Strains in Rhesus Macaques (Macaca mulatta)

Shigella are gram-negative bacterium that cause bacillary dysentery (shigellosis). Symptoms include diarrhea and discharge of bloody mucoid stools, accompanied by severe abdominal pain, nausea, vomiting, malaise, and fever. Persons traveling to regions with poor sanitation and crowded conditions become particularly susceptible to shigellosis. Currently a vaccine for Shigella has not been licensed in the United States, and the organism quickly becomes resistant to medications. During the past 10 y, several live attenuated oral Shigella vaccines, including the strain WRSS1, have been tested in humans with considerable success. These Phase I vaccines lack the gene for the protein VirG also known as IcsA, which enables the organism to disseminate in the host target tissue. However, 5% to 20% of the vaccinated volunteers developed mild fever and brief diarrhea, and the removal of additional virulence-associated genes from the vaccine strain may reduce or eliminate these side effects. We administered 2 Shigella sonnei vaccines, WRSs2 and WRSs3, along with WRSS1 to compare their rates of colonization and clinical safety in groups of 5 rhesus macaques. The primate model provides the most physiologically relevant animal system to test the validity and efficacy of vaccine candidates. In this pilot study using a gastrointestinal model of infection, the vaccine candidates WRSs2 and WRSs3, which have additional deletions in the enterotoxin and LPS modification genes, provided better safety and comparable immunogenicity to those of WRSS1.Abbreviations: IcsA, intercellular spread protein A (VirG protein); Ipa, invasion plasmid antigen; LPS, lipopolysaccharideVarious species of Shigella cause bacillary dysentery, also known as shigellosis, in humans and other primates.^{1,18,31,37,49} Symptoms include diarrhea, with various degrees of mucus and hematochezia, accompanied by severe abdominal pain, nausea, vomiting, malaise, and fever. Shigella is a gram-negative bacterium whose genomic sequence is very similar to that of Escherichia coli and is phylogenetically considered a pathotype of E. coli.²³ Shigella infections are spread by the fecal–oral route through the consumption of contaminated food and water or by mechanical vectors such as insects. Persons traveling in areas with poor sanitation and crowded conditions become particularly susceptible to such diseases.^2,39,48,56 In colonies of research macaques, Shigella infections are spread by the fecal–oral route, originating from addition of animals that are asymptomatic carriers, either from the wild or from other colonies.^1,55 Currently no Shigella vaccine has been licensed in the United States, although several are under development.^{25,32,35,38,54} Antibiotics are used as treatment therapy, but many Shigella isolates are multidrug-resistant, increasing the need for a preventive vaccine for travelers, military personnel, and children in endemic areas.^{16,34,41,44,57} Rhesus macaques represent an excellent model for studying Shigella because primates are the only known animal model that simulate natural human infection, including dysentery after oral challenge.^{11-13,17,28,40,47,46} Other animal models, such as the mouse pulmonary model and the guineapig ocular and intranasal models, mimic specific, isolated steps in Shigella pathogenesis.^14,19,26There are 4 major serogroups of Shigella and one or more serotypes within each serogroup. This classification is based on antigenic differences in the O-antigen polysaccharide component of the outer membrane-associated lipopolysaccharide (LPS). Estimates from the Centers for Disease Control (Atlanta, GA) indicate that approximately 400,000 cases of shigellosis occur in the US annually, with an estimated 165 million cases worldwide each year.²² These occur predominantly in developing countries, where the population most affected is children younger than 5 y.²²Various in vitro cell culture models of infection, as well as studies in animal models including gastrointestinal infection in nonhuman primates, have contributed to the current understanding of Shigella pathogenesis.^4,42 Shigella organisms target the distal region of the colon and rectum, where the bacteria are captured by specialized M-cells located within the follicle-associated epithelium. The M-cells deliver bacterial antigens, which include bacterial LPS and invasion plasmid antigen (Ipa) proteins, to the underlying antigen-presenting macrophages and dendritic cells.³⁶ Virulent Shigella strains escape macrophages by a cytotoxic effect, causing release of the bacteria and inflammatory cytokines such as IL1β, TNFα, and IL18. The bacteria then invade adjacent intestinal epithelial cells at the basolateral side, through interaction between bacterial proteins and multiple signaling molecules within the host cell.^36,42Shigella are capable of orchestrating this uptake into nonphagocytic epithelial cells, a process termed invasion, through the secretion of proteins that are highly conserved among all virulent strains. These proteins are encoded by a large, 213-kb plasmid, referred to as the invasion plasmid or the virulence plasmid.^50-52 Each bacterium ultimately is engulfed within an endocytic vacuole. Subsequent lysis of the vacuole sets the bacterium free within the epithelial cell cytoplasm, where it replicates and moves to adjacent epithelial cells, with the help of the intercellular spread (Ics) A protein, also known as VirG.^3,24,45 The VirG(IcsA)-assisted intra- and intercellular spread of the bacteria within the epithelial tissue contributes significantly to the loss of epithelial cell integrity and accompanying tissue injury. Shigella strains with loss of the virG(icsA) gene are significantly attenuated in all animal models of virulence.⁵ Several Shigella vaccine candidates that have undergone Phase 1 clinical trials are principally attenuated due to lack of the VirG(IcsA) protein, these include S. flexneri 2a strain SC602, S. sonnei strain WRSS1, and S. dysenteriae 1 vaccine strain WRSd1.^{5,10,15,21,53}The S. sonnei first-generation vaccine candidate WRSS1 has been tested in several Phase I inpatient and outpatient trials.^15,21,33 WRSS1, like the previous S. flexneri 2a vaccine candidate, SC602, was shown to be safe in Phase I trials when orally administered at a dose of 10³ to 10⁴ CFU.^15,21,33 Both SC602 and WRSS1 colonized well as evidenced by fecal excretion of the vaccine strain for 5 to 7 d. The vigorous immune response seen with both these vaccine candidates was correlated with the robust colonization. However, 5% to 20% of the SC602- and WRSS1-immunized volunteers showed mild and transient symptoms of diarrhea and fever. In light of new knowledge about Shigella pathogenesis as well as data from other clinical trials, 2 new and presumably safer S. sonnei derivatives have been constructed (WRSs2 and WRSs3). In addition to loss of virG(icsA), WRSs2 has deletions in 2 genes, senA and senB, that are present on the virulence plasmid.^29,52 senA (also known as shet2-1 and ospD3) encodes the enterotoxin ShET2-1, which has been shown to cause fluid accumulation in rabbit ileal loops.^7,8 senB (also known as shet2-2 and ospD2) encodes a similarly sized protein as SenA and shows 40% identity at the amino acid level. The enterotoxic activity of ShET2-2 remains to be demonstrated.^20,29 Like WRSs2, WRSs3 lacks virG(icsA) and the 2 enterotoxin genes with the additional deletion of the virulence plasmid-based msbB2 gene. Lack of the msbB2 gene product has previously been shown to produce a less-toxic LPS molecule, which might help to reduce the symptoms of fever seen in WRSS1-immunized volunteers.^20,29 How these additional mutations, especially that of msbB2, will affect colonization of these strains is unclear, given that effective colonization is critical in the elicitation of immune response and protection. The primary goal of this pilot study was to compare the safety and colonization of 2 novel S. sonnei vaccine candidate strains (WRSs2 and WRSs3), with those of the clinically tested vaccine strain WRSS1, by using a gastrointestinal model of infection. The hypothesis tested was that the 2 novel Shigella vaccine strains would colonize the vaccinated animal and induce an immune response similar to that of WRSS1 but with less frequent and less severe clinical side effects.     

Use of Genome-wide Heterospecific Single-Nucleotide Polymorphisms to Estimate Linkage Disequilibrium in Rhesus and Cynomolgus Macaques

Rhesus and cynomolgus macaques are frequently used in biomedical research, and the availability of their reference genomes now provides for their use in genome-wide association studies. However, little is known about linkage disequilibrium (LD) in their genomes, which can affect the design and success of such studies. Here we studied LD by using 1781 conserved single-nucleotide polymorphisms (SNPs) in 183 rhesus macaques (Macaca mulatta), including 97 purebred Chinese and 86 purebred Indian animals, and 96 cynomolgus macaques (M. fascicularis fascicularis). Correlation between loci pairs decayed to 0.02 at 1146.83, 2197.92, and 3955.83 kb for Chinese rhesus, Indian rhesus, and cynomolgus macaques, respectively. Differences between the observed heterozygosity and minor allele frequency (MAF) of pairs of these 3 taxa were highly statistically significant. These 3 nonhuman primate taxa have significantly different genetic diversities (heterozygosity and MAF) and rates of LD decay. Our study confirms a much lower rate of LD decay in Indian than in Chinese rhesus macaques relative to that previously reported. In contrast, the especially low rate of LD decay in cynomolgus macaques suggests the particular usefulness of this species in genome-wide association studies. Although conserved markers, such as those used here, are required for valid LD comparisons among taxa, LD can be assessed with less bias by using species-specific markers, because conserved SNPs may be ancestral and therefore not informative for LD.Abbreviations: GWAS, genome-wide association study; LD, linkage disequilibrium; MAF, minor allele frequencyContributing to the widespread use of nonhuman primates in biomedical research, captive-breeding programs such as those of the National Primate Research Center system in the United States were established initially by using animals imported from Asia. The 2 most commonly used primates are rhesus macaques (Macaca mulatta) and long-tailed or cynomolgus macaques (M. fascicularis fascicularis).After humans, rhesus macaques are the most widely distributed primate species.^37,38 This species is found throughout mainland Asia, ranging from Afghanistan to India and eastward through Thailand and southern China to the Yellow Sea.^31,34 In addition to their significant morphological differences,⁹ rhesus macaques of Indian and Chinese origins have been demonstrated to exhibit significant phenotypic differences that are directly relevant to their use as biomedical models in experimental studies.^2,23,42 Cynomolgus macaques are found south of the subtropical and temperate geographic distributions of rhesus macaques, in the south and southeast Indo-Malayan regions.^8,10The 2 species share a common ancestor that lived 1 to 2 million years ago.^3,13,25 This ancestral population of rhesus macaques diverged from a fascicularis-like ancestor shared in common with both rhesus and cynomolgus macaques after cynomolgus macaques expanded from their homeland in Indonesia.³⁶ For this reason, genetic markers present in Indian rhesus macaques are either highly derived or are conserved as ancestral markers shared with Chinese rhesus macaques. The interspecific boundaries of rhesus and cynomolgus macaques are delineated by a narrow zone of parapatry in northern Indochina,^7,8,10 within which male-biased gene flow^37,39 and relatively high, but highly variable, levels of introgression of genes³² have occurred from rhesus to cynomolgus macaque groups.^37,39 Because cynomolgus macaques originated in Indonesia³⁶ and because rhesus macaques probably diverged from cynomolgus macaques in southwestern China,¹¹ genetic markers shared between Indonesian cynomolgus macaques and Chinese rhesus macaques comprise a unique set of markers that are conserved in both macaque species.The wide assortment of morphometric differences^8,9 and the broad geographic distribution of these 2 macaque species foster an expectation of high genetic diversity within and between them that could be exploited for mapping genes responsible for phenotypic differences between taxa. A better understanding of linkage disequilibrium (LD) in these nonhuman primate species can lead to a more informed selection of study subjects for, and more efficient conduct of, genome-wide association studies (GWAS) of particular diseases that macaques share in common with humans. LD is the nonrandom association of alleles at 2 or more adjacent loci that descend from single, ancestral chromosomes.²⁹ LD plays a critical role in gene mapping, both as a tool for fine mapping of complex disease genes and in GWAS-based approaches. GWAS facilitate the identification of genes associated with complex and common traits or diseases by examining LD estimates among large numbers of common genetic variants, typically single-nucleotide polymorphisms (SNPs), between pairs of different groups of subjects to determine whether any variant is associated with a trait or disease of interest. LD data make tightly linked variants strongly correlated to produce successful association studies. For instance, LD reduces the number of markers and sample size of study subjects required to map genes influencing phenotypes to the genome because markers in LD are linked and inherited together.¹³ In addition, differences in LD can be used to identify orthologs for detecting the signatures of selective sweeps,²¹ as defined by d_N/d_S ratios obtained through the McDonald–Kreitman neutrality test.²⁴ Furthermore, LD assessments can provide a more complete understanding of genome structure by defining the boundaries of haplotype blocks, within which recombination is rare or absent and which are separated by recombination ‘hotspots,’ in genomes.⁴³Evidence from a study based on 1476 SNPs identified in ENCODE regions of the Indian rhesus macaque genome¹³ indicated that the rate of LD decay is higher in Chinese than in Indian rhesus macaques due to an hypothesized genetic bottleneck experienced by Indian rhesus macaques after diverging from the eastern subspecies, and, therefore, that Indian rhesus macaques, having higher LD, may be more useful for GWAS than Chinese rhesus macaques. In that study,¹³ only 33% of the SNPs were shared in common between the 2 subspecies, with Chinese rhesus macaques contributing to more than 60% of the remaining rhesus SNPs. Conversely, another study⁴¹ reported a slower rate of decay of LD in 25 Chinese than in 25 Indian rhesus macaques on the basis of 4040 SNPs, only 2% of which fell in coding regions, but 68% of those SNPs were shared between the 2 subspecies, with Indian rhesus macaques contributing almost 60% of the remaining SNPs. The marked disparity between the 2 studies in the proportions of shared SNPs used, the subspecies with the most genetic diversity, the sample size of Chinese rhesus macaques, the proportions of SNPs located in or near coding regions that are subject to functional constraints, and the greater disparity in LD decay between the 2 subspecies of rhesus macaques might reflect biases in either or both studies. For example, the use of markers whose frequencies are uncharacteristically low in one subspecies relative to the other can underestimate the rate of LD decay because lower frequency alleles, on average, are younger and have experienced less time for recombination.²⁶ To avoid the influence of such ascertainment biases, comparisons of LD between 2 taxa should involve only SNPs conserved in both taxa. Moreover, because 2 points do not provide a phylogenetic or cladistic analysis to assign specific SNPs to origin on one phylogenetic line or another, comparing just the Indian and Chinese rhesus macaques without an additional primate taxon makes it is difficult to establish polarity and distinguish between derived and conserved SNPs. This limitation likely led to the contradictory conclusions of the 2 previously cited studies^13,41 regarding the rate of LD decay in Chinese and Indian rhesus macaques.Because rhesus and cynomolgus macaques share a common fascicularis-like ancestor, a comparison of heterospecific SNPs among cynomolgus, Indian rhesus, and Chinese rhesus macaques would likely be fundamental to inferences regarding genome-wide LD estimates. The objective of the present study was to evaluate the conclusions of previous studies^13,41 by using our panel of 1781 autosomal SNPs that are conserved in both rhesus and cynomolgus macaques to estimate the rates at which genome-wide LD decays in Indian and Chinese rhesus macaques and cynomolgus macaques, the species ancestral to rhesus macaques, and to evaluate the suitability of these populations for GWAS.     

Retrospective Analysis of the Incidence of Retained Placenta in 3 Large Colonies of NHP

During 1999 through 2014, retained placenta was the most common cause of clinical admission for reproductive complications in breeding colonies of baboons (approximate colony size, 2000 animals), cynomolgus macaques (approximately 1000), and rhesus macaques (approximately 500) at the Southwest National Primate Research Center. Retained placentas occurred in 2.7% of baboons, 3.3% of cynomolgus macaques, and 1.0% of rhesus macaques. Apparent risk factors for retained placenta included stillbirth or abortion and at least one prior cesarean section. There was a significant association between stillbirth and retained placenta in all species. Cesarean sections were performed routinely for baboons to meet research objectives but occurred only as needed for cynomolgus and rhesus macaques. Having had at least one prior cesarean section was an incidence factor for retained placenta in 37.0% of baboons and 4.7% of cynomolgus macaques; none of the rhesus macaques with retained placentas had undergone cesarean section previously. More than 90% of dams with retained placenta returned to a successful reproductive life or assignment to a nonbreeding research protocol. Advances in reproductive management will benefit from prospective studies that capture additional data from all members of a breeding group prior to reproductive complications.Abbreviations: Southwest National Primate Research Center (SNPRC), retained placenta (RP), cesarean section (C-section)Retained placentas and other reproductive problems are unavoidable complications encountered in association with NHP production colonies and are difficult to diagnose, because most births occur at night, when human observation is minimal, and because the dams routinely consume the placenta.^41,44,45 There is extensive information regarding retained placentas in dairy cattle,^7,25,20 and humans,^{3,13,24,35,36,40} but little is documented about this problem''s health hazard and effect on future reproduction in NHP,^16,17,23,49 with 3 documented cases reported as isolated reports between 1991 and 2009.^16,17,23 The first documented case of a retained placenta in a NHP was that of a female chimpanzee (Pan troglodytes).¹⁷ Clinical signs for that case included depression, poor maternal care, and vaginal hemorrhage 1 wk after delivery. The chimpanzee was treated successfully, and the infant was returned to the dam with no further complications. Another documented case involved a golden lion tamarin (Leontopithecus rosalia),¹⁶ which had experienced prolonged labor resulting in a stillbirth. After continued placental retention, the tamarin was hysterectomized. Histopathologic evaluation revealed that placental infiltration into the myometrium was the cause of retention.¹⁶ The third documented case occurred in a bonobo (Pan paniscus) housed in a sanctuary in the Democratic Republic of Congo.²³ The animal was treated with oxytocin injections; after manual removal of the placenta, the dam and infant were reunited, and maternal recovery was uneventful.In addition, in an unpublished case, one of the current authors (TH) treated a mandrill (Mandrillus sphinx) by using oxytocin injection and manual removal of the placenta, after which the dam and infant were reunited, and maternal recovery was uneventful. Several other unpublished cases documented in the medical records of the breeding colonies at the Southwest National Primate Research Center (SNPRC) involved species baboons (Papio spp.), cynomolgus macaques (Macaca fascicularis), and rhesus macaques (Macaca mulatta). Clinical veterinarians had deemed all of these animals to be healthy prior to their placement into breeding groups and were rechecked semiannually concurrent with tuberculin testing. Body condition varied from lean to obese, but body condition score was not recorded. We retrospectively reviewed these records to determine the risk factors and incidence of retained placenta within the 3 NHP colonies over 15 y.     

New-Onset Diabetes Mellitus After Transplantation in a Cynomolgus Macaque (Macaca fasicularis)

A 5.5-y-old intact male cynomolgus macaque (Macaca fasicularis) presented with inappetence and weight loss 57 d after heterotopic heart and thymus transplantation while receiving an immunosuppressant regimen consisting of tacrolimus, mycophenolate mofetil, and methylprednisolone to prevent graft rejection. A serum chemistry panel, a glycated hemoglobin test, and urinalysis performed at presentation revealed elevated blood glucose and glycated hemoglobin (HbA1c) levels (727 mg/dL and 10.1%, respectively), glucosuria, and ketonuria. Diabetes mellitus was diagnosed, and insulin therapy was initiated immediately. The macaque was weaned off the immunosuppressive therapy as his clinical condition improved and stabilized. Approximately 74 d after discontinuation of the immunosuppressants, the blood glucose normalized, and the insulin therapy was stopped. The animal''s blood glucose and HbA1c values have remained within normal limits since this time. We suspect that our macaque experienced new-onset diabetes mellitus after transplantation, a condition that is commonly observed in human transplant patients but not well described in NHP. To our knowledge, this report represents the first documented case of new-onset diabetes mellitus after transplantation in a cynomolgus macaque.Abbreviations: NODAT, new-onset diabetes mellitus after transplantationNew-onset diabetes mellitus after transplantation (NODAT, formerly known as posttransplantation diabetes mellitus) is an important consequence of solid-organ transplantation in humans.^{7-10,15,17,19,21,25-28,31,33,34,37,38,42} A variety of risk factors have been identified including increased age, sex (male prevalence), elevated pretransplant fasting plasma glucose levels, and immunosuppressive therapy.^{7-10,15,17,19,21,25-28,31,33,34,37,38,42} The relationship between calcineurin inhibitors, such as tacrolimus and cyclosporin, and the development of NODAT is widely recognized in human medicine.^{7-10,15,17,19,21,25-28,31,33,34,37,38,42} Cynomolgus macaques (Macaca fasicularis) are a commonly used NHP model in organ transplantation research. Cases of natural and induced diabetes of cynomolgus monkeys have been described in the literature;^14,43,45 however, NODAT in a macaque model of solid-organ transplantation has not been reported previously to our knowledge.     

Serologic Evaluation of Clinical and Subclinical Secondary Hepatic Amyloidosis in Rhesus Macaques (Macaca mulatta)

Secondary hepatic amyloidosis in nonhuman primates carries a grave prognosis once animals become clinically ill. The purpose of this study was to establish serologic parameters that potentially could be used to identify rhesus macaques undergoing subclinical development of secondary hepatic amyloidosis. A retrospective analysis was completed by using serum biochemical profiles from 26 histologically diagnosed amyloidotic macaques evaluated at 2 stages of disease, clinical and subclinical (3 to 32 mo prior to clinical signs of disease). Standard serum biochemistry values for cases were compared with institutional age- and gender-specific references ranges by construction of 95% confidence intervals for the difference between means. In addition, 19 histologically diagnosed amyloidotic macaques and 19 age-matched controls were assayed for changes in various parameters by using routinely banked, frozen (–80 °C) sera available from clinical and subclinical time points. Clinically amyloidotic animals displayed increased levels of alkaline phosphatase, aspartate aminotransferase, lactate dehydrogenase, gamma glutamyltranspeptidase, and macrophage colony-stimulating factor and significantly decreased quantities of albumin and total cholesterol. Subclinical amyloidotic animals displayed increased levels of alkaline phosphatase, aspartate aminotransferase, lactate dehydrogenase, and serum amyloid A and decreased concentrations of albumin and total cholesterol. The serologic parameters studied indicate a temporal relationship of these factors not previously described, show a clear pattern of disease progression, and could be useful in subclinical disease detection.Abbreviations: mCSF, macrophage colony stimulating factor; SAA, serum amyloid AAmyloid is an eosinophilic substance made of insoluble fibrillar protein.³² When deposited extracellularly, amyloid causes displacement of tissue form and disruption of organ function.³² Persistent accretion of amyloid can result in organ failure and ultimately animal death.²² Clinical signs of disease depend on the tissues affected and the degree of involvement.³² Amyloidosis has been well documented in humans, other mammals, birds, and reptiles.³⁸ In humans, amyloidosis plays a key role in many diseases, including Alzheimer disease, type II diabetes, rheumatoid arthritis, and Down syndrome.^15,20,35,38Amyloidosis generally is classified into 3 categories: primary, secondary, and hereditary. Primary amyloidosis consists of the immunoglobulin- and myeloma-associated types. Secondary (reactive) amyloidosis is associated with chronic inflammation.²⁴ Common causes of secondary amyloidosis in humans include rheumatoid arthritis, idiopathic colitis, infectious diseases, such as tuberculosis and leprosy, and malignant tumors, such as mesothelioma and Hodgkins disease.²⁸ Hereditary amyloid syndromes are rare and include Mediterranean fever, Muckle–Wells syndrome, and familial amyloid cardiomyopathy.^32,38Secondary amyloidosis is the most common form of amyloidosis in animals.³⁸ Amyloidosis occurs in many species of nonhuman primates including the common marmoset (Callithrix jacchus),²³ squirrel monkey (Saimiri sciureus),³⁴ rhesus macaque (Macaca mulatta),^9,10 pigtailed macaque (Macaca nemestrina),^18,27 crab-eating macaque (Macaca fascicularis),²⁷ barbary ape (Macaca sylvanus),⁶ baboon (Papio spp.),¹⁷ mandrill (Papio sphinx), and chimpanzee (Pan troglodytes).^16,39 Although a definitive cause of secondary amyloidosis has not been identified in nonhuman primates, this condition has been associated with chronic inflammation due to rheumatoid arthritis,⁶ viral infection,¹⁸ parasitism,¹ respiratory disease,^27,30 trauma,³⁰ and bacterial enterocolitis.^27,30,31 Shigella spp. have received particular attention as a common etiology linking enterocolitis with amyloidosis.^4,7,38Previous research on amyloidosis in nonhuman primates has yielded clinical and serologic profiles in end-stage amyloidotic animals, but little is known about the serologic status in the subclinical stages of disease. Amyloid can accumulate for as long as 3 y before severe organ disruption occurs¹⁴ and clinical signs of amyloidosis become evident.¹⁶ With appropriate analysis, detection of amyloidosis could occur much earlier than typically now achieved, thus allowing for targeted preventative therapy to potentially halt the progression of this insidious disease.     

Detection and Quantification of Male-Specific Fetal DNA in the Serum of Pregnant Cynomolgus Monkeys (Macaca fascicularis)

Because of their developmental similarities to humans, nonhuman primates are often used as a model to study fetal development for potential clinical applications in humans. The detection of fetal DNA in maternal plasma or serum offers a source of fetal genetic material for prenatal diagnosis. However, no such data have been reported for cynomolgus monkeys (Macaca fascicularis), an important model in biomedical research. We have developed a specific, highly sensitive PCR system for detecting and quantifying male-specific fetal DNA in pregnant cynomolgus monkeys. We used multiplex quantitative real-time PCR to analyze cell-free DNA in maternal blood serum obtained from 46 pregnant monkeys at gestational weeks 5, 12, and 22. The presence of SRY gene and DYS14 Y chromosomal sequences was determined in 28 monkeys with male-bearing pregnancies. According to confirmation of fetal sex at birth, the probe and primers for detecting the Y chromosomal regions at each time point revealed 100% specificity of the PCR test and no false-positive or false-negative results. Increased levels of the SRY-specific sequences (mean, 4706 copies/mL serum DNA; range, 1731 to 12,625) and DYS14-specific sequences (mean, 54,814 copies/mL serum DNA; range, 4175–131,250 copies) were detected at week 22. The SRY- and DYS14-specific probes appear to be an effective combination of markers in a multiplex PCR system. To our knowledge, this report is the first to describe the detection of cell-free DNA in cynomolgus monkeys.Abbreviations: C_t, threshold cycleAnalysis of cell-free circulating nucleic acids in human maternal plasma or serum has led to the development of risk-free methods for prenatal genetic diagnosis and the assessment of several fetal and maternal conditions, for example, sex determination for paternally inherited diseases, pregnancy-associated complications, sex-linked disorders for ambiguous genitalia, and embryo tracking.^{1,4,12,14,18,19} Technical challenges associated with detecting fetal DNA arise due to the low concentration of fetal DNA in maternal plasma during pregnancy and the difficulty of differentiating the genetic material of the fetus from that of the mother.^5,13,20 Fetal sex determination using sequences derived from the Y chromosome only is relatively simple and has a reported accuracy rate in humans of approximately 99.0% at 7 wk of gestation and 100% after 20 wk, depending on the protocol and methods used.^3,5,17,20 In other species, researchers have used real-time PCR assays during pregnancy to predict fetal sex from cell-free DNA at an accuracy of 100%.^9,10,11 Cell-free fetal DNA in the maternal circulation represents only 3% to 6% of the total free DNA obtained from plasma throughout pregnancy; however, this percentage is variable between pregnancies.^5,13,20In clinical biomedical research, it is essential to develop animal models for human diseases to reveal their mechanisms.^16,22 Continued progress in surgical intervention and molecular medicine suggests that it may soon be possible to develop potential treatments or even cures for several fetal genetic diseases at an early stage of pregnancy.¹⁵ Fetal developmental research during early pregnancy might be facilitated by using cell-free fetal DNA in the maternal blood rather than other methods, such as serum screening and ultrasonography. Nonhuman primates, especially macaques, are useful model animals for studying fetal development because of the similarity of the reproductive characteristics, placental structure, and developmental events between these animals and humans.^9,10 These developmental similarities highlight the importance of the study of cell-free fetal DNA in nonhuman primates and its usefulness as a marker to obtain genetic information about the fetus.In the current study, we investigated the presence of cell-free fetal DNA in the maternal plasma of cynomolgus monkeys by developing and using a standardized PCR system. To this end, we selected the SRY (sex-determining region Y) gene and DYS14 sequences of the cynomolgus monkey to use as sex-associated markers. The Y chromosome-specific sequences in the single-copy sex determination region of SRY and the multicopy (thus yielding increased sensitivity) sequences of DYS14 in the TSPY (testis-specific protein, Y-linked) gene have had wide clinical use in humans as molecular markers for detecting and quantifying cell-free fetal DNA.^3,7 In addition, TSPY has been used in bovines for detecting cell-free fetal DNA² and in rhesus macaques for long-term evaluation of microchimerism.⁸ Given the reports of fetal sex determination in rhesus macaques^9,10 and sheep¹¹ by analyzing Y chromosome-specific sequences from cell-free DNA, we hypothesized that we could predict the fetal sex of cynomolgus monkeys at different stages of gestation. This information has been extremely useful in optimizing the design of experimental studies in biomedical research and in managing a nonhuman primate breeding colony.¹⁰ Because cynomolgus and rhesus macaques are closely related members of the same genus, the current experiments are similar to a previous study.⁹We developed an efficient 2-color multiplex PCR system to detect and quantify fetal DNA in the maternal serum of cynomolgus monkeys during pregnancy. We used 2 loci on the Y chromosome in a single PCR test to minimize the likelihood of false-positive signals. Here we report the results of detection and analysis of fetal DNA at various weeks of gestation and evaluate our PCR system for its ability to determine fetal sex from pregnant monkeys’ cell-free DNA.     

Effects of Maternal and Infant Characteristics on Birth Weight and Gestation Length in a Colony of Rhesus Macaques (Macaca mulatta)

A retrospective study using maternal and birth statistics from an open, captive rhesus macaque colony was done to determine the effects of parity, exposure to simian retrovirus (SRV), housing, maternal parity, and maternal birth weight on infant birth weight, viability and gestation length. Retrospective colony statistics for a 23-y period indicated that birth weight, but not gestation length, differed between genders. Adjusted mean birth weights were higher in nonviable infants. Mothers positive for SRV had shorter gestations, but SRV exposure did not affect neonatal birth weights or viability. Infants born in cages had longer gestations than did those born in pens, but neither birth weight nor viability differed between these groups. Maternal birth weight did not correlate with infant birth weight but positively correlated with gestation length. Parity was correlated with birth weight and decreased viability. Increased parity of the mother was associated with higher birth weight of the infant. A transgenerational trend toward increasing birth weight was noted. The birth statistics of this colony were consistent with those of other macaque colonies. Unlike findings for humans, maternal birth weight had little predictive value for infant outcomes in rhesus macaques. Nonviable rhesus infants had higher birth weights, unlike their human counterparts, perhaps due to gestational diabetes occurring in a sedentary caged population. Similar to the situation for humans, multiparity had a protective effect on infant viability in rhesus macaques.Abbreviations: ANCOVA, analysis of covariance; PRL, Primate Research Laboratory; SRV, simian retrovirusThe rhesus macaque (Macaca mulatta) is a useful animal model for human female reproduction studies because the comparative physiology between the 2 species is nearly identical.^1.5,49 Some factors that affect birth weight and neonatal viability in both humans and macaques include maternal birth weight, maternal age, maternal parity, and the presence of underlying maternal disease. Even experimentally induced simulated human lifestyle factors can affect neonatal outcome.^{10,16,17,25,44}In humans, maternal birth weight correlates with infant birth weight such that low birth weight mothers themselves have low birth weight infants.^8,19,28,30 A similar association has been shown in the macaque.^38,39 Because low birth weight is associated with increased neonatal mortality in humans and in macaques, this correlation, if present, may have important predictive value.^{11,20,21,32,45,47,53} One objective of this study was to establish whether maternal birth weight correlated with neonatal birth weight and viability in this colony of rhesus macaques.The relationship between parity, age, and birth outcomes in humans is controversial because multiparous and grand multiparous women tend to be of lower socioeconomic status, older, and have many confounding lifestyle factors.^2,24,27,56 In macaques, low parity and young age are associated with reproductive failure.⁵⁰ In pigtailed macaques (Macaca nemestrina), increased parity was associated with decreased neonatal viability but increased birth weight. Despite their lower parity, younger mothers in the colony of pigtailed macaques produced lower birth-weight infants, but more viable infants, compared with those of older mothers.¹⁷ The positive correlation between birth weight and viability merits further investigation in rhesus macaques. One objective of the current study was to determine whether maternal parity and age affected birth weight and neonatal viability in our rhesus macaque colony.The lifestyle factors of alcohol consumption, cigarettes, caffeine, drug use, diabetes and exercise have all been shown to influence birth weight and gestation length in humans and macaques.^{4,7,15,22,26,35,40,42,44,51,55} Captive animals can become obese and develop insulin-resistant diabetes, which prolongs gestation and produces oversized infants that are less healthy.^21,46,51 Because exercise is a preventative lifestyle factor for obesity and diabetes, it would be useful to compare active animals with sedentary ones.³⁰ Previous retrospective colony studies in pigtail macaques show that cage type, location, and social housing have significant effects on birth weight and birth outcome.^18,19 Another objective of the current study was to determine whether housing in cages (sedentary animals) or group pens (active animals) influenced gestation length, birth weight, and viability in our rhesus macaques.Another factor in birth outcome is the disease status of the mother. Viral infections, particularly of adenoviruses and immunosuppressive retroviruses, are associated with low birth weight and infant mortality in humans and nonhuman primates.^{13,21,25,33, 34,52,53} A previous report describes maternal transmission of simian retrovirus in a colony of pigtailed macaques with concurrent immunosuppression, low birth weight, and increased infant mortality in viremic mothers.³³ However, some evidence suggests that lentiviral antibodies in amniotic fluid may protect against in utero infection.²³ Further confounding the effects of retroviruses on reproductive outcome, animals infected horizontally can be viremic but serologically negative, and animals with sufficient, detectable immune responses may have provirus latent in their tissues.³³ Because simian retrovirus (SRV) was endemic in the subject rhesus colony and most data were retrospective thus preventing confirmation of viremia, another objective was to determine whether seropositivity of the dam was associated with neonatal viability, gestation length, and infant birth weight.     

Endometrial Decidualization and Deciduosis in Aged Rhesus Macaques (Macaca mulatta)

Superficial decidualization of the endometrial stroma is an essential feature of the implantation stage of pregnancy in rhesus macaques and other primates. Decidualization involves proliferation of the endometrial stromal cells, with differentiation into morphologically distinct decidual cells. Previous reports involving nonpregnant rhesus monkeys have described localized and widespread endometrial decidualization in response to administration of progesterone and synthetic progestogens. Ectopic decidua or ‘deciduosis’ describes the condition in which groups of decidual cells are located outside of the endometrium, most often in the ovaries, uterus and cervix but also in various other organs. In humans, most cases of deciduosis are associated with normal pregnancy, and ectopic decidua can be found in the ovary in nearly all term pregnancies. Here we describe pronounced endometrial decidualization in 2 rhesus macaques. Both macaques had been treated long-term with medroxyprogesterone acetate for presumed endometriosis, which was confirmed in one of the macaques at postmortem examination. In one animal, florid extrauterine and peritoneal serosal decidualization was admixed multifocally with carcinomatosis from a primary colonic adenocarcinoma. Cells constituting endometrial and serosal decidualization reactions were immunopositive for the stromal markers CD10, collagen IV, smooth muscle actin, and vimentin and immunonegative for cytokeratin. In contrast, carcinomatous foci were cytokeratin-positive. To our knowledge, this report describes the first cases of serosal peritoneal decidualization in rhesus macaques. The concurrent presentation of serosal peritoneal decidualization with carcinomatosis is unique.Abbreviations: GnRH, gonadotropin-releasing hormone; PAS, periodic acid–Schiff; SMA, smooth-muscle actinSuperficial decidualization of the endometrial stroma is an essential feature of the implantation stage of pregnancy in rhesus macaques and other primates.^13,27,29,37 This process typically begins, and is most prominent, adjacent to the spiral arteries, eventually expanding to affect the endometrium uniformly.³⁵ The endometrial stroma surrounds and supports the endometrial glands and is composed mainly of endometrial stromal cells and blood vessels.³⁵ Decidualization involves proliferation of the endometrial stromal cells, with differentiation into morphologically distinct decidual cells.^7,27,38 Endometrial stromal cells transform into large, polyhedral, cytoplasm-rich cells with large amounts of stored glycogen and are often binucleated or polyploid in character.^{6,13,27,30,35} Ultrastructurally, decidualized cells have numerous ribosomes, prominent rough endoplasmic reticulum and Golgi complexes, and cytoplasmic accumulation of glycogen and lipid droplets.^13,35 Consistent with their stromal origin, decidualized cells express mesenchymal immunohistochemical markers, such as vimentin, desmin, and muscle-specific actin.^{6,7,14,16,20,22}Initiation of decidualization by attachment of the blastocyst to the uterine epithelium depends on previous sensitization by progesterone secretion, after a brief priming by estrogen.^12,13,27 Estrogen and progesterone regulate a series of complex interactions at the interface between the developing embryo and the cells in the stromal compartment, leading to the formation of a differentiated maternal tissue (decidua) that supports embryo growth and maintains early pregnancy.²⁷ Postovulatory levels of circulating progesterone increase and help maintain the differentiation of decidual cells.^{7,13,33,37,38}Ectopic decidua or ‘deciduosis’ describes the condition in which groups of decidual cells reside outside of the endometrium, most often in the ovaries, uterus, and cervix; the fallopian tubes, peritoneum, omentum, diaphragm, liver, skin, spleen, appendix, abdominal–pelvic lymph nodes, renal pelvis, and lungs of women have also been reported as affected.^{6,14,18,20,22,28,29,38} In humans, most cases of deciduosis are associated with normal pregnancy, and ectopic decidua have been reported in the ovary in 90.5% to 100% of term pregnancies.^{6-8,14,20,22,28-30,38} Occasional cases in nonpregnant or postmenopausal women have been attributed to progesterone-secreting active corpora lutea, progesterone secretion by the adrenal cortex, trophoblastic disease, exogenous progestational agents, and pelvic irradiation.^{6-8,14,18,20,22,28,38} Deciduosis is usually an incidental finding that regresses postpartum within 4 to 6 wk; rarely, florid reactions have been reported to cause peritonitis, adhesions, hydronephrosis and hematuria, acute bowel obstruction or perforation (or both), abdominal pain mimicking appendicitis, massive and occasionally fatal hemoperitoneum, vaginal bleeding, and pneumothorax.^{6,7,14,18,20,22,28,29,31}Previous reports involving nonpregnant rhesus macaques have described localized and widespread endometrial decidualization in response to the administration of progesterone, synthetic progestogens, or progesterone-releasing bioactive intrauterine devices and intravaginal rings and have referred to these changes as ‘pseudodecidualization’ to indicate the absence of pregnancy in these animals.^12,33,35,37 In macaques given low (but superphysiologic) levels of progestogens, decidual changes have been noted in localized regions (around spiral arteries and underneath superficial epithelium), whereas high doses of progesterone or synthetic progestagens can cause a more pronounced and extensive reaction.³⁵In cynomolgus macaques, extrauterine decidual cell plaques are rare histologic findings in the subcoelomic mesenchyme of the ovarian cortex.^8,30 Despite the frequency of the condition in women, deciduosis is postulated to be a rarely documented lesion in primates because it is most often observed in conjunction with pregnancy, and pregnant cynomolgus macaques are seldom used in toxicity studies.⁸ Here we describe the pronounced endometrial decidualization of 2 rhesus macaques, one of which also had florid extrauterine and peritoneal decidualization that was admixed multifocally with carcinomatosis. Both macaques had been treated long-term with medroxyprogesterone acetate for presumed endometriosis, which was confirmed in one of the macaques at postmortem examination. To our knowledge, this report describes the first cases of peritoneal decidualization in rhesus macaques as well as the concurrent occurrence of carcinomatosis, endometriosis and peritoneal decidualization in a macaque. The extensive intermixing of the cell populations presented a diagnostic challenge at pathologic examination, and accurate diagnosis was achieved only through the use of multiple immunohistochemical markers.     

Alterations in Cytokines and Effects of Dexamethasone Immunosuppression during Subclinical Infections of Invasive Klebsiella pneumoniae with Hypermucoviscosity Phenotype in Rhesus (Macaca mulatta) and Cynomolgus (Macaca fascicularis) Macaques

Invasive Klebsiella pneumoniae with the hypermucoviscosity phenotype (HMV K. pneumoniae) is an emerging human pathogen that also has been attributed to fatal multisystemic disease in African green monkeys at our institution. Combining a cluster of subclinically infected macaques identified in March and April 2008 and the animals documented during a subsequent survey of more than 300 colony nonhuman primates yielded a total of 9 rhesus macaques and 6 cynomolgus macaques that were subclinically infected. In an attempt to propagate the responsible HMV K. pneumoniae strain, a subset of these animals was immunosuppressed with dexamethasone. None of the treated animals developed clinical disease consistent with the multisystemic disease that affected colony African green monkeys. However, cytokine analysis revealed significant alterations of secreted cytokines in macaques subclinically infected with HMV K. pneumoniae when compared with noninfected macaques, thereby calling into question the suitability of animals subclinically infected with HMV K. pneumoniae for use in immunologic or infectious disease research.Abbreviations: HMV, hypermucoviscosity phenotype; rmpA, regulator of the mucoid phenotype gene; magA, mucoviscosity-associated geneKlebsiella pneumoniae is a gram-negative member of the Enterobacteriaceae family that comprises part of the normal fecal and oral flora of many nonhuman primates¹⁹ but also has been implicated in cases of peritonitis, septicemia, pneumonia, and meningitis in both Old and New World primates.^17,20,37 Over the past 20 y, strains of invasive K. pneumoniae with a unique hypermucoviscosity phenotype (HMV K. pneumoniae) have been reported to cause community-acquired primary liver abscesses, meningitis, and endophthalmitis in humans in Taiwan and other Asian countries,^{10, 26–31,33,44,48,51} mostly in people with diabetes mellitus.^7,8,44 In addition, HMV K. pneumoniae has caused clinical disease in the United States and other nonAsian countries.^18,30,33 The HMV phenotype is determined based on a positive string test, which is performed by touching a colony with a bacterial loop and gently lifting. If a mucoid ‘string’ of at least 5 mm forms, the string test is considered positive.^3,14,45,51Capsular serotypes K1 and K2 have been reported as the major virulence determinants for human HMV K. pneumoniae liver abscesses.^9,15,49,50 The products of the mucoviscosity-associated gene (magA), which encodes a structural outer membrane protein of the K1 serotype, and the regulator of the mucoid phenotype gene (rmpA) have also been proposed as virulence factors.^{16,34,42,52,53}HMV K. pneumoniae has been reported to cause multisystemic abscesses in African green monkeys (Chlorocebus aethiops).⁴⁵ In late 2005 and early 2006, 7 African green monkeys in the research colony at our institution, the US Army Medical Research Institute for Infectious Diseases, were found to have abscesses in multiple locations; all 7 animals either succumbed or were euthanized because of poor prognosis due to surgically nonresectable abdominal abscesses.⁴⁵ The etiology of the final case was determined to be HMV K. pneumoniae with the K2 serotype and rmpA, and all 6 other cases had similar clinical, microbiologic, and pathologic characteristics. Prior to the current study, we believe these 7 cases were the only documented natural infections attributed specifically to HMV K. pneumoniae in nonhuman primates.⁴⁵As a result of those findings, our institution instituted a policy to report K. pneumoniae positive cultures in nonhuman primates during quarantine periods and on routine semiannual examination. Over several months in spring and summer 2008, a group of 19 macaques tested positive on oropharyngeal or rectal culture for HMV K. pneumoniae; 15 of those 19 animals were isolated in a single room for 2 to 4 mo to better characterize the infection.³ None of the animals showed clinical signs of disease during the isolation period, and abdominal palpation failed to suggest the presence of abdominal abscesses like those seen in African green monkeys. Testing of isolates suggested that the macaques harbored subclinical infections and that multiple genotypes of HMV K. pneumoniae were present.³In July 2008, a cynomolgus macaque from the colony that was experimentally challenged with monkeypox virus survived beyond the normal time-to-death window (12 to 16 d after infection). However, on day 22 after infection (6 to 10 d beyond this window), this macaque died unexpectedly. Histopathologic analysis of tissues from this NHP revealed a concurrent gram-negative bacterial infection, based on Gram stains and immunohistochemistry. Although cultures were not available, PCR analysis of DNA extracted from formalin-fixed, paraffin-embedded tissues revealed the presence of K. pneumoniae through the amplification of rmpA,³⁹ which is consistent with the HMV phenotype. This animal was considered to have survived infection with monkeypox based on time to death after infection. Monkeypox is reported to target the mononuclear phagocyte system and associated dendritic cells,⁵⁴ and we theorized that the monkeypox infection in this macaque led to suppression of the immune system, which then allowed development of a fatal HMV K. pneumoniae septicemia.The present project sought to explore the pathophysiology of HMV K. pneumoniae in macaques. We hypothesized that immunosuppression of subclinically infected macaques would produce lesions similar to those observed in the coinfected macaque. In addition, we hypothesized that subclinically infected macaques would have a different immune profile from that of noninfected primates. We measured and analyzed cytokine levels as an indication of altered immune status because such a state potentially could confound research into immunologic responses and infectious disease.     

Role of Retinoic Acid and Fibroblast Growth Factor 2 in Neural Differentiation from Cynomolgus Monkey (Macaca fascicularis) Embryonic Stem Cells

Retinoic acid is a widely used factor in both mouse and human embryonic stem cells. It suppresses differentiation to mesoderm and enhances differentiation to ectoderm. Fibroblast growth factor 2 (FGF2) is widely used to induce differentiation to neurons in mice, yet in primates, including humans, it maintains embryonic stem cells in the undifferentiated state. In this study, we established an FGF2 low-dose-dependent embryonic stem cell line from cynomolgus monkeys and then analyzed neural differentiation in cultures supplemented with retinoic acid and FGF2. When only retinoic acid was added to culture, neurons differentiated from FGF2 low-dose-dependent embryonic stem cells. When both retinoic acid and FGF2 were added, neurons and astrocytes differentiated from the same embryonic stem cell line. Thus, retinoic acid promotes the differentiation from embryonic stem cells to neuroectoderm. Although FGF2 seems to promote self-renewal in stem cells, its effects on the differentiation of stem cells are influenced by the presence or absence of supplemental retinoic acid.Abbreviations: EB, embryoid body; ES, embryonic stem; ESM, embryonic stem cell medium; FGF, fibroblast growth factor; GFAP, glial fibrillary acidic protein; LIF, leukemia inhibitory factor; MBP, myelin basic protein; RA, retinoic acid; SSEA, stage-specific embryonic antigen; TRA, tumor-related antigenPluripotent stem cells are potential sources of material for cell replacement therapy and are useful experimental tools for in vitro models of human disease and drug screening. Embryonic stem (ES) cells are capable of extensive proliferation and multilineage differentiation, and thus ES-derived cells are suitable for use in cell-replacement therapies.^18,23 Reported ES cell characteristics including tumorigenic potential, DNA methylation status, expression of imprinted genes, and chromatin structure were elucidated by using induced pluripotent stem cells.^2,11,17 Because the social expectations of regeneration medicine are growing, we must perform basic research with ES cells, which differ from induced pluripotent stem cells in terms of origin, differentiation ability, and epigenetic status.^2,8Several advances in research have been made by using mouse ES cells. Furthermore, primate ES cell lines have been established from rhesus monkeys (Macaca mulatta),²⁴ common marmosets (Callithrix jacchus),²⁵ cynomolgus monkeys (M. fascicularis),²⁰ and African green monkeys (Chlorocebus aethiops).¹⁹ Mouse and other mammalian ES cells differ markedly in their responses to the signaling pathways that support self-renewal.^8,28 Mouse ES cells require leukemia inhibitory factor (LIF)–STAT3 signaling.¹⁴ In contrast, primate ES cells do not respond to LIF. Fibroblast growth factor 2 (FGF2) appears to be the most upstream self-renewal factor in primate ES cells. FGF2 also exerts its effects through indirect mechanisms, such as the TGFβ–Activin–Nodal signaling pathway, in primate ES cells.²¹ In addition to the biologic similarities between monkeys and humans, ES cells derived from cynomolgus monkeys or human blastocysts have extensive similarities that are not apparent in mouse ES cells.^8,14,21,28 Numerous monkey ES cell lines are now available, and cynomolgus monkeys are an efficient model for developing strategies to investigate the efficacy of ES-cell–based medical treatments in humans.Several growth factors and chemical compounds, including retinoic acid (RA),^4,9,13,22,26 FGF2,^9,10,16,22 epidermal growth factor,^9,22 SB431542,^1,4,10 dorsomorphin,^10,27 sonic hedgehog,^{12,13,16,27,29} and noggin,^1,4,9,27 are essential for the differentiation and proliferation or maintenance of neural stem cells derived from primate ES cells. Of these factors, active RA signaling suppresses a mesodermal fate by inhibiting Wnt and Nodal signaling pathways during in vitro culture and leads to neuroectoderm differentiation in ES cells.^4,13,26 RA is an indispensable factor for the specialization to neural cells. FGF2 is important during nervous system development,¹² and FGF2 and RA both are believed to influence the differentiation to neural cells. The current study was done to clarify the mechanism of RA and FGF2 in the induction of differentiation along the neural lineage.We recently established a monkey ES cell line that does not need FGF2 supplementation for maintenance of the undifferentiated state. This ES cell line allowed us to study the role of differentiation to neural cells with RA and enabled us to compare ES cell differentiation in the context of supplementation with RA or FGF2 in culture. To this end, we established a novel cynomolgus monkey cell line derived from ES cells and maintained it in an undifferentiated state in the absence of FGF2 supplementation.     

Chagas Disease in 2 Geriatric Rhesus Macaques (Macaca mulatta) Housed in the Pacific Northwest

Chagas disease (American trypanosomiasis) is caused by the protozoan parasite Trypanosoma cruzi. It is endemic in Latin America but also is found in the southern United States, particularly Texas and along the Gulf Coast. Typical clinical manifestations of Chagas disease are not well-characterized in rhesus macaques, but conduction abnormalities, myocarditis, and encephalitis and megaesophagus have been described. Here we report 2 cases of Chagas disease in rhesus macaques housed in the northwestern United States. The first case involved a geriatric male macaque with cardiomegaly, diagnosed as dilated cardiomyopathy on ultrasonographic examination. Postmortem findings included myocarditis as well as ganglioneuritis in the esophagus, stomach, and colon. The second case affected a geriatric female macaque experimentally infected with SIV. She was euthanized for a protocol-related time point. Microscopic examination revealed chronic myocarditis with amastigotes present in the cardiomyocytes, ganglioneuritis, and opportunistic infections attributed to her immunocompromised status. Banked serum samples from both macaques had positive titers for T. cruzi. T. cruzi DNA was amplified by conventional PCR from multiple tissues from both animals. Review of their histories revealed that both animals had been obtained from facilities in South Texas more than 12 y earlier. Given the long period of clinical latency, Chagas disease may be more prevalent in rhesus macaques than typically has been reported. T. cruzi infection should be considered for animals with unexplained cardiac or gastrointestinal pathology and that originated from areas known to have a high risk for disease transmission.Abbreviations: DCM, dilated cardiomyopathy; CMV, cytomegalovirus; NHP, nonhuman primateChagas disease is caused by the hemoflagellate protozoan parasite Trypanosoma cruzi. The disease is endemic in many regions of South and Central America, and its range extends to the southern United States. In the United States, there is evidence that the parasite has established a domestic transmission cycle with canine reservoirs,¹⁹ and there are numerous wildlife reservoirs, most importantly armadillos, raccoons, rodents, and opossums.⁶ The main mode of transmission is via arthropod vectors, primarily triatomine species (kissing bugs or cone-nosed bugs), which serve as intermediate hosts. Vector species are present in the southern half of the United States.² Infection has been reported sporadically in domestic nonhuman primate (NHP) colonies.¹² Autochthonous insect vector-mediated transmission in humans in the United States has been reported rarely.³³ Transmission of T. cruzi to NHP is thought to occur mainly through insect vectors, specifically by contamination of the oral mucous membranes with parasite-containing feces during consumption of the bug. The infection may remain subclinical for years and, similar to that in people, affects the nervous system, digestive system, and heart. Clinical findings in NHP are infrequent but can include subcutaneous edema, fever, anorexia, lethargy, heart failure, and sudden death.^4,5 As in humans, the disease in NHP consists of an acute phase, with a paucity of clinical manifestations, and a chronic phase, characterized by irreversible cardiomyopathy leading to cardiac dysfunction and death. Chronically infected NHP in the indeterminate form of the chronic phase can exhibit subclinical conduction and echocardiographic abnormalities.⁸T. cruzi infections have been reported in a number of NHP species housed in Texas, Louisiana, and Georgia. Species affected include rhesus macaques (Macaca mulatta),^12,17 cynomolgus macaques (M. fascicularis),^29,42 yellow baboons (Papio cynocephalus), olive baboons (P. anubis),^12,14,41 pig-tailed macaques (M. nemestrina),^12,35 squirrel monkeys (Saimiri sciureus),¹³ ring-tailed lemurs (Lemur catta),^15,30 black-eyed lemurs (Eulemur macaco flavifrons), black and white ruffed lemurs (Varecia variegata variegate),¹⁵ pileated gibbon (Hylobates pileatus),³⁶ a lion-tailed macaque (M. silenus),³⁰ a Celebes crested black macaque (M. nigra),²⁷ and a chimpanzee (Pan troglodytes).⁴ Here we report on 2 cases of Chagas disease in rhesus macaques housed in the northwestern United States but that originated from South Texas.     

Adenocarcinoma of the Ileocolic Junction and Multifocal Hepatic Sarcomas in an Aged Rhesus Macaque (Macaca mulatta)

An aged male rhesus macaque in our colony had decreased appetite and a loss of interest in behavioral testing. CBC analysis revealed a regenerative, microcytic, hypochromic anemia with thrombocytosis, consistent with iron deficiency. A fecal occult blood test was positive. Ultrasound imaging revealed numerous, vascularized focal liver lesions that suggested metastases. The macaque''s appetite continued to decrease, and he became more lethargic. At this point, the investigator elected to euthanize the macaque. At necropsy, the ileocolic junction was white and abnormally thickened, and the liver was pale tan with approximately 18 discrete white masses randomly scattered throughout the hepatic parenchyma. Histologically, the mass at the ileocolic junction was identified as an intestinal adenocarcinoma, whereas the liver masses were confirmed to be undifferentiated hepatic sarcomas. This case report describes a rhesus macaque that had 2 unrelated primary neoplasms. A review of the literature indicates that this rhesus macaque is the first reported to have an adenocarcinoma of the ileocolic junction and multiple hepatic sarcomas simultaneously.Rhesus macaques (Macaca mulatta) are genetically similar to humans, have a similar aging phenotype at approximately 3 times the rate of those in humans, and develop spontaneous cancers similar to those in humans.³⁶ In humans, gastrointestinal carcinomas are relatively common, but most of these lesions arise in the colon and rectum with only a small percentage in the small intestine and ileum.^4,12,15,18 Although the ileocolic junction is considered a common site for intestinal adenocarcinomas in aged rhesus macaques, this tumor has also been found in the duodenum, jejunum, distal ileum, cecum, and colon.^{6,13,21-23,25,39} Intestinal adenocarcinomas also occur in aged cynomologus macaques (Macaca fasicularis),³⁹ cotton-top marmosets (Saguinus oedipus),^6,10 common marmosets (Callithrix jacchus),^6,27 and a squirrel monkey (Saimiri sciureus).²⁴ Cotton-top marmosets often develop adenocarcinomas of the colon, including the cecum–colon, and rectum.^6,10 Common marmosets have been reported to develop adenocarcinomas of the small intestine.^6,27 Adenocarcinoma of the cecum in a squirrel monkey has been reported.²⁴Spontaneous hepatic tumors unrelated to carcinogenic factors, such as aflatoxin B1,³³ occur only rarely in nonhuman primates. In the United States, primary malignant hepatic tumors in humans are rare, and fewer than 1% are reported to be hepatic sarcomas.^1,16,40 Review of the nonhuman primate literature revealed reports of hepatic cholangiocarcinoma in a 25-y-old male capuchin monkey (Cebus albifrons),⁷ hepatocellular carcinoma in a 24-y-old male squirrel monkey (Saimiri boliviensis)⁵ and in a female squirrel monkey (Saimiri sciureus) older than 13 y,²⁸ and hepatocellular carcinoma and cholangiocarcinoma in an African green monkey (Cercopithecus aethiops).³⁴ Spontaneous hepatocellular carcinomas were reported to occur in 2 adolescent male cynomologus macaques younger than 5 y.³¹ Hepatic hemangiosarcoma was diagnosed in 3-y-old female rhesus macaque,²⁶ and hepatic cholangiocarcinoma was found in a rhesus macaque that also had an intestinal adenocarcinoma.³⁹The aged male rhesus macaque (Macaca mulatta) in the current case study was found to have adenocarcinoma of the ileocolic junction and multiple, random, discrete neoplasms in the liver, which were identified as undifferentiated sarcomas. No metastases from the intestinal adenocarcinoma were detected, but neoplastic cells similar to those of the undifferentiated hepatic cells were identified in an intestinal artery. The frequency of multiple tumor types in aged nonhuman primates is relevant to the use of older animals in research.     

Clinicopathologic Characteristics,Prevalence, and Risk Factors of Spontaneous Diabetes in Sooty Mangabeys (Cercocebus atys)

In 2008, clinical observations in our colony of sooty mangabeys (Cercocebus atys) suggested a high frequency of type 2 diabetes. Postmortem studies of diabetic animals revealed dense amyloid deposits in pancreatic islets. To investigate these findings, we screened our colony (97 male mangabeys; 99 female mangabeys) for the disease from 2008 to 2012. The overall prevalence of diabetes was 11% and of prediabetes was 7%, which is nearly double that reported for other primate species (less than 6%). Fructosamine and triglyceride levels were the best indicators of diabetes; total cholesterol and glycated hemoglobin were not associated with disease. Increasing age was a significant risk factor: prevalence increased from 0% in infants, juveniles, and young adults to 11% in adults and 19% in geriatric mangabeys. Sex, medroxyprogesterone acetate exposure, and SIV status were unrelated to disease. Weight was marginally higher in prediabetics, but body condition did not indicate obesity. Of the 49 mangabeys that were necropsied after clinical euthanasia or death from natural causes, 22 were diabetic; all 22 animals demonstrated pancreatic amyloid, and most had more than 75% of islets replaced with amyloid. We conclude that type 2 diabetes is more common in mangabeys than in other primate species. Diabetes in mangabeys has some unusual pathologic characteristics, including the absence of altered cholesterol levels and glycated hemoglobin but a robust association of pancreatic insular amyloidosis with clinical diabetes. Future research will examine the genetic basis of mangabey diabetes and evaluate additional diagnostic tools using imaging and serum markers.Abbreviations: HbA1c, glycated hemoglobin; MPA, medroxyprogesterone acetate; YNPRC, Yerkes National Primate Research CenterSooty mangabeys (Cercocebus atys) are Old World NHP that are native to West Africa. Historically their use in research has been limited to infectious disease studies, leprosy studies, and behavioral research.^14,25 Over the past 20 to 30 y, they have been used in HIV–AIDS research. Mangabeys are natural hosts of SIV_smm, which is recognized as the origin of HIV2 infection in humans.^7,8,30,36,42 SIV typically is nonpathogenic in mangabeys despite high levels of virus replication, which makes this species a unique and invaluable model in AIDS research.^7,30,36,42 Our facility maintains a colony of approximately 200 sooty mangabeys. In 2008 clinical observations of relative hyperglycemia, glucosuria, and weight loss in our colony suggested that type 2 diabetes mellitus occurred at a relatively high frequency in this population. Spontaneous diabetes was found in 10% of the colony, and 5% of animals were prediabetic; this incidence is higher than that typically reported for other NHP species, such as cynomolgus macaques (less than 1% to 2%)²² and chimpanzees (less than 1%).³⁷ The prevalence of spontaneous diabetes in humans is typically 8.3%.^2,6,22,37 In addition, necropsies revealed that many affected animals had dense amyloid deposits in pancreatic islet cells. Insular amyloidosis was seen on histology, with a total replacement of islets by amyloid deposition in advanced diabetes. Advanced diabetes was determined by increased weight loss and severity of relative hyperglycemia. The increased clinical prevalence of diabetes in our mangabey colony prompted additional characterization of the clinicopathologic profile, risk factors, and prevalence of diabetes in our mangabey colony.The form of diabetes in this mangabey colony is characterized as type 2 diabetes mellitus, as they have hyperglycemia, hypertriglyceridemia, and islet amyloidosis. Type 2 diabetes mellitus is the most common of the 3 forms of diabetes, and has been documented in humans and NHP,^22,31,37,55 including rhesus macaques (Macaca mulatta), cynomolgus macaques (Macaca fascicularis), Celebes crested macaques (Macaca nigra), bonnet macaques (Macaca radiate), pigtailed macaques (Macaca nemestrina), vervet monkeys (Chlorocebus pygerythrus), squirrel monkeys (Saimiri sciureus), chimpanzees (Pan troglodytes), and woolly monkeys (Lagothrix spp.).^{1,24,31,52,55} Type 2 diabetes is a chronic metabolic disorder in which insulin resistance occurs in liver, muscle, and adipose tissue. As type 2 diabetes progresses, it also can be characterized as a relative insulin deficiency.^{1,6,15,22,29,31,37,55} The initial clinical presentation of diabetes in humans and NHP includes polydipsia, polyuria, polyphagia, weight loss, and lethargy.^{1,6,22,27,31,37,55} Similar presentation was observed in our colony of diabetic mangabeys.Diagnostic criteria of diabetes in NHP species is similar to that for humans and is based on clinical symptoms and routine lab tests, including serum chemistry panel to evaluate persistent fasting hyperglycemia, hypertriglyceridemia, and hypercholesterolemia.^{2,6,11,16-18,21,22,29,31,37,48-50,52,55} Hypertriglyceridemia and hypercholesterolemia frequently are elevated due to diabetes and therefore are used as supportive diagnostic markers. In addition, the disease is characterized by transient hyperinsulinemia followed by insulin deficiency subsequent to glucose challenge. Urinalysis is used to evaluate glucosuria and ketonuria. These tests are not exclusive for diagnosing diabetes and can be inconsistent between species, thus making conclusive diagnosis challenging. For example, hyperglycemia can be a transient finding associated with recent food intake or stress associated with restraint for blood sample collection or anesthetic access, whereas hypertriglyceridemia can be seen in obese animals and those with other metabolic diseases such as pancreatitis and hypothyroidism.^1,22,37,55The typical clinical approach to the diagnosis of diabetes in NHP and other veterinary patients includes evaluation of fructosamine and glycated hemoglobin (HbA1c) levels and glucose tolerance testing. These tests are indices of glycemic control and are used in clinical settings primarily to assess prognosis and response to treatment; they are also useful for the initial diagnosis of diabetes when used in parallel with serum chemistry markers. Fructosamine and HbA1c can both provide information on long-term glycemic control, because fructosamine reflects average blood glucose levels over 2 to 3 wk whereas HbA1c reflects average blood glucose over 2 to 3 mo preceding blood collection. HbA1c is the primary test for diabetes in human medicine,^6,31,35,37 whereas fructosamine is commonly used in veterinary medicine. Glucose tolerance testing provides an indirect measure of insulin sensitivity, but it is not frequently used clinically in NHP because of the requirement for prolonged physical restraint or sedation.^{1,21,22,26,27,34,37,55}Prevention and management of diabetes in NHP and humans can be achieved by identifying potential risk factors, including age, weight, sex, genetics, hormone drug exposure, and viral status.^{1,6,15,22,29,31,37,42,55} Advanced age, obesity, sex, and genetics are associated with diabetes in some species of NHP and humans.^{1,6,15,22,29,31,37,55} In addition, exposure to drugs such as medroxyprogesterone acetate (MPA) is suspected to be linked to diabetes due to the hormonal effects of progesterone impacting glucoregulatory function.^{1,6,10,22,23,31,34,55} MPA exposure is of interest, because it is used regularly in our mangabey colony as both a contraceptive and as therapy for endometriosis. In addition, SIV status is being evaluated as a risk factor, because a portion of our colony is SIV positive. Although HIV is not thought to be associated with diabetes in people, SIV pathogenesis in mangabeys differs; therefore it was of interest to explore the possible association of SIV and diabetes in mangabeys.^7,30,36,42 Pancreatic insular amyloidosis has been documented to be associated with type 2 diabetes in several species. Amyloidosis is a group of disorders that are caused by extracellular deposition of misfolded proteins that can result in impaired function of any organ.^{15,20,23,28,32,43,45,48,49} Because a high incidence of pancreatic insular amyloid was noted at necropsy, we sought to document the relationship with clinical diabetes in mangabeys.Spontaneous type 2 diabetes mellitus has been well documented in several species of NHP. Because the literature contains little information regarding the clinicopathologic features (the ‘profile’), risk factors, and prevalence of spontaneous diabetes mellitus in sooty mangabeys, the primary aims of the current study were 1) to determine whether elevated levels of fasting blood glucose, fructosamine, HbA1c, triglycerides, and total cholesterol levels are reliable diagnostic markers of type 2 diabetes mellitus in this NHP species; 2) to determine whether age, sex, MPA exposure, and SIV status influence the risk of diabetes; 3) to determine whether body weight influences diabetic status; 4) to evaluate the relationship between pancreatic amyloidosis and diabetes mellitus; and 5) to characterize the prevalence of diabetes mellitus in the mangabey population at our institution. To our knowledge, this report is the first to describe the natural occurrence of type 2 diabetes mellitus within a captive colony of sooty mangabeys. We hypothesized that blood glucose, fructosamine, HbA1c, triglyceride, and total cholesterol would be reliable diagnostic markers and that age, sex, and MPA exposure would influence the risk of diabetes in this species.     

Prevalence of Viremia and Oral Shedding of Rhesus Rhadinovirus and Retroperitoneal Fibromatosis Herpesvirus in Large Age-Structured Breeding Groups of Rhesus Macaques (Macaca mulatta)

We performed a cross-sectional study to estimate the prevalence of 2 gamma-2-herpesviruses, rhesus rhadinovirus (RRV) and retroperitoneal fibromatosis herpesvirus (RFHV), in breeding colonies of rhesus macaques. Of 90 animals selected for sampling, 73 (81%) were positive for RRV, which was detected only in blood in 22 (24%), only in saliva in 15 (16%), and in both blood and saliva in 36 (40%). Detection of RRV DNA in blood and saliva was significantly higher in animals younger than 2 y. In comparison, RFHV was detected in 40 (44%) of the 90 animals: only in blood in 5 (6%), only in saliva in 26 (29%), and in both blood and saliva in 9 (10%). Dual infection was detected in 38 (42%) animals; RFHV was only detected in coinfections. The mean RRV genome copy number in blood was significantly higher than that for RFHV. Age was a significant predictor of RRV copy number in blood and RFHV copy number in saliva. Of the 90 animals, 88 (98%) were positive for rhadinoviral antibodies on an immunofluorescent assay. Both RRV and RFHV are highly endemic in socially housed breeding colonies of rhesus macaques, and their patterns of infection are similar to that for the betaherpesvirus rhesus cytomegalovirus.Abbreviations: CNPRC, California National Primate Research Center; GE, genome equivalents (copy number); KSHV, Kaposi sarcoma-associated herpesvirus; RFHV, retroperitoneal fibromatosis herpesvirus; RRV, rhesus rhadinovirus; OSM, oncostatin M geneThe Rhadinovirus genus of gamma-2-herpesviruses is divided into 2 subgroups, RV1 and RV2, based on genomic sequence comparisons.^36,44 Rhadinovirus infections are generally subclinical in immunocompetent natural hosts, and overt disease is thought to arise only when hosts are immunocompromised.²⁸ In addition, the ability to establish both lytic and latent infections, a hallmark of the Herpesviridae family, occurs during rhadinovirus infections.^1,43 The RV1 subgroup includes Kaposi sarcoma-associated herpesvirus (KSHV; also referred to as human herpesvirus 8)^12,32 the causative agent of Kaposi sarcoma, an angioproliferative lesion composed of a mixed population of endothelial, inflammatory and spindle cells.^19,24 Furthermore, KSHV has been linked etiologically to 2 different B-cell lymphomas: primary effusion lymphoma and multicentric Castleman disease.¹⁷ Retroperitoneal fibromatosis herpesvirus (RFHV) is also a member of the RV1 subgroup and is thought to be the macaque homolog of KSHV.^{4,8,14,36,37,40} DNA sequences specific for RFHV have been detected in retroperitoneal fibromatosis in macaques coinfected with the potentially immunosuppressive simian betaretrovirus type 2.⁷ Histologic similarities between retroperitoneal fibromatosis and KS lesions seen in humans coinfected with KSHV and HIV have been previously described.^7,9,21,37 During outbreaks of simian betaretrovirus type 2 disease at 2 national primate research centers in the 1980s, the incidence of retroperitoneal fibromatosis was reported to be 5% to 7% for animals younger than 2 y and 1% across all age groups.^7,37,45 Since the end of these outbreaks in the late 1980s, retroperitoneal fibromatosis has occurred only rarely in primate colonies. The majority of published RFHV studies have focused on animals with recognized retroperitoneal fibromatosis lesions.^9-11 However, RFHV has proven extremely difficult to isolate and, to date, has not been propagated successfully in vitro, and only a small portion of the RFHV genome has been sequenced.^36,37,40,44 In this study we determined the prevalence of RFHV infection in nondiseased animals and address aspects of the natural history of this virus infection in captive macaque populations.Rhesus rhadinovirus (RRV) is a member of the RV2 subgroup, which naturally infects rhesus macaques.^15,38,44 RRV was isolated independently at 2 national primate research centers in the late 1990s from rhesus macaques.^15,42 Both RRV isolates were shown to have noteworthy sequence similarity to KSHV and RFHV.^2,8,15,42 Unlike RFHV, RRV can be propagated readily in vitro, thus facilitating studies of the lytic replication cycle.^5,6,16 Experimental coinfection of rhesus macaques with SIV and RRV resulted in a lymphoproliferative disease resembling multicentric Castleman disease, but variations in disease outcome between the 2 RRV isolates were noted.^30,49 More recently, RRV has been shown to be associated with nonHodgkin lymphoma and retroperitoneal fibromatosis in SIV-infected rhesus macaques.³⁴ Therefore, RRV infection in macaques is a highly useful animal model for the study of KSHV infection in humans, including studies of viral pathogenesis, factors affecting prevalence of infection, viral shedding, and transmission.^2,25,31,42 In addition, RRV is a persistent virus targeted for elimination in some specific pathogen free (SPF) macaque breeding populations. A better understanding of the natural history of RRV and RFHV infections will lead to improved characterization of host–virus interactions, contribute to the refinement of these nonhuman primate models, and allow more efficient management of SPF colonies.Here we report estimates of the prevalence of viremia and oral shedding of RRV and RFHV in large age-structured breeding colonies of rhesus macaques. Both viruses were highly endemic in the breeding populations we tested, and coinfection with both viruses was common.     

An Automated ELISA Using Recombinant Antigens for Serologic Diagnosis of B Virus Infections in Macaques

B virus (Macacine herpesvirus 1) occurs naturally in macaques and can cause lethal zoonotic infections in humans. Detection of B virus (BV) antibodies in macaques is essential for the development of SPF breeding colonies and for diagnosing infection in macaques that are involved in human exposures. Traditionally, BV infections are monitored for presence of antibodies by ELISA (a screening assay) and western blot analysis (WBA; a confirmatory test). Both tests use lysates of infected cells as antigens. Because WBA often fails to confirm the presence of low-titer serum antibodies detected by ELISA, we examined a recombinant-based ELISA as a potential alternative confirmatory test. We compared a high-throughput ELISA using 384-well plates for simultaneous antibody screening against 4 BV-related, recombinant proteins with the standard ELISA and WBA. The recombinant ELISA results confirmed more ELISA-positive sera than did WBA. The superiority of the recombinant ELISA over WBA was particularly prominent for sera with low (<500 ELISA units) antibody titers. Among low-titer sera, the relative sensitivity of the recombinant ELISA ranged from 36.7% to 45.0% as compared with 3.3% to 10.0% for WBA. In addition, the screening and confirmatory assays can be run simultaneously, providing results more rapidly. We conclude that the recombinant ELISA is an effective replacement for WBA as a confirmatory assay for the evaluation of macaque serum antibodies to BV.Abbreviations: BV, B virus (Macacine herpesvirus 1); EU, ELISA units; g, glycoprotein; HSV, herpes simplex virus; tELISA, titration ELISA; UN, uninfected; WBA, western blot analysisB virus (BV; Macacine herpesvirus 1) is a member of the genus Simplexvirus, subfamily Alphaherpesvirinae and family Herpesviridae. The virus occurs naturally in macaques (Macaca spp.) and causes a lethal zoonotic infection in 80% of untreated humans. Because biomedical professionals working with macaques, their cells, or tissues are at risk for becoming infected with BV, it is important to know the status of macaques involved in potential BV exposures. Although cases of BV infection after encounters between tourists and macaques have not been reported, any event that involves direct or fomite-associated contact with macaques has inherent risks. Identification of zoonotic BV infection through the detection of antibodies enables timely antiviral intervention, which is critical to reduce or prevent morbidity and mortality. Similarly rapid detection is important to maintain the biointegrity of SPF captive macaque colonies. The identification of BV in clinical specimens is achieved by using cell culture, PCR, or antibody detection methods. Because BV is shed only rarely from peripheral sites, the identification of BV infection in monkeys and humans currently is based on antibody detection (serology).^14,23,28In our laboratory, current serological diagnosis for B virus infections has been based on 2 principal tests: a titration-based (that is, traditional) ELISA (tELISA) as a screening test and western blot analysis (WBA) as a confirmatory test. Each test uses quality-controlled BV antigens that are prepared from lysates of infected cells.^20,22,23 Because BV is the only simplex virus in the Alphaherpesvirinae subfamily that is known to infect macaques,^14,28 antibodies interacting with BV antigens are used to indicate BV infection and not an infection due to a crossreacting virus. In practice, tELISA has identified numerous BV antibody-positive sera, the majority of which are low-titer sera from SPF colonies, which fail to be confirmed by WBA, and therefore, are classified as false positives.²³ We, therefore, searched for other approaches that could be used for confirmation of tELISA results. One reasonable option was the use of BV recombinant proteins as antigens. Numerous investigators have used recombinant-based assays for routine diagnosis of infections with viruses, including cytomegalovirus,³⁶ Epstein–Barr,⁶ herpes simplex (HSV1 and HSV2)^{2,3,17,31,32,34} Crimean–Congo hemorrhagic fever,¹⁰ HIV,³⁶ dengue,^5,11,27 hepatitis C,²⁴ hepatitis B,⁸ West Nile,²⁶ influenza,¹⁶ Ebola, and Marburg³³ viruses.Screening for the presence of serum IgG molecules against an array of defined and purified recombinant antigens has distinct advantages over assays that use the entire complement of viral antigens that are present in virus-infected cells. This is particularly true for pathogens that require BSL4 laboratories.^28,33 The pattern of reactivity obtained against each individual recombinant protein may have diagnostic value, by enabling identification of the stage of infection and the prediction of the prognosis of the disease.^3,4,18 However, using a single or only a few recombinant proteins as ELISA antigens can lead to a false-negative result if the antibody repertoire produced after BV infection reacts with other antigenic determinants that are not represented by the particular recombinant antigens used in the test.^{3,18,28,31,34}Several laboratories have examined the efficacy of using a single BV recombinant antigen (that is, glycoprotein D [gD]) for diagnosing BV infections in macaques^25,37 and humans,¹⁵ and we previously reported the diagnostic potential of an ELISA that incorporated several recombinant BV antigens.²⁸ We chose 4 recombinant BV glycoproteins as candidate antigens: peptides corresponding to the full-length extracellular domain of gB, gC, and gD and the membrane-associated segment of gG (gGm). Among these antigens, gGm was the most BV-specific, because it failed to crossreact with antibodies induced by HSV1 and HSV2. To validate the use of the recombinant BV antigens for the purpose of BV antibody detection, a panel of antibody-negative (n = 40) and antibody-positive (n = 75) macaque sera that were confirmed to be positive by tELISA and WBA were tested against the panel of the 4 B virus recombinant antigens, all of which showed fairly high sensitivity for detecting antibodies to BV.²⁸Here, we examine the performance of the recombinant-based ELISA (rELISA) for BV detection by using numerous (>1000) macaque sera, which have a broad range of antibody titers as determined by tELISA. Because manual ELISA to identify antibodies against an array of antigens are too laborious to be cost-effective, we adapted a previously described high-throughput automated single-antigen ELISA performed in 384-well plates to detect antibodies in macaque sera to multiple BV antigens.²³ This assay format has been adapted to include antigens from other alphaherpesviruses²³ and can be easily modified further for other viruses. We then compared the performance of the rELISA with that of whole-virus tELISA and WBA. The main goal of this study was to determine whether the 384-well rELISA is an effective alternative to WBA as a confirmatory assay for tELISA.     

Diagnosis of Amyloidosis and Differentiation from Chronic,Idiopathic Enterocolitis in Rhesus (Macaca mulatta) and Pig-Tailed (M. nemestrina) Macaques

Amyloidosis is a progressive and ultimately fatal disease in which amyloid, an insoluble fibrillar protein, is deposited inappropriately in multiple organs, eventually leading to organ dysfunction. Although this condition commonly affects macaques, there is currently no reliable method of early diagnosis. Changes in clinical pathology parameters have been associated with amyloidosis but occur in late stages of disease, are nonspecific, and resemble those seen in chronic, idiopathic enterocolitis. A review of animal records revealed that amyloidosis was almost always diagnosed postmortem, with prevalences of 15% and 25% in our rhesus and pig-tailed macaque colonies, respectively. As a noninvasive, high-throughput diagnostic approach to improve antemortem diagnosis of amyloidosis in macaques, we evaluated serum amyloid A (SAA), an acute-phase protein and the precursor to amyloid. Using necropsy records and ELISA analysis of banked serum, we found that SAA is significantly elevated in both rhesus and pig-tailed macaques with amyloid compared with those with chronic enterocolitis and healthy controls. At necropsy, 92% of rhesus and 83% of pig-tailed had amyloid deposition in either the intestines or liver. Minimally invasive biopsy techniques including endoscopy of the small intestine, mucosal biopsy of the colon, and ultrasound-guided trucut biopsy of the liver were used to differentiate macaques in our colonies with similar clinical presentations as either having amyloidosis or chronic, idiopathic enterocolitis. Our data suggest that SAA can serve as an effective noninvasive screening tool for amyloidosis and that minimally invasive biopsies can be used to confirm this diagnosis.Abbreviations: SAA, serum amyloid AAmyloidosis is a pathologic condition that occurs spontaneously in humans, mammals, birds, and reptiles.⁴⁷ Secondary systemic amyloidosis, also referred to as reactive amyloidosis, is the most common form described in domestic animals.⁴⁶ It is a progressive disease in which an insoluble fibrillar protein consisting of β pleated sheets, amyloid, is deposited inappropriately in multiple organs, eventually leading to dysfunction.^40,46 Secondary amyloidosis is most often the result of chronic infections or inflammatory disease. In humans, it occurs with a wide variety of conditions including inflammatory bowel disease,³ osteoarthritis including rheumatoid and juvenile forms,^20,25 chronic infections such as tuberculosis, and hereditary disease such as familial Mediterranean fever.⁴³ Similarly, in nonhuman primates, the disease has been described with several conditions of chronic infection or inflammation including bacterial enterocolitis,^4,19,30,37 chronic indwelling catheters,⁹ parasitism,^2,4 respiratory disease,^30,37 trauma,³⁷ and rheumatoid arthritis.⁶Despite reported prevalences as high as 30% in rhesus (Macaca mulatta)⁴ and 47% in pig-tailed macaques (Macaca nemestrina),¹⁹ amyloidosis remains a challenge to diagnose. The current diagnostic ‘gold standard’ in macaques is histopathology of the affected organ;¹⁹ however, amyloid can be deposited in tissues for as long as 3 y before the development of clinical signs.¹⁶ Histologic diagnoses of amyloidosis typically are confirmed with Congo red staining, in which amyloid proteins appear apple-green and birefringent under polarized light. In addition, electron microscopy can detect the fibrillar amyloid proteins in tissues, and other histologic stains including methyl violet, sulphonated Alcian blue, and thioflavin S and T can be used but are less specific than is Congo red.³³ Although changes in clinical pathology parameters such as decreases in serum albumin and total protein have been associated with amyloidosis,^19,29 they are often nonspecific and resemble those seen in the frequently comorbid conditions chronic anorexia and chronic, idiopathic enterocolitis. Furthermore, imaging techniques such as abdominal X-ray and ultrasonography have been shown to be nondiagnostic in macaques with amyloidosis.¹⁹ Consequently, at our institution and in other macaque colonies, diagnosis of amyloidosis is often made at necropsy.The current standard of diagnosis in humans is biopsy with histopathology of affected organs, but unlike in nonhuman primates, minimally invasive tissue sampling has been extensively explored.¹⁷ Aspiration or biopsy of the subcutaneous abdominal fat pad has currently replaced many biopsy techniques as the preliminary diagnostic, with reported sensitivities ranging from 66% to 92%.^{5,24,28,39,44} Rectal biopsy was previously the preferred minimally invasive approach and is now often used adjunctively when subcutaneous abdominal fat is negative for amyloid but the clinical suspicion for amyloidosis remains high.^5,17 Additional tissue biopsy sites with limited morbidity such as skin, gingiva, and stomach have been reported with lesser sensitivities.^5,34,39,44 In contrast, limited information is published on the usefulness of minimally invasive biopsy techniques for diagnosing amyloidosis in macaques. One report found endoscopic biopsy of the stomach and colon to be of limited utility in diagnosing amyloidosis in a colony of pig-tailed macaques.¹⁹ Similarly, a single publication reported colonoscopy to be noninformative and labor-intensive in a colony of rhesus macaques.¹⁵ Retrospective studies of macaque colonies have shown a predilection for amyloid deposition in the intestines and liver,^4,30,38 suggesting that endoscopic or percutaneous biopsy of these tissues may reliably provide definitive antemortem diagnosis for amyloidosis.In addition to biopsy, identification of the relevant amyloid precursor protein within the blood is an integral part of the diagnosis of amyloidosis in human patients¹⁷ and holds promise as a screening tool in macaque colonies because of its high throughput potential in comparison to biopsy. Serum amyloid A (SAA), an acute-phase protein, can be found circulating in the blood and is the precursor for amyloid formation and deposition in secondary systemic amyloidosis. Specifically, when elevated SAA persists in the bloodstream, it ultimately progresses to amyloid deposition in tissues.^13,45 Profound elevations in SAA occur in the bloodstream as a result of acute inflammation, but these elevations are transient as SAA then is rapidly degraded and removed from the peripheral circulation.^7,45 Although the exact role of chronic inflammation and SAA in the pathogenesis of secondary, systemic amyloidosis is not well understood, SAA is pathologically persistently elevated in human patients with chronic inflammatory disease that develop secondary systemic amyloidosis. In contrast, serum SAA remains at normal lower levels in human patients without amyloidosis but ongoing chronic inflammatory disease.^13,14,26 Furthermore, quantification of SAA is more effective than are organ function tests as a prognostic measure of amyloid disease and is routinely used to monitor disease progression and response to treatment in humans.¹⁴ In rhesus and pig-tailed macaques, SAA is elevated in subjects with amyloidosis as compared with those that are clinically normal.^8,19 The ability to distinguish between healthy animals and those with subclinical amyloidosis would be clinically useful. Human studies indicate that establishing a diagnosis of secondary amyloidosis in its early stages followed by prompt treatment of the inciting chronic inflammatory process can arrest the progression of amyloidosis and can even result in disease remission in some cases.^{21,23,31,32,36} Of equal interest would be the ability to distinguish amyloidosis from chronic, idiopathic enterocolitis, a common disease among macaque colonies^12,35 that has considerable clinical overlap with the late stages of amyloidosis but different therapeutic options and prognosis than does systemic amyloidosis. Although there is no definitive treatment for amyloidosis in humans or macaques, recent human case reports suggest that antiinflammatory therapy with newer targeted monocolonal antibody medications, such as IL6 receptor antagonists, can successfully reverse the disease. This outcome has been demonstrated in several cases by both the reduction of circulating SAA to normal levels and by the histologic disappearance of amyloid proteins in biopsies of affected tissues.^{21,23,31,32,36} Accurate antemortem diagnosis of amyloidosis in macaques potentially would support further investigations into the novel application of these drugs for the treatment of amyloidosis in both human and macaque patients.We hypothesize that SAA, in addition to being a useful screening method for identifying animals with amyloidosis, can be used to distinguish between macaques with this disease and those with chronic, idiopathic enterocolitis. We further hypothesize that, in agreement with retrospective studies from macaques at other institutions, the intestines and liver will be commonly affected in amyloidotic macaques in our own colonies and that minimally invasive biopsy of these tissues can provide definitive, antemortem diagnosis of amyloidosis.     

Self-Injurious Behavior Secondary to Cytomegalovirus-Induced Neuropathy in an SIV-Infected Rhesus Macaque (Macaca mulatta)

A 3.5-y-old, female rhesus macaque (Macaca mulatta) inoculated with SIVmac239 presented 8 mo later for inappetence and facial bruising. Physical examination revealed a superficial skin abrasion below the left eye, bruising below the left brow, and epistaxis of the left nostril. There were no significant findings on CBC, serum chemistry, urinalysis, or radiographs. Differential diagnoses included infectious etiologies, self-injurious behavior, immune-mediated dermatitis, and neoplasia. Lack of response to antibiotic and analgesic therapy and observations of the macaque made it apparent that the skin lesions were self-inflicted. The excoriations rapidly progressed to extend over the nose, and the left palpebrae became edematous. Euthanasia was elected because the macaque appeared to be experiencing continued discomfort despite analgesic therapy. Histopathologic examination revealed systemic cytomegalovirus (CMV) infection involving the facial nerves, periocular nerves, meninges, and perimesenteric lymph nodes. CMV is a common infection in macaques, with adult seroprevalence close to 100% in most colonies. Infection in immunocompetent animals is usually asymptomatic but can cause significant clinical disease in immunodeficient hosts. CMV is associated with a painful peripheral neuropathy in human AIDS patients, and analgesic treatment is often unsatisfactory. Peripheral neuropathy secondary to CMV should be considered as an underlying cause of self-injurious behavior in SIV-infected macaques. Macaques affected by other diseases and disorders may also be at risk for development of painful peripheral neuropathies.Abbreviations: CMV, cytomegalovirus; HCMV, human CMV; RhCMV, rhesus CMV; SIB, self-injurious behaviorRhesus macaques (Macaca mulatta) are one of the most commonly used NHP species in biomedical research.^9,25 They generally adapt well to captivity, but some develop abnormal behaviors such as stereotypies and self-injurious behavior (SIB).³² Examples of SIB include excessive hair-plucking, head banging, and self-biting that causes wounds in some cases.³² Self-inflicted wounding has been reported in 11% to 14% of individually housed rhesus macaques and can be difficult to manage.^26,32,39 The most commonly discussed risk factors for the development of SIB are related to housing and management, and little is known about potential physiologic causes, such as neuropathic pain.^18,26,32 Compulsive SIB directed toward a specific body part due to neuropathic pain or pruritus occurs in humans.^12,28Rhesus cytomegalovirus (RhCMV) is enzootic in rhesus macaques with close to 100% seroprevalence by 1 y of age in both wild and captive populations.^22,42 As with human cytomegalovirus (HCMV), RhCMV infection is generally subclinical in immunocompetent animals but can cause serious disease in immunodeficient macaques.⁸ RhCMV can be highly pathogenic in SIV-infected animals, and HCMV is the most common viral opportunistic infection in humans with AIDS.^8,37 HCMV infection has been associated with painful peripheral neuropathies in AIDS patients.^17,36,37 We here report a case of SIB associated with RhCMV-induced peripheral neuropathy in an immunocompromised macaque.     

Clinical and Pathologic Features of Cynomolgus Macaques (Macaca fascicularis) Infected with Aerosolized Yersinia pestis

Since the anthrax attacks of 2001, the emphasis on developing animal models of aerosolized select agent pathogens has increased. Many scientists believe that nonhuman primate models are the most appropriate to evaluate pulmonary response to, vaccines for, and treatments for select agents such as Yersinia pestis (Y. pestis), the causative agent of plague. A recent symposium concluded that the cynomolgus macaque (Macaca fascicularis) plague model should be characterized more fully. To date, a well-characterized cynomolgus macaque model of pneumonic plague using reproducible bioaerosols of viable Y. pestis has not been published. In the current study, methods for creating reproducible bioaerosols of viable Y. pestis strain CO92 (YpCO92) and pneumonic plague models were evaluated in 22 Indonesian-origin cynomolgus macaques. Five macaques exposed to doses lower than 250 CFU remained free of any indication of plague infection. Fifteen macaques developed fever, lethargy, and anorexia indicative of clinical plague. The 2 remaining macaques died without overt clinical signs but were plague-positive on culture and demonstrated pathology consistent with plague. The lethal dose of plague in humans is reputedly less than 100 organisms; in this study, 66 CFU was the dose at which half of the macaques developed fever and clinical signs (ED₅₀), The Indonesian cynomolgus macaque reproduces many aspects of human pneumonic plague and likely will provide an excellent model for studies that require a macaque model.Yersinia pestis is the causative agent of plague. Likely more people worldwide have died from Y. pestis infections than from any other single infectious disease.^26,27 Bubonic plague, the most common form of the disease, results when the bacterium is inoculated into the skin, typically by means of flea bites. The resulting cutaneous infection spreads to local lymph nodes; the swollen lymph nodes are known as bubos and often serve as a source of systemic infection. Although less common, the bacterium also can spread by aerosol, causing pneumonic plague. Pneumonic plague can result from pulmonary spread of systemic infection or from deliberate dissemination and is associated with nearly 100% human mortality if left untreated. Y. pestis is susceptible to commonly available antibiotics if treatment begins soon after infection. However, depending on the route of infection, the time at which infection is confirmed is often too late for antibiotics to prevent significant morbidity or mortality.¹⁰ Because pneumonic plague is the form most likely to be seen in bioterrorism events,¹⁶ interest in animal models has arisen to support development of vaccines and improved therapeutics.Potential vaccines and therapeutic agents for plague must protect against the pneumonic disease, but contemporary published data regarding disease pathogenesis using aerosolized Y. pestis pathogenesis in nonhuman primates are scant.^4,9,21,23,24 In the United States, when vaccine or antibiotic efficacy cannot be evaluated in humans, an animal species that is reasonably expected to recapitulate human disease must be used.⁹ For many biothreat agents such as plague, a nonhuman primate model often is required. Although some laboratories have examined the cynomolgus macaque model of aerosolized plague briefly,¹ no published reports fully characterize this model. Published studies have examined plague in the African green monkey or vervet (Chlorocebus spp., formerly Cercopithecus aethiops) and rhesus macaque (Macaca mulatta).¹ Vervets reportedly are more sensitive to plague than are macaques,^4,24 such that some vervets are susceptible to infection with vaccine strains, casting some doubt on applicability of this species for plague studies.¹ The disease in rhesus macaques differs from that in humans in that rhesus macaques frequently develop disseminated intravascular coagulation (DIC) and chronic pneumonia as a result of pneumonic plague while humans usually develop acute pneumonia without DIC.^1,7Many participants at a recent symposium sponsored by the Food and Drug Administration and National Institute of Allergy and Infectious Disease endorsed the development of a cynomolgus macaque pneumonic plague model to support plague therapeutic and vaccine studies.⁸ The current study was undertaken to evaluate the Indonesian cynomolgus macaque as a model of aerosolized Y. pestis Colorado 92 (YpCO92) for subsequent vaccine and therapeutic trials. We also sought to determine whether fever development could be used to determine a humane endpoint to the study, as an alternative to LD₅₀ methods.     

Oral Squamous Cell Carcinoma in a Pigtailed Macaque (Macaca nemestrina)

An adult, gravid, female pigtailed macaque (Macaca nemestrina) presented for facial swelling centered on the left mandible that was approximately 5 cm wide. Differential diagnoses included infectious, inflammatory, and neoplastic origins. Definitive antemortem diagnosis was not possible, and the macaque''s condition worsened despite supportive care. Necropsy findings included a mandibular mass that was locally invasive and expansile, encompassing approximately 80% of the left mandibular bone. The mass replaced portions of the soft palate, hard palate, sinuses, ear canal, and the caudal–rostral calvarium and masseter muscle. Histologically, the mass was a neoplasm that was poorly circumscribed, unencapsulated, and infiltrative invading regional bone and soft tissue. The mass consisted of polygonal squamous epithelial cells with intercellular bridging that breached the epithelial basement membrane and formed invasive nests, cords, and trabeculae. The mitotic rate averaged 3 per 400× field of view, with occasional bizarre mitotic figures. Epithelial cells often exhibited dyskeratosis, and the nests often contained compact lamellated keratin (keratin pearls). The neoplasm was positive via immunohistochemistry for pancytokeratin, variably positive for S100, and negative for vimentin, smooth muscle actin, and desmin. The gross, histologic, and immunohistochemical findings were consistent with an aggressive oral squamous cell carcinoma. The neoplasm was negative via PCR for papilloma virus. In general, neoplasia in macaques is rare. Although squamous cell carcinomas are one of the most common oral neoplasia in many species, to our knowledge this case represents the first reported oral squamous cell carcinoma in a pigtailed macaque.Abbreviation: SCC, squamous cell carcinomaSquamous cell carcinomas (SCC) are one of the most commonly reported oral tumors. They are characterized as firm, nodular to irregular, soft-tissue masses that are often ulcerated.⁶ These tumors are frequently highly invasive to local bone and muscle and occasionally metastasize to local and regional lymph nodes.⁶ Histologically, SCC are characterized by keratin pearls, intercellular bridges, and positive cytokeratin staining on immunohistochemistry.^6,18 SCC have been associated with carcinogen exposure (such as bracken fern toxicosis in cattle), actinic radiation, and rarely with papillomatosis.⁸In general, neoplastic diseases are rare in nonhuman primates, and SCC and lymphoma are the 2 most commonly reported oral neoplasms in these species.³ SCC have most commonly been reported in rhesus macaques (Macaca mullata) and baboons (Papio spp.) among nonhuman primate species.⁹ In rhesus macaques, SCC has occurred in the oral cavity,⁹ integument,^9,22 esophagus,⁹ stomach,²¹ lung,^9,13 prepuce–penis,¹⁰ cervix,⁹ uterus,⁹ and eye.⁹ These neoplasms have also been reported to occur in cynomolgus macaques,^14,15,17,19 marmosets, squirrel monkeys, tree shrews, capuchins, tamarins, black spider monkeys, sooty mangabies, a spectacled langur, and an orangutan.⁹ No report describing SCC in a pig-tailed macaque has been published previously. The oral cavity is the most common site of SCC in nonhuman primates, and metastasis occurs in approximately 23% of cases.⁹ The average age at diagnosis of oral SCC in rhesus macaques is 17.6 y.²² In baboons, SCC is the third most common neoplasm, after intestinal adenocarcinoma and lymphosarcoma.⁴ The following case report describes an oral SCC in a pregnant pig-tailed macaque.