Pox infection in white rats.

2 pox outbreaks among white rats in a breeding colony are described. The infection occurred in 3 different forms: pulmonary, dermal and mixed. Apparently healthy animals appeared to be virus carriers. The virus isolated belonged to the genus Orthopoxvirus of Poxviridae family, and was very close to cowpox virus. It differed from reference strains of cowpox virus in having a lower ceiling temperature and a higher pathogenicity for white rats.     

T Cell Inactivation by Poxviral B22 Family Proteins Increases Viral Virulence

Infections with monkeypox, cowpox and weaponized variola virus remain a threat to the increasingly unvaccinated human population, but little is known about their mechanisms of virulence and immune evasion. We now demonstrate that B22 proteins, encoded by the largest genes of these viruses, render human T cells unresponsive to stimulation of the T cell receptor by MHC-dependent antigen presentation or by MHC-independent stimulation. In contrast, stimuli that bypass TCR-signaling are not inhibited. In a non-human primate model of monkeypox, virus lacking the B22R homologue (MPXVΔ197) caused only mild disease with lower viremia and cutaneous pox lesions compared to wild type MPXV which caused high viremia, morbidity and mortality. Since MPXVΔ197-infected animals displayed accelerated T cell responses and less T cell dysregulation than MPXV US2003, we conclude that B22 family proteins cause viral virulence by suppressing T cell control of viral dissemination.     

Monkeypox: features of spread after cancellation of mandatory pox immunization

Features of spread of monkeypox after eradication of smallpox and cancellation of mandatory pox immunization are examined. In the condition of cancellation of mandatory pox immunization, a decrease of population immunity to pox in the population, a lack of vigilance in most of the medical specialists to diseases caused by other pathogenic for human orthopoxviruses was noted. This situation complicates the prognosis of the development of possible outbreaks of infection of humans by monkeypox. In such situation only constant vigilance with respect to this zooanthroponosis, use of express diagnostics methods, as well as means of effective protection will allow to stop outbreaks of monkeypox at the early stages of the development.     

Genomic expression libraries for the identification of cross-reactive orthopoxvirus antigens

Increasing numbers of human cowpox virus infections that are being observed and that particularly affect young non-vaccinated persons have renewed interest in this zoonotic disease. Usually causing a self-limiting local infection, human cowpox can in fact be fatal for immunocompromised individuals. Conventional smallpox vaccination presumably protects an individual from infections with other Orthopoxviruses, including cowpox virus. However, available live vaccines are causing severe adverse reactions especially in individuals with impaired immunity. Because of a decrease in protective immunity against Orthopoxviruses and a coincident increase in the proportion of immunodeficient individuals in today's population, safer vaccines need to be developed. Recombinant subunit vaccines containing cross-reactive antigens are promising candidates, which avoid the application of infectious virus. However, subunit vaccines should contain carefully selected antigens to confer a solid cross-protection against different Orthopoxvirus species. Little is known about the cross-reactivity of antibodies elicited to cowpox virus proteins. Here, we first identified 21 immunogenic proteins of cowpox and vaccinia virus by serological screenings of genomic Orthopoxvirus expression libraries. Screenings were performed using sera from vaccinated humans and animals as well as clinical sera from patients and animals with a naturally acquired cowpox virus infection. We further analyzed the cross-reactivity of the identified immunogenic proteins. Out of 21 identified proteins 16 were found to be cross-reactive between cowpox and vaccinia virus. The presented findings provide important indications for the design of new-generation recombinant subunit vaccines.     

Cowpox virus infection in natural field vole Microtus agrestis populations: significant negative impacts on survival

1. Cowpox virus is an endemic virus circulating in populations of wild rodents. It has been implicated as a potential cause of population cycles in field voles Microtus agrestis L., in Britain, owing to a delayed density-dependent pattern in prevalence, but its impact on field vole demographic parameters is unknown. This study tests the hypothesis that wild field voles infected with cowpox virus have a lower probability of survival than uninfected individuals. 2. The effect of cowpox virus infection on the probability of an individual surviving to the next month was investigated using longitudinal data collected over 2 years from four grassland sites in Kielder Forest, UK. This effect was also investigated at the population level, by examining whether infection prevalence explained temporal variation in survival rates, once other factors influencing survival had been controlled for. 3. Individuals with a probability of infection, P(I), of 1 at a time when base survival rate was at median levels had a 22.4% lower estimated probability of survival than uninfected individuals, whereas those with a P(I) of 0.5 had a 10.4% lower survival. 4. At the population level, survival rates also decreased with increasing cowpox prevalence, with lower survival rates in months of higher cowpox prevalence. 5. Simple matrix projection models with 28 day time steps and two stages, with 71% of voles experiencing cowpox infection in their second month of life (the average observed seroprevalence at the end of the breeding season) predict a reduction in 28-day population growth rate during the breeding season from lambda = 1.62 to 1.53 for populations with no cowpox infection compared with infected populations. 6. This negative correlation between cowpox virus infection and field vole survival, with its potentially significant effect on population growth rate, is the first for an endemic pathogen in a cyclic population of wild rodents.     

Laboratory-confirmed case of human infection with ratpox (cowpox)

The present work describes a case of human disease resulting from the bite of a white rat and caused by a biological variant of cowpox virus. The isolates obtained from the sick man and the white rats which had been the source of this infection proved to be identical and did not differ from the biological variants of cowpox virus, isolated earlier from white rats and carnivorous animals of the family Felidae. Thus, the possibility of ratpox (cowpox) transmission from sick rodents to man was established.     

The outbreak of carp disease caused by CyHV-3 as a model for new emerging viral diseases in aquaculture: a review

Aquacultured koi and common carp (Cyprinus carpio) are intensively bred for ornamental purposes and for human consumption worldwide. The carp and koi farming industries have suffered enormous economic losses over the past decade due to an epizootic disease caused by Cyprinus herpesvirus-3 (CyHV-3) also known as koi herpesvirus and carp interstitial nephritis gill necrosis virus. CyHV-3 is a large dsDNA virus, morphologically similar to herpesviruses, yet contains genetic elements similar to those of pox, irido- and herpesviruses. Considering the phylogenic distance between CyHV-3 and higher vertebrate herpesviruses, CyHV-3 represents the prototype of viruses assigned to the novel family Alloherpesviridae. Although emergence of a new virus rarely initiates a pandemic so severe that it reduces the life expectancy of a population, CyHV-3 is exceptional because of its enormous impact on the world carp population. High population density is the major contributing factor to the epizootic disease caused by CyHV-3.     

Tanapox: A New Disease Caused by a Pox Virus

Two epidemics of a new virus disease, tanapox, occurred in 1957 and 1962 among the Wapakomo tribe along the Tana River in Kenya. Several hundred people were affected by a short febrile illness with headache and prostration and the disease was characterized by a single pock-like lesion on the upper part of the body. A pox virus, unrelated to the vaccinia-variola group, has been incriminated as the causative agent. The virus has a limited host range and has been grown only in human and monkey tissue cultures, and so far the only animals that have proved susceptible in the laboratory have been monkeys. The characteristic lesions have been reproduced in a human volunteer. Histopathological and electron microscopic studies indicate that the virus belongs to the pox group, but serological tests show that it differs from other animal pox viruses, including yabapox virus of monkeys. A similar if not identical pox virus has caused epidemics in primate colonies in the U.S.A. It is suggested that tanapox is a zoonosis and that the disease is transmitted from monkeys to man in Kenya.     

Prevalence of avian pox virus and effect on the fledging success of Laysan Albatross

ABSTRACT.   Avian pox virus ( Poxvirus avium ) is a mosquito-borne disease that occurs worldwide in a variety of bird species, but little is known about its prevalence or effect on seabirds. We monitored prevalence of pox virus and its effect on fledging success of Laysan Albatross ( Phoebastria immutabilis ) on Oahu, Hawaii, from 2003 to 2007. Pox prevalence in albatross chicks averaged 88% in years with high rainfall and 3% in years with low rainfall. Diagnosis of pox virus was clinically confirmed in two birds by Muscovy Duck ( Cairina moschata ) fibrolast cultures. Severity of infection ranged from small wart-like nodules and lesions on the bill, face, eyes, tarsus, and feet, to large tumorous growths that completely covered both eyes and caused deformation of the bill and skull. Most chicks recovered from infection, and the fledging rate in pox epizootic years (82%) did not differ from that in years with low pox prevalence (80%) or the average fledging rate on Midway Atoll (86%). Three chicks with severe infections were resighted as healthy adults on Kauai and Oahu in 2007, confirming postfledging survival of at least some birds. The high recovery rate, fledging success, and postfledging survival indicate that Laysan Albatross have strong immunity to avian pox virus.     

Infection with cowpox virus decreases female maturation rates in wild populations of woodland rodents

Sublethal effects of parasitic infection, such as reductions in reproductive rate, can significantly affect host population dynamics. Here we show that in wild populations of both Clethrionomys glareolus (bank vole) and Apodemus sylvaticus (wood mouse), females infected with cowpox virus are likely to delay maturation and therefore reproduction – in most cases until the following breeding season. Some infected bank voles do mature in their year of birth but still take longer than uninfected females. Together with our previous demonstration that individuals infected with cowpox virus in the summer survive better than uninfected individuals, these results support the prediction that hosts that develop an acute infection may best optimise their fitness by decreasing current reproduction to maximise the probability of surviving infection. Moreover, as the proportion of individuals infected increases with density, the reduction in host fecundity may have significant consequences for host dynamics.     

Differentiation of capripoxvirus species and strains by polymerase chain reaction

A fast and simple method for capripoxvirus species identification has been developed. The method is based on multiplex polymerase chain reaction (MPCR) with species-specific primers and does not require nucleotide sequencing or restriction analysis of PCR products. To differentiate vaccine stains used in Russia and countries of the former Soviet Union from epizootic isolates of sheep pox virus, a method based on restriction analysis of the ankyrin-repeat protein gene fragment amplified by PCR has been developed. Being highly specific, both methods may be used for routine diagnosis of capripoxvirus-associated diseases.     

Transmission dynamics of a zoonotic pathogen within and between wildlife host species

The transmission dynamics of the cowpox virus infection have been quantified in two mixed populations of bank voles (Clethrionomys glareolus) and wood mice (Apodemus sylvaticus), through analyses of detailed time-series of the numbers of susceptible, infectious and newly infected individuals. The cowpox virus is a zoonosis which circulates in these rodent hosts and has been shown to have an adverse effect on reproductive output. The transmission dynamics within species is best described as frequency dependent rather than density dependent, contrary to the 'mass action' assumption of most previous studies, both theoretical and empirical. Estimation of a transmission coefficient for each species in each population also allows annual and seasonal variations in transmission dynamics to be investigated through an analysis of regression residuals. Transmission between host species is found to be negligible despite their close cohabitation. The consequences of this for the combining ability of hosts as zoonotic reservoirs, and for apparent competition between hosts, are discussed.     

A cowpox virus gene required for multiplication in Chinese hamster ovary cells.

Cowpox virus, in contrast to vaccinia virus, can multiply in Chinese hamster ovary cells. To study the genetic basis for this difference in host range, recombinants between vaccinia and cowpox viruses were isolated and their DNA restriction patterns were examined. The ability to multiply in Chinese hamster ovary cells could be correlated with the conservation of cowpox virus sequences mapping at the left end of the genome. This was further demonstrated by marker rescue of the host range phenotype with restricted cowpox virus DNA. Marker rescue with cloned restriction fragments of decreasing size enabled the fine localization of the host range function to a 2.3-kilobase-pair fragment. Nucleotide sequencing revealed that the fragment encoded a single major polypeptide of approximately 77,000 daltons. It is suggested that the role of the host range gene from cowpox virus is to prevent the early and extensive shutoff of protein synthesis that normally occurs in Chinese hamster ovary cells infected by vaccinia virus.     

CrmE, a novel soluble tumor necrosis factor receptor encoded by poxviruses

Cytokines and chemokines play a critical role in both the innate and acquired immune responses and constitute prime targets for pathogen sabotage. Molecular mimicry of cytokines and cytokine receptors is a mechanism encoded by large DNA viruses to modulate the host immune response. Three tumor necrosis factor receptors (TNFRs) have been identified in the poxvirus cowpox virus. Here we report the identification and characterization of a fourth distinct soluble TNFR, named cytokine response modifier E (CrmE), encoded by cowpox virus. The crmE gene has been sequenced in strains of the orthopoxviruses cowpox virus, ectromelia virus, and camelpox virus, and was found to be active in cowpox virus. crmE is expressed as a secreted 18-kDa protein with TNF binding activity. CrmE was produced in the baculovirus and vaccinia virus expression systems and was shown to bind human, mouse, and rat TNF, but not human lymphotoxin alpha, conjugates of lymphotoxins alpha and beta, or seven other ligands of the TNF superfamily. However, CrmE protects cells only from the cytolytic activity of human TNF. CrmE is a new member of the TNFR superfamily which is expressed as a soluble molecule that blocks the binding of TNF to high-affinity TNFRs on the cell surface. The remarkable finding of a fourth poxvirus-encoded TNFR suggests that modulation of TNF activity is complex and represents a novel viral immune evasion mechanism.     

The Ugi reaction in the generation of new nucleosides as potential antiviral and antileishmanial agents

5-Formyl-2'-deoxyuridine-3',5'-diacetate was converted to a small library of 5-substituted pyrimidine nucleoside N-acylamino acid amides by means of a Ugi multicomponent reaction. The reaction allowed introduction of various substituents at the acyl moiety, at the amino acid alpha-amide group, and at the amino acid carboxyl function. Evaluation of these novel 5-substituted nucleosides against vaccinia virus and cowpox virus provided one compound with discernable activity against cowpox virus but five- to eightfold less active than the Cidofovir standard. More promising activity was seen for the inhibition of Leishmania donovani promastigotes. Several synthetic products showed antileishmanial activity in the 10(-5)M range. When compared to earlier studies demonstrating anti-orthopoxviral and antileishmanial activity of 5-substituted pyrimidine nucleosides, these results imply that the 5-(N-acylamino acid amide)-derivatized pyrimidine nucleosides may possess more steric bulk, greater hydrophobicity, and more flexibility than is compatible with these particular biological activities.     

Modeling spatial structures of variola and cowpox virus TNF-binding CrmB proteins bound to murine or human TNF

Orthopoxviruses bear in their genomes several genes coding for homologous secreted proteins able to bind tumor necrosis factor. Different species of the genus possess different sets of these tumor necrosis factor-binding proteins. Viriola virus encodes the only one of them named CrmB. Despite sharing high sequence identity, CrmB proteins belonging to distinct orthopoxviral species were shown to significantly differ by their physico-chemical and biological properties. We modeled spatial structures of tumor necrosis factor receptor domains of variola and cowpox virus CrmB proteins bound to either murine, or human or mutated human tumor necrosis factor. In the sequence of last the arginine residue at position 31 is substituted with glutamine that is characteristic for murine tumor necrosis factor. Theoretical analysis of modeled ligand-receptor complexes revealed that the least stable should be the complex of cowpox virus CrmB with human tumor necrosis factor, and that arginine to glutamine substitution at position 31 should significantly stabilize binding of corresponding human tumor necrosis factor mutant to cowpox virus CrmB. Experimental evaluation of recombinant variola and cowpox virus CrmB efficiencies in inhibiting cytotoxic effect of all these tumor necrosis factors have approved our predictions.     

检疫性有害生物李痘病毒生物学特性及预防控制技术

李痘病毒最早发现于欧洲东部的保加利亚,是一种严重危害核果类果树的病毒,为欧洲和地中海植物保护组织A2类检疫性有害生物,泛非植物检疫理事会和北美植物保护组织检疫性有害生物,我国于2007年将其列入《中华人民共和国进境植物检疫性有害生物名录》。李痘病毒主要通过寄主植物繁殖材料(种苗、砧木、芽条等)的贸易活动进行远距离传播,或借助带毒媒介蚜虫进行短距离扩散。截至2018年,李痘病毒已在全世界56个国家和地区发生,我国于2004年在湖南发现其危害杏树。本文从李痘病毒的生物学特性、传播扩散途径、诊断检测方法及预防控制技术等方面进行阐述,以期为防止其再次入侵和进一步传播扩散提供参考。     

3D structure modeling of complexes formed by CrmB TNF-binding proteins of Variola and cowpox viruses with murine and human TNFs

Orthopoxviral genomes bear genes for a series of homologous secreted proteins binding tumor necrosis factor (TNF). Orthopoxvirus species have different sets of these proteins. Variola virus has only one protein of this series, CrmB. Although CrmB protein sequences are similar to each other, their physicochemical and biological properties show certain species-specific features. We constructed 3D models of complexes formed by TNF-binding domains of variola and cowpox viruses with murine and human TNFs. We also constructed corresponding models with a mutant human TNF. In this mutant TNF, the arginine residue at position 31 involved in receptor binding was replaced by glutamine, characteristic of murine TNF. Analysis of the models showed that the least stable complex should be that formed by cowpox virus CrmB with human TNF, and the Arg31/Gln substitution should significantly stabilize the interaction between cowpox CrmB and mutant human TNF. Experimental comparison of the abilities of recombinant variola and cowpox CrmB proteins to inhibit the cytotoxic action of TNFs confirmed the predictions.     

Aphid (Hemiptera: Aphididae) species composition and potential aphid vectors of plum pox virus in Pennsylvania peach orchards

Plum pox, an invasive disease recently identified in Pennsylvania stone fruit orchards, is caused by the aphid-transmitted Plum pox virus (genus Potyvirus, family Potyviridae, PPV). To identify potential vectors, we described the aphid species communities and the seasonal dynamics of the dominant aphid species within Pennsylvania peach orchards. Aphids were trapped weekly in 2002 and 2003 from mid-April through mid-November within two central Pennsylvania orchards by using yellow and green water pan traps. In total, 42 aphid species were identified from both orchards over 2 yr. Within orchards, actual species richness ranged from 24 to 30 species. The Abundance Based Coverage Estimator predicted species richness to range from 30 to 36 species, indicating that trap catches were identifying most aphid species expected to occur in the orchard. Three species, Rhopalosiphum maidis (Fitch), Aphis spiraecola Patch, and Myzus persicae (Sulzer), were consistently dominant across locations and years. Orchard-trapped populations of these three species peaked in a similar chronological sequence each year. As expected, trap color influenced the total number and distribution of the predominate species collected. However, the same dominant species occurred in both yellow and green traps. Based on the seasonal population dynamics reported here and on published vector efficacy studies, the most probable significant PPV vector was identified as A. spiraecola. If the PPV pathogen escapes current quarantine or if subsequent reintroductions of PPV occur, these data will be useful for developing plum pox management strategies.