Detection of TT virus among chimpanzees in the wild using a noninvasive technique

Zoonotic transmission and emergence of pathogens are serious threats to endangered populations of free-ranging primate species. Recent discovery of a nonpathogenic yet highly prevalent virus in human populations, TT virus (TTV), has prompted studies into the presence of this virus among captive individuals of other species of nonhuman primates. In this study, we screened captive primate species for TTV. In addition, we provide the first data on TTV infectionin free-ranging primates by noninvasive screening of three chimpanzee (Pan troglodytes sweinfurthii) commlunities. Phylogenetic relationships between virus isolates and those previously reported from hulman popullations, captive primates, and domesticated species are inferred. Our findings are discussed with respect to potential zoonotic events that may result from increased levels of human encroachlment into wild habitats.     

Optimization of a Novel Non-invasive Oral Sampling Technique for Zoonotic Pathogen Surveillance in Nonhuman Primates

Free-ranging nonhuman primates are frequent sources of zoonotic pathogens due to their physiologic similarity and in many tropical regions, close contact with humans. Many high-risk disease transmission interfaces have not been monitored for zoonotic pathogens due to difficulties inherent to invasive sampling of free-ranging wildlife. Non-invasive surveillance of nonhuman primates for pathogens with high potential for spillover into humans is therefore critical for understanding disease ecology of existing zoonotic pathogen burdens and identifying communities where zoonotic diseases are likely to emerge in the future. We developed a non-invasive oral sampling technique using ropes distributed to nonhuman primates to target viruses shed in the oral cavity, which through bite wounds and discarded food, could be transmitted to people. Optimization was performed by testing paired rope and oral swabs from laboratory colony rhesus macaques for rhesus cytomegalovirus (RhCMV) and simian foamy virus (SFV) and implementing the technique with free-ranging terrestrial and arboreal nonhuman primate species in Uganda and Nepal. Both ubiquitous DNA and RNA viruses, RhCMV and SFV, were detected in oral samples collected from ropes distributed to laboratory colony macaques and SFV was detected in free-ranging macaques and olive baboons. Our study describes a technique that can be used for disease surveillance in free-ranging nonhuman primates and, potentially, other wildlife species when invasive sampling techniques may not be feasible.     

Primates and the Ecology of their Infectious Diseases: How will Anthropogenic Change Affect Host‐Parasite Interactions?

The sudden appearance of diseases like SARS (severe acute respiratory syndrome 1 ), the devastating impacts of diseases like Ebola on both human and wildlife communities, 2 , 3 and the immense social and economic costs created by viruses like HIV 4 underscore our need to understand the ecology of infectious diseases. Given that monkeys and apes often share parasites with humans, understanding the ecology of infectious diseases in nonhuman primates is of paramount importance. This is well illustrated by the HIV viruses, the causative agents of human AIDS, which evolved recently from related viruses of chimpanzees (Pan troglodytes) and sooty mangabeys (Cercocebus atys 5 ), as well as by the outbreaks of Ebola virus, which trace their origins to zoonotic transmissions from local apes. 6 A consideration of how environmental change may promote contact between humans and nonhuman primates and thus increase the possibility of sharing infectious diseases detrimental to humans or nonhuman primates is now paramount in conservation and human health planning.     

Application of PCR ribotyping and tDNA-PCR for Klebsiella pneumoniae identification

PCR analysis of 16S-23S internal transcribed spacer (PCR ribotyping) and tRNA intergenic spacer (tDNA-PCR) were evaluated for their effectiveness in identification of clinical strains of Klebsiella pneumoniae and differentiation with related species. For this purpose both methods were applied to forty-three clinical isolates biochemically identified as K. pneumoniae subsp. pneumoniae isolated from patients clinical specimens attended at five hospitals in three Brazilian cities. References strains of K. pneumoniae subsp. pneumoniae, K. pneumoniae subsp. ozaenae, K. oxytoca, K. planticola and Enterobacter aerogenes were also analyzed. Both PCR methods showed specific patterns for each species. A conserved PCR ribotype pattern was observed for all clinical K. pneumoniae isolates, while differing from other related analyzed species. tDNA-PCR revealed five distinct patterns among the K. pneumoniae clinical isolates studied, demonstrating a predominant group with 90.6% of isolates presenting the same pattern of K. pneumoniae type strain. Both PCR-based methods were not able to differentiate K. pneumoniae subspecies. On the basis of the results obtained, both methods were efficient to differentiate the Klebsiella species analyzed, as well as E. aerogenes. Meanwhile tDNA-PCR revealed different tRNA arrangements in K. pneumoniae, suggesting intra-species heterogeneity of their genome organization, the polymorphism of the intergenic spacers between 16S and 23S rRNA genes appears to be highly conserved whithin K. pneumoniae clinical isolates, showing that PCR ribotyping can be an useful tool for identification of K. pneumoniae isolates.     

TT virus infection in nonhuman primates and characterization of the viral genome: identification of simian TT virus isolates

Newly discovered TT virus (TTV) is widely distributed in human populations. To understand more about the relationship between TTV and its hosts, we tested 400 sera from various nonhuman primates for the presence of TTV DNA by PCR assay. We collected serum samples from 24 different species of nonhuman primates. TTV DNA was determined by PCR with primers designed from the 5'-end region of the TTV genome. Nucleotide sequencing and phylogenetic analysis of viral genomes were also performed. TTV DNA was detected in 87 of 98 (89%) chimpanzees and 3 of 21 (14%) crab-eating macaques. Nucleotide sequences of the PCR products obtained from both animals were 80 to 100% identical between two species. In contrast, the sequences differed from TTV isolates in humans by 24 to 33% at the nucleotide level and 36 to 50% at the amino acid level. Phylogenetic analysis demonstrated that all TTV isolates obtained from simians were distinct from the human TTV isolates. Furthermore, TTV in simians, but not in humans, was classified into three different genotypes. Our results indicate that TTV in simians represents a group different from, but closely related to, TTV in humans. From these results, we tentatively named this TTV simian TTV (s-TTV). The existence of the s-TTV will be important in determining the origin, nature, and transmission of human TTV and may provide useful animal models for studies of the infection and pathogenesis of this new DNA virus.     

Epidemiology of Invasive Klebsiella pneumoniae with Hypermucoviscosity Phenotype in a Research Colony of Nonhuman Primates

Invasive Klebsiella pneumoniae with hypermucoviscosity phenotype (HMV K. pneumoniae) is an emerging human pathogen that, over the past 20 y, has resulted in a distinct clinical syndrome characterized by pyogenic liver abscesses sometimes complicated by bacteremia, meningitis, and endophthalmitis. Infections occur predominantly in Taiwan and other Asian countries, but HMV K. pneumoniae is considered an emerging infectious disease in the United States and other Western countries. In 2005, fatal multisystemic disease was attributed to HMV K. pneumoniae in African green monkeys (AGM) at our institution. After identification of a cluster of subclinically infected macaques in March and April 2008, screening of all colony nonhuman primates by oropharyngeal and rectal culture revealed 19 subclinically infected rhesus and cynomolgus macaques. PCR testing for 2 genes associated with HMV K. pneumoniae, rmpA and magA, suggested genetic variability in the samples. Random amplified polymorphic DNA analysis on a subset of clinical isolates confirmed a high degree of genetic diversity between the samples. Environmental testing did not reveal evidence of aerosol or droplet transmission of the organism in housing areas. Further research is needed to characterize HMV K. pneumoniae, particularly with regard to genetic differences among bacterial strains and their relationship to human disease and to the apparent susceptibility of AGM to this organism.Abbreviations: AGM, African green monkey; HMV K. pneumoniae, invasive Klebsiella pneumoniae with hypermucoviscosity phenotype; NHP, nonhuman primate; RAPD, random amplification of polymorphic DNAKlebsiella pneumoniae is an enteric, gram-negative, lactose-fermenting bacillus with a prominent capsule. This bacterium has been associated with peritonitis, septicemia, pneumonia, and meningitis in both Old and New World primates,^10,13,29 although it also is reported to constitute normal fecal and oral flora in many nonhuman primates (NHP).¹² Pathogenic strains associated with the upper respiratory tract typically are heavily encapsulated.¹² Over the past several decades, human medical literature indicates the emergence of an invasive K. pneumoniae disease in Taiwan and other Asian countries, in which community-acquired pyogenic liver abscesses have been attributed to strains of invasive K. pneumoniae with a unique hypermucoviscous phenotype (HMV K. pneumoniae).^{6,17-19,21,26,34} The hypermucoviscous phenotype has also been associated with other serious complications, including bacteremia, meningitis, and endophthalmitis. This strain of Klebsiella has become an emerging cause of pyogenic liver abscesses in some nonAsian countries, including the United States.^16,20,36,39 The majority of clinical cases of HMV K. pneumoniae are in the Asian population, particularly in patients with diabetes mellitus.^3,4,33 Determination of the HMV phenotype typically is based on a positive string test.^8,35,39Several virulence factors have been associated with HMV K. pneumoniae. Klebsiella spp. generally develop prominent polysaccharide capsules which increase virulence by protecting the bacteria from phagocytosis and preventing destruction by bactericidal serum factors. Capsular serotypes K1 or K2 have been reported as the major virulence determinants for human HMV K. pneumoniae liver abscesses.^5,8,37,38 In addition, the mucoviscosity-associated gene magA, which encodes a structural outer membrane protein of the K1 serotype, and rmpA (regulator of the mucoid phenotype gene; located on a plasmid) have been proposed as virulence factors.^{9,27,31,40,41} Recently, it was suggested that 2 clones, CC23 ^K1 and CC82^K1, are strongly associated with primary liver abscess and respiratory infection, respectively.²Over a period of several months in 2005 to 2006, 7 African green monkeys (AGM; Chlorocebus aethiops) in the US Army Medical Research Institute of Infectious Diseases research colony developed abscesses in multiple locations and either died or were euthanized when the abscesses were determined to be nonresectable.³⁵ HMV K. pneumoniae of the K2 serotype and carrying rmpA was determined to be the cause of the infection in 1 case, and the 6 other cases had similar clinical and pathologic features. This report³⁵ is the only documentation, to our knowledge, of natural infection with HMV K. pneumoniae in NHP. As a result of these cases, the US Army Medical Research Institute of Infectious Diseases instituted policies to exclude HMV K. pneumoniae from the colony. The organism was included as a specific pathogen-free requirement for vendors, and K. pneumoniae culture results were reported during quarantine periods and on routine semiannual examination for all colony NHP.     

Zoonotic Potential of Simian Arteriviruses

Wild nonhuman primates are immediate sources and long-term reservoirs of human pathogens. However, ethical and technical challenges have hampered the identification of novel blood-borne pathogens in these animals. We recently examined RNA viruses in plasma from wild African monkeys and discovered several novel, highly divergent viruses belonging to the family Arteriviridae. Close relatives of these viruses, including simian hemorrhagic fever virus, have caused sporadic outbreaks of viral hemorrhagic fever in captive macaque monkeys since the 1960s. However, arterivirus infection in wild nonhuman primates had not been described prior to 2011. The arteriviruses recently identified in wild monkeys have high sequence and host species diversity, maintain high viremia, and are prevalent in affected populations. Taken together, these features suggest that the simian arteriviruses may be “preemergent” zoonotic pathogens. If not, this would imply that biological characteristics of RNA viruses thought to facilitate zoonotic transmission may not, by themselves, be sufficient for such transmission to occur.     

Opportunistic infections in immunologically compromised nonhuman primates

Despite advances in the husbandry of nonhuman primates, natural and experimentally induced diseases continue to pose risks to animal health. These risks are particularly important when such disease results in immunodeficient states that provide an opportunity for the development of opportunistic infections. Because opportunistic agents may serve as significant confounders to research and hold potential for zoonotic transmission, knowledge of disease pathogenesis, surveillance, and risk reduction is particularly important to individuals who work closely with primates. Endogenous diseases of primates that result in blunted immune responses and thus allow for the development of opportunistic infection include simian type D retroviruses and measles. In addition, simian immunodeficiency virus is a frequently studied experimental cause of immunosuppression. This article focuses on clinical and pathological aspects of the most common opportunistic infections that occur in nonhuman primates maintained in research settings. The complete elimination of all infectious agents from primate colonies may be impossible and unwarranted, but microbial surveillance programs can help both to define the complement of agents present in a colony and to elucidate their potential impacts on colony health, zoonotic risk, and experimental research. We discuss risk reduction through the use of quarantine procedures, specific pathogen-free animals, and environmental controls.     

Nonhuman primates and the acquired immunodeficiency syndrome: a union of necessity

Because of the close phylogenetic relationship, nonhuman primates are highly susceptible to human pathogens, including infection of chimpanzees by the human immunodeficiency virus (HIV), the causative agent of AIDS. This, and the existence of a highly related simian virus, SIV, which causes an AIDS-like disease in macaques, emphasizes the continued importance of using nonhuman primates as model systems for identifying and developing prophylaxis and therapy for infectious agents and, in particular, for fighting the pandemic AIDS.     

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.     

Hepadnavirus infection in captive gibbons

The recent isolation of a nonhuman primate hepadnavirus from woolly monkeys prompted an examination of other primates for potentially new hepadnaviruses. A serological analysis of 30 captive gibbons revealed that 47% were positive for at least one marker of ongoing or previous infection with a hepatitis B virus (HBV). The amino acid sequences of the core and surface genes of human and gibbon virus isolates were very similar. Phylogenetic analysis indicated that the gibbon isolates lie within the human HBV family, indicating that these HBV isolates most likely stem from infection of gibbons from a human source.     

Molecular characterization of nodule worm in a community of Bornean primates

Strongyles are commonly reported parasites in studies of primate parasite biodiversity. Among them, nodule worm species are often overlooked as a serious concern despite having been observed to cause serious disease in nonhuman primates and humans. In this study, we investigated whether strongyles found in Bornean primates are the nodule worm Oesophagostomum spp., and to what extent these parasites are shared among members of the community. To test this, we propose two hypotheses that use the parasite genetic structure to infer transmission processes within the community. In the first scenario, the absence of parasite genetic substructuring would reflect high levels of parasite transmission among primate hosts, as primates’ home ranges overlap in the study area. In the second scenario, the presence of parasite substructuring would suggest cryptic diversity within the parasite genus and the existence of phylogenetic barriers to cross‐species transmission. By using molecular markers, we identify strongyles infecting this primate community as O. aculeatum, the only species of nodule worm currently known to infect Asian nonhuman primates. Furthermore, the little to no genetic substructuring supports a scenario with no phylogenetic barriers to transmission and where host movements across the landscape would enable gene flow between host populations. This work shows that the parasite's high adaptability could act as a buffer against local parasite extinctions. Surveys targeting human populations living in close proximity to nonhuman primates could help clarify whether this species of nodule worm presents the zoonotic potential found in the other two species infecting African nonhuman primates.     

Basic considerations in assessing and preventing occupational infections in personnel working with nonhuman primates

Transmission of zoonotic infections of nonhuman primates to human contacts is a documented occupational hazard. Although the list of naturally occurring and experimentally induced infections of nonhuman primates is extensive the risks of transmission may substantially be reduced by the use of good animal care practices, appropriate protective measures and devices, and suitable animal facilities. The essential elements of good animal care practices include high levels of personal hygiene; minimizing the creation of potentially infectious aerosols and droplets; use of personal protective clothing, devices, and vaccines; a system for reporting, evaluating, and treatment of occupational exposures and infections; and animal facilities appropriate for the species being used and the activities conducted. These essential elements are described and discussed in the context of published voluntary codes of practice--notably "Biosafety in Microbiological and Biomedical Laboratories."     

PCR-based identification of Klebsiella pneumoniae subsp. rhinoscleromatis, the agent of rhinoscleroma

Rhinoscleroma is a chronic granulomatous infection of the upper airways caused by the bacterium Klebsiella pneumoniae subsp. rhinoscleromatis. The disease is endemic in tropical and subtropical areas, but its diagnosis remains difficult. As a consequence, and despite available antibiotherapy, some patients evolve advanced stages that can lead to disfiguration, severe respiratory impairment and death by anoxia. Because identification of the etiologic agent is crucial for the definitive diagnosis of the disease, the aim of this study was to develop two simple PCR assays. We took advantage of the fact that all Klebsiella pneumoniae subsp. rhinoscleromatis isolates are (i) of capsular serotype K3; and (ii) belong to a single clone with diagnostic single nucleotide polymorphisms (SNP). The complete sequence of the genomic region comprising the capsular polysaccharide synthesis (cps) gene cluster was determined. Putative functions of the 21 genes identified were consistent with the structure of the K3 antigen. The K3-specific sequence of gene Kr11509 (wzy) was exploited to set up a PCR test, which was positive for 40 K3 strains but negative when assayed on the 76 other Klebsiella capsular types. Further, to discriminate Klebsiella pneumoniae subsp. rhinoscleromatis from other K3 Klebsiella strains, a specific PCR assay was developed based on diagnostic SNPs in the phosphate porin gene phoE. This work provides rapid and simple molecular tools to confirm the diagnostic of rhinoscleroma, which should improve patient care as well as knowledge on the prevalence and epidemiology of rhinoscleroma.     

埃博拉出血热及埃博拉病毒的研究进展

埃博拉病毒可以引起一种人畜共患烈性传染病,即埃博拉出血热,此病于1976年始发于埃博拉河流域,并且于该区域严重流行,故而得名。人类一旦感染埃博拉病毒,死亡率可高达88%,从而引起医学界的广泛关注,世界卫生组织已将埃博拉病毒列为对人类危害最为严重的病毒之一。深入地了解埃博拉出血热及埃博拉病毒,及其致病机理,对于埃博拉出血热的预防和控制具有非常重要的意义。     

Nonhuman primate transgenesis: progress and prospects

The nonhuman primate is used extensively in biomedical research owing to its close similarities to human physiology and human disease pathophysiology. Recently, several groups have initiated efforts to genetically manipulate nonhuman primates to address complex questions concerning primate-specific development and physiological adaptation. Primates pose unique challenges to transgenesis and, although this field is still in its infancy, the potential for obtaining new insights into primate physiology and gene function is unprecedented. This review focuses on the methods and potential applications of genetically altered nonhuman primates in biomedical research.     

Antibiotic susceptibility and genotype patterns of Escherichia coli, Klebsiella pneumoniae and Pseudomonas aeruginosa isolated from urinary tract infected patients

Thirty nine isolates of Escherichia coli, twenty two isolates of Klebsiella pneumoniae and sixteen isolates of Pseudomonas aeruginosa isolated from urinary tract infected patients were analyzed by antimicrobial susceptibility typing and random amplified polymorphic DNA (RAPD)-PCR. Antibiotic susceptibility testing was carried out by microdilution and E Test methods. From the antibiotic susceptibility, ten patterns were recorded (four for E. coli, three for K. pneumoniae and three for P. aeruginosa respectively). Furthermore, genotyping showed seventeen RAPD patterns (seven for E. coli, five for K. pneumoniae and five for P. aeruginosa respectively). In this study, differentiation of strains of E. coli, K. pneumoniae and P. aeruginosa from nosocomial infection was possible with the use of RAPD.     

Advantages and limitations of nonhuman primates as animal models in genetic research on complex diseases

Abstract: The genetic similarity between humans and nonhuman primates makes nonhuman primates uniquely suited as models for genetic research on complex physiological and behavioral phenotypes. By comparison with human subjects, nonhuman primates, like other animal models, have several advantages for these types of studies: 1) constant environmental conditions can be maintained over long periods of time, greatly increasing the power to detect genetic effects; 2) different environmental conditions can be imposed sequentially on individuals to characterize genotype-environment interactions; 3) complex pedigrees that are much more powerful for genetic analysis than typically available human pedigrees can be generated; 4) genetic hypotheses can be tested prospectively by selective matings; and 5) essential invasive and terminal experiments can be conducted. Limitations of genetic research with nonhuman primates include cost and availability. However, the ability to manipulate both genetic and environmental factors in captive primate populations indicates the promise of genetic research with these important animal models for illuminating complex disease processes. The utility of nonhuman primates for biomedical research on human health problems is illustrated by examples concerning the use of baboons in studies of osteoporosis, alcohol metabolism, and lipoproteins.     

Development of Y-chromosomal microsatellite markers for nonhuman primates

We have analysed 136 newly identified human Y-chromosomal microsatellites in five (sub)species of nonhuman primates. We identified 83 male-specific loci for central chimpanzees, 82 for western chimpanzees, 67 for gorillas, 45 for orangutans and 19 loci for mandrills. Polymorphism was detected at 56 loci in central chimpanzees, 29 in western chimpanzees, 24 in western gorillas, 17 in orangutans and at three in mandrills. Success in male-specific amplification of human Y-chromosomal microsatellites in nonhuman primates was significantly negatively correlated with divergence time from the human lineage. We observed significantly more Y-chromosomal microsatellite diversity in central chimpanzees than in western chimpanzees. There were significantly more male-specific loci with longer alleles in humans than with longer alleles in the nonhuman primates; however, this significant difference disappeared when only the loci which are polymorphic in nonhuman primates were analysed, suggesting that ascertainment bias is responsible. This study provides primatologists with a large number of polymorphic, male-specific microsatellite markers that will be valuable for investigating relevant questions in behavioural ecology such as male reproductive strategies, kin-based cooperation among males and male-specific dispersal patterns in wild groups of nonhuman primates.