An overview of tecovirimat for smallpox treatment and expanded anti-orthopoxvirus applications.

INTRODUCTION: Tecovirimat (TPOXX®; ST-246) was approved for the treatment of symptomatic smallpox by the USFDA in July of 2018 and has been stockpiled by the US government for use in a smallpox outbreak. While there has not been a reported case of smallpox since 1978 it is still considered a serious bioterrorism threat. AREAS COVERED: A brief history of smallpox from its proposed origins as a human disease through its eradication in the late 20th century is presented. The current smallpox threat and the current public health response plans are described. The discovery, and development of tecovirimat through NDA submission and subsequent approval for treatment of smallpox are discussed. Google Scholar and PubMed were searched over all available dates for relevant publications. EXPERT OPINION: Approval of tecovirimat to treat smallpox represents an important milestone in biosecurity preparedness. Incorporating tecovirimat into the CDC smallpox response plan, development of pediatric liquid and intravenous formulations, and approval for post-exposure prophylaxis would provide additional health security benefit.Tecovirimat shows broad efficacy against orthopoxviruses in vitro and in vivo and could be developed for use against emerging orthopoxvirus diseases such as monkeypox, vaccination-associated adverse events, and side effects of vaccinia oncolytic virus therapy.

Novel oncolytic chimeric orthopoxvirus causes regression of pancreatic cancer xenografts and exhibits abscopal effect at a single low dose.

BACKGROUND: Pancreatic ductal adenocarcinoma (PDAC) has been increasing by 0.5% per year in the United States. PDAC portends a dismal prognosis and novel therapies are needed. This study describes the generation and characterization of a novel oncolytic chimeric orthopoxvirus for the treatment of pancreatic cancer. METHODS: After chimerization and high-throughput screening, CF33 was chosen from 100 new chimeric orthopoxvirus isolates for its ability to kill pancreatic cancer cells. In vitro cytotoxicity was assayed in six pancreatic cancer cell lines. In vivo efficacy and toxicity were evaluated in PANC-1 and MIA PaCa-2 xenograft models. RESULTS: CF33 caused rapid killing of six pancreatic cancer cells lines in vitro, releasing damage-associated molecular patterns, and regression of PANC-1 injected and non-injected distant xenografts in vivo after a single low intratumoral dose of 103 plaque-forming units. Using luciferase imaging, CF33 was noted to preferentially replicate in tumors which corresponds to the low viral titers found in solid organs. CONCLUSION: The low dose of CF33 required to treat pancreatic cancer in this preclinical study may ease the manufacturing and dosing challenges currently facing oncolytic viral therapy.

Genetic characterization of poxviruses in Camelus dromedarius in Ethiopia, 2011-2014.

Camelpox and camel contagious ecthyma are infectious viral diseases of camelids caused by camelpox virus (CMLV) and camel contagious ecthyma virus (CCEV), respectively. Even though, in Ethiopia, pox disease has been creating significant economic losses in camel production, little is known on the responsible pathogens and their genetic diversity. Thus, the present study aimed at isolation, identification and genetic characterization of the causative viruses. Accordingly, clinical case observations, infectious virus isolation, and molecular and phylogenetic analysis of poxviruses infecting camels in three regions and six districts in the country, Afar (Chifra), Oromia (Arero, Miyu and Yabello) and Somali (Gursum and Jijiga) between 2011 and 2014 were undertaken. The full hemagglutinin (HA) and partial A-type inclusion protein (ATIP) genes of CMLV and full major envelope protein (B2L) gene of CCEV of Ethiopian isolates were sequenced, analyzed and compared among each other and to foreign isolates. The viral isolation confirmed the presence of infectious poxviruses. The preliminary screening by PCR showed 27 CMLVs and 20 CCEVs. The sequence analyses showed that the HA and ATIP gene sequences are highly conserved within the local isolates of CMLVs, and formed a single cluster together with isolates from Somalia and Syria. Unlike CMLVs, the B2L gene analysis of Ethiopian CCEV showed few genetic variations. The phylogenetic analysis revealed three clusters of CCEV in Ethiopia with the isolates clustering according to their geographical origins. To our knowledge, this is the first report indicating the existence of CCEV in Ethiopia where camel contagious ecthyma was misdiagnosed as camelpox. Additionally, this study has also disclosed the existence of co-infections with CMLV and CCEV. A comprehensive characterization of poxviruses affecting camels in Ethiopia and the full genome sequencing of representative isolates are recommended to better understand the dynamics of pox diseases of camels and to assist in the implementation of more efficient control measures.

Cloning and rescue of the genome of Bombyx mori bidensovirus, and characterization of a recombinant virus.

BACKGROUND: Bombyx mori bidensovirus (BmBDV), which belongs to the Bidnaviridae family established by the International Committee on Taxonomy of Viruses in 2011, was the first bidensovirus identified in insects. The structure of BmBDV is similar to that of parvoviruses, while its replication is similar to that of adenoviruses. Although BmBDV has the potential to be used as a tool in biological pest control and as an expression vector, virus rescue has been a bottleneck in the application of this virus. METHODS: In this study, we constructed a full-length genomic clone of BmBDV and showed that its terminal structure was restored. A recombinant BmBDV that expressed the green fluorescence protein (GFP) gene was constructed. Then, BmN cells, which are an ovarian cell line, were co-transfected with the linearized genome using continuous culture and expanded cell culture methods. RESULTS: The results showed that the GFP gene was expressed successfully, and that cell lesions occurred in virus-infected cells. Furthermore, typical densonucleosis viruses were observed in reinfected silkworm larvae and larval midgut tissues infected by BmBDV, as evidenced by the emission of green fluorescence. CONCLUSIONS: Overall, these results suggest that the virus could be rescued from the infected BmN cells after co-transfection with the linear full length virus genome.

[Cutaneous infection with Orthopoxvirus bovis in a German Spaniel]. / Kutane Infektion mit Orthopoxvirus bovis bei einem Wachtelhund.

A 4-year-old female German Spaniel was presented with anorexia. Clinically, the dog showed papular to ulcerative lesions on the nasal planum and on the tongue. Hematological, bacteriological and mycological examinations did not contribute any evidence for the etiology of the lesions. Histopathological examination of skin biopsies revealed a proliferative dermatitis and folliculitis with hydropic degeneration of keratinocytes and cytoplasmatic inclusion bodies. Cowpox virus antigen was detected by immunohistochemistry, and electron microscopy showed pox virus particles in the cytoplasm of the epithelial cells. DNA of Orthopoxvirus bovis was identified by polymerase chain reaction. Consequently, in dogs with papular to ulcerative lesions in the face or on the tongue, infection with cowpoxvirus should be considered as an etiological differential diagnosis. Infected dogs represent a potential risk of infection for humans and other animals with close contact.

Multiplex PCR for rapid diagnosis and differentiation of pox and pox-like diseases in dromedary Camels.

BACKGROUND: Pox and pox-like diseases of camels are a group of exanthematous skin conditions that have become increasingly important economically. Three distinct viruses may cause them: camelpox virus (CMLV), camel parapox virus (CPPV) and camelus dromedary papilloma virus (CdPV). These diseases are often difficult to differentiate based on clinical presentation in disease outbreaks. Molecular methods such as PCR targeting species-specific genes have been developed and used to identify these diseases, but not simultaneously in a single tube. Recently, multiplex PCR has gained reputation as a convenient diagnostic method with cost-and timesaving benefits. METHODS AND RESULTS: In the present communication, we describe the development, optimization and validation of a multiplex PCR assay able to detect simultaneously the genome of the three viruses in one single test allowing for rapid and efficient molecular diagnosis. The assay was developed based on the evaluation and combination of published and new primer sets and was validated with viral genomic DNA extracted from known virus strains (n = 14) and DNA extracted from homogenized clinical skin specimens (n = 86). The assay detects correctly the target pathogens by amplification of targeted genes, even in case of co-infection. The method showed high sensitivity, and the specificity was confirmed by PCR-product sequencing. CONCLUSION: This assay provide rapid, sensitive and specific method for identifying three important viruses in specimens collected from dromedary camels with varying clinical presentations.

Identification and characterization of a phage display-derived peptide for orthopoxvirus detection.

Fast and reliable diagnostic assays are required for a resilient detection of clinical infections or biothreat-relevant pathogens. While PCR has proven to be the gold standard for nucleic acid detection, the identification of pathogen particles is still challenging and depends on the availability of well-characterized, chemically stable, and selective recognition molecules. Here, we report the screening of a phage display random peptide library for vaccinia virus-binding peptides. The identified peptide was extensively characterized using peptide-probe ELISA, surface plasmon resonance, nLC-MS/MS, Western Blot, peptide-based immunofluorescence assay, and electron microscopy. Following identification, the phage-free, synthetic peptide, designated αVACVpep05, was shown to bind to vaccinia virus and other orthopoxviruses. We can demonstrate that the highly conserved orthopoxvirus surface protein D8 is the interaction partner of αVACVpep05, thus enabling the peptide to bind to other orthopoxviruses, including cowpox virus and monkeypox virus, viruses that cause clinically relevant zoonotic infections in humans. The process of phage display-mediated peptide identification has been optimized intensively, and we provide recommendations for the identification of peptides suitable for the detection of further pathogens. The peptide described here was critically characterized and seems to be a promising reagent for the development of diagnostic platforms for orthopoxviruses. We believe that our results will help to promote the development of alternative, nonantibody-based synthetic detection molecules for further pathogens.

Cutaneous lesions associated with dual infection caused by canine distemper virus and orthopoxvirus in a domestic cat.

BACKGROUND: Within the context of an increased epidemiological pressure caused by canine distemper virus (CDV) in Switzerland together with a potential re-emergence of endemic pathogens such as orthopoxviruses (OPXV), dual infections are possible among susceptible species. OBJECTIVE: To describe a case of concurrent CDV and OPXV infection in a cat. ANIMAL: A 5-year-old, neutered male cat was presented with erythema, crusts and ulcerations around the left eye. High-grade pruritus and a severe conjunctivitis were also present. METHODS: Formalin-fixed skin biopsy samples were obtained from lesional skin. Histopathology, CDV immunohistochemistry and CDV and OPXV RT-PCR were performed. RESULTS: Histopathological examination showed severe epidermal necrosis extending to the follicular walls and a dermal infiltration, predominantly eosinophilic. Intranuclear and intracytoplasmic eosinophilic inclusion bodies were visible in the wall of affected hair follicles, with occasional formation of syncytia. The RT-PCR revealed the contextual presence of both CDV and OPXV. Scattered cells stained positive for CDV by immunohistochemistry. CONCLUSION AND DISCUSSION: Dual infections with CDV and OPXV, although rare, may occur and represent additional differential diagnoses for ulcerative skin lesions in cats.

Animal infections by vaccinia-like viruses in the state of Rio de Janeiro: an expanding disease / Infecções animais por vírus semelhantes ao vaccínia no estado do Rio de Janeiro: uma doença em expansão

In the present study we investigated the presence of infections by vaccinia-like viruses in dairy cattle from 12 counties in the state of Rio de Janeiro in the last 9 years. Clinical specimens were collected from adult animals with vesicular/pustular lesions mainly in the udder and teats, and from calves with lesions around the nose and mouth. A plaque reduction neutralization test (PRNT) was applied to search for antibodies to Orthopoxvirus; the vesicular/pustular fluids and scabs were examined by PCR, electron microscopy (EM) and by inoculation in VERO cells for virus isolation. Antibodies to Orthopoxvirus were detected in most cases. The PCR test indicated a high nucleotide homology among the isolates and the vaccinia viruses (VACV) used as controls. By EM, typical orthopoxvirus particles were observed in some specimens. The agents isolated in tissue culture were confirmed as vaccinia-like viruses by EM and PCR. The HA gene of the vaccinia-like Cantagalo/IOC virus isolated in our laboratory was sequenced and compared with other vaccinia-like isolates, showing high homology with the original Cantagalo strain, both strains isolated in 1999 from dairy cattle. Antibodies to Orthopoxvirus were detected in one wild rodent (genus Akodon sp.) collected in the northwestern region of the state, indicating the circulation of poxvirus in this area. Nonetheless, PCR applied to tissue samples collected from the wild rodents were negative. Vesicular/pustular lesions in people in close contact with animals have been also recorded. Thus, the vaccinia-like virus infections in cattle and humans in the state seem to be an expanding condition, resulting in economic losses to dairy herds and leading to transient incapacitating human disease. Therefore, a possible immunization of the dairy cattle in the state should be carefully evaluated.

Neste estudo avaliou-se a presença de infecções por vírus semelhantes ao vírus vaccínia (VACV) em gado leiteiro em 12 municípios no estado do Rio de Janeiro, ao longo dos últimos nove anos. Amostras clínicas foram coletadas de animais com vesículas, pústulas e crostas no úbere e tetas, e da região do nariz e da cavidade oral de bezerros. Um teste de neutralização viral por redução de placas foi desenvolvido para investigar a presença de anticorpos contra Orthopoxvirus. Os fluidos de vesículas / pústulas e as crostas foram testadas por PCR, microscopia eletrônica (ME) e por inoculação em células VERO para isolamento viral. Anticorpos contra Orthopoxvirus foram detectados na grande maioria dos animais. O teste de PCR demonstrou homologia entre os vírus isolados e amostras de vírus vaccínia usados como controles. Na ME, partículas típicas de Orthopoxvirus foram observadas em vários espécimes analisados. Os vírus isolados em cultivo celular foram confirmados como Orthopoxvirus por PCR e ME. O gene HA da amostra Cantagalo/IOC isolada em nosso laboratório foi seqüenciado e comparado com outras amostras semelhantes ao vaccínia, mostrando uma alta homologia com a amostra original Cantagalo, tendo sido as duas amostras isoladas em 1999 de gado leiteiro. Anticorpos para Orthopoxvirus foram detectados em um roedor silvestre do gênero Akodon sp. coletado na região noroeste do estado, sugerindo uma circulação de poxvírus na natureza. No entanto, os testes de PCR aplicados a tecidos de roedores silvestres foram negativos. Infecções vesiculares / pustulares em humanos que mantinham contato com os animais afetados também foram relatadas. Assim, infecções por amostras semelhantes ao vírus VACV em bovinos e em humanos parecem em expansão no estado, gerando perdas econômicas em animais e quadros de doença incapacitante temporária em pacientes humanos. Dessa forma, a possibilidade da imunização do gado leiteiro no estado deve ser devidamente avaliada.

Epidemiologia da poxvirose bovina no Estado do Espírito Santo, Brasil / Epidemiology bovine poxviruses in the Espírito Santo State, Brazil

O trabalho consistiu no estudo epidemiológico do surto de poxvirose bovina no Estado do Espírito Santo no período de 2002 a 2005. A coleta dos dados deu-se em 28 propriedades de gado bovino leiteiro de 08 municípios do Sul do Estado do Espírito Santo com casos de doenças pústulo-vesicular em bovinos, no período de agosto de 2002 a maio de 2005. Observou-se que a prevalência da doença no gado bovino leiteiro variou de 10,2% a 100% das propriedades com média de 52,7%. Através de isolamento viral e PCR do gene Timidina Quinase (TK), identificou-se o vírus do gênero Orthopoxvirus como o agente etiológico da poxvirose bovina. Em todas as propriedades constatou-se uma perda econômica, principalmente relacionada à queda na produção leiteira. A poxvirose bovina assumiu um caráter epidêmico no Sul do Estado do Espírito Santo, com grande impacto econômico e importância em saúde pública, como uma zoonose ocupacional entre os ordenhadores. Baseadas nos dados obtidos, medidas de cunho fiscal-sanitário e de orientação ao produtor agropecuário foram implementadas, visando conter a disseminação da doença entres as propriedades, e os outros municípios do Estado.

The purpose of this study was to investigate the epidemiological data of bovine poxviruses in the State of Espírito Santo during the years 2002 to 2005. The sample consisted of 28 properties that produce cow's milk in 08 cities from the South of the State, in wich were present cases of bonive pustulo-vesicular disease between 2002 august to 2005 may. The bovine disease was found in 10,2% to 100% of the properties with a mean of 52,7%. Throughout virus isolation techniques and PCR of the Timidin Kinase gene, an Orthopoxvirus was identified as the etiological agent of the bovine yiruses. All the properties reported economic losts related to a decrease in milk production. The bovine poxviruses assumed an epidemic feature in the South of the State of Espírito Santo promoting a big economic impact and representing an important public health worry as an occupational zoonosis mainly for the milkers. Thus, based on the obtained data, policy and sanitary statements, and educational strategies, were applied in the properties in order to stop the disease dissemination over the neighbor cities.

Raccoonpox in a Canadian cat.

Poxvirus infections affecting the skin of cats are extremely rare in North America, in contrast to Europe where cowpox virus is well recognized as an accidental pathogen in cats that hunt small rodents. The virus or viruses responsible for the anecdotal cases in North America have never been characterized. This paper reports a case of raccoonpox infection in a Canadian cat. Biopsy of the initial ulcerative lesion on the forepaw revealed ballooning degeneration of surface and follicular keratinoctyes. Infected cells contained large eosinophilic type A inclusions. Electron microscopic examination revealed virions of an orthopoxvirus, subsequently identified as raccoonpox by polymerase chain reaction and gene sequencing. The cat made a full recovery.

Use of internally controlled real-time genome amplification for detection of variola virus and other orthopoxviruses infecting humans.

Smallpox, once a devastating disease caused by Variola virus, a member of the Orthopoxvirus genus, was eradicated in 1980. However, the importance of variola virus infections has been stressed widely in the last few years, particularly following recent social events in the world. Today, variola virus is considered to be one of the most significant agents with potential use as a biological weapon. In this study we developed an internally controlled real-time PCR assay for rapid detection and simultaneous differentiation of variola virus from other orthopoxviruses. The assay is based on TaqMan 3'-minor groove binder (MGB) chemistry and uses generic primers, designed in highly conserved genomic regions of the crmB gene, and three TaqMan MGB probes designed to identify orthopoxviruses, variola virus, and an internal control. The results obtained suggest that the assay is rapid, sensitive, specific, and suitable for the generic detection of orthopoxviruses and the identification of variola virus and avoids false-negative results in a single reaction tube.

Detection and identification of orthopoxviruses using a generic nested PCR followed by sequencing.

Some orthopoxviruses are considered to be potential biological weapons. After the smallpox eradication campaign ended, routine vaccination was stopped around the world. Consequently, a significant portion of the population is now completely unprotected from infection by variola virus and related orthopoxviruses. Some of the symptoms associated with non-variola infections can be similar to smallpox, causing alert and panic situations. These infections should be considered as real public health concerns, so suitable tools for their differential diagnosis are needed. This study aims to devise a simple and easy-to-perform method that is able to detect and identify any orthopoxvirus that might cause infection in humans. In addition, the similarity of the different genes in the genomes of several species of orthopoxviruses is investigated, and orthopoxvirus-universal primer pairs in the tumour necrosis factor receptor II homologue gene are designed, taking full account of nucleotide similarity. A strategy is devised for their sensitive, rapid and cost-effective detection and identification, based on a nested PCR followed by sequencing. The efficacy of the method is tested with samples sent by the European Network of Imported Viral Diseases as part of two external quality control assays. All human orthopoxviruses assayed were detected and identified.

An orally bioavailable antipoxvirus compound (ST-246) inhibits extracellular virus formation and protects mice from lethal orthopoxvirus Challenge.

ST-246 is a low-molecular-weight compound (molecular weight = 376), that is potent (concentration that inhibited virus replication by 50% = 0.010 microM), selective (concentration of compound that inhibited cell viability by 50% = >40 microM), and active against multiple orthopoxviruses, including vaccinia, monkeypox, camelpox, cowpox, ectromelia (mousepox), and variola viruses. Cowpox virus variants selected in cell culture for resistance to ST-246 were found to have a single amino acid change in the V061 gene. Reengineering this change back into the wild-type cowpox virus genome conferred resistance to ST-246, suggesting that V061 is the target of ST-246 antiviral activity. The cowpox virus V061 gene is homologous to vaccinia virus F13L, which encodes a major envelope protein (p37) required for production of extracellular virus. In cell culture, ST-246 inhibited plaque formation and virus-induced cytopathic effects. In single-cycle growth assays, ST-246 reduced extracellular virus formation by 10 fold relative to untreated controls, while having little effect on the production of intracellular virus. In vivo oral administration of ST-246 protected BALB/c mice from lethal infection, following intranasal inoculation with 10x 50% lethal dose (LD(50)) of vaccinia virus strain IHD-J. ST-246-treated mice that survived infection acquired protective immunity and were resistant to subsequent challenge with a lethal dose (10x LD(50)) of vaccinia virus. Orally administered ST-246 also protected A/NCr mice from lethal infection, following intranasal inoculation with 40,000x LD(50) of ectromelia virus. Infectious virus titers at day 8 postinfection in liver, spleen, and lung from ST-246-treated animals were below the limits of detection (<10 PFU/ml). In contrast, mean virus titers in liver, spleen, and lung tissues from placebo-treated mice were 6.2 x 10(7), 5.2 x 10(7), and 1.8 x 10(5) PFU/ml, respectively. Finally, oral administration of ST-246 inhibited vaccinia virus-induced tail lesions in Naval Medical Research Institute mice inoculated via the tail vein. Taken together, these results validate F13L as an antiviral target and demonstrate that an inhibitor of extracellular virus formation can protect mice from orthopoxvirus-induced disease.

Nucleic acid test screening of blood donors for orthopoxviruses can potentially prevent dispersion of viral agents in case of bioterrorism.

BACKGROUND: Microbiologic agents such as variola virus (VAR) are very attractive for terrorism. As a result of international collaboration under the WHO eradication campaign, smallpox was declared eradicated in 1980. Therefore, the immunization programs were discontinued worldwide. Because most people are now immunologically naive, VAR is considered to be a potential threat agent or bioterrorist weapon. Real-time polymerase chain reaction (PCR) followed by melting analysis was developed for fast and safe analysis and allows differentiation of VAR from other orthopoxviruses (OPVs) like vaccinia or camelpox virus. STUDY DESIGN AND METHODS: A RealArt Orthopox LC PCR kit (Artus GmbH) was used to amplify OPV sequences from blood donor samples. A total of 31,500 blood donor samples were tested in minipools of up to 96 samples. To evaluate the sensitivity of the assay, routine donor minipools (90 +/- 6 samples per pool) were spiked with vaccinia virus used as positive control. RESULTS: Specificity was 100 percent because none of 31,500 blood donors was positive for the presence OPV. The detection limit of the assay was 10.6 copies per PCR procedure. Therefore, a sensitivity of 1590 copies per mL was calculated. Overall, 0.28 percent of test results had to be considered invalid owing to negative internal controls. CONCLUSION: The RealArt Orthopox LC PCR kit enables reliable detection of OPV DNA in viremic blood donor samples, even at the beginning of the disease when patients present minor clinical symptoms, and could be implemented in our routine screening procedure immediately. Thus, the assay could potentially help to prevent dispersion of viral agents by blood transfusion in case of bioterrorism.

Real-time PCR system for detection of orthopoxviruses and simultaneous identification of smallpox virus.

A screening assay for real-time LightCycler (Roche Applied Science, Mannheim, Germany) PCR identification of smallpox virus DNA was developed and compiled in a kit system under good manufacturing practice conditions with standardized reagents. In search of a sequence region unique to smallpox virus, the nucleotide sequence of the 14-kDa fusion protein gene of each of 14 variola virus isolates of the Russian World Health Organization smallpox virus repository was determined and compared to published sequences. PCR primers were designed to detect all Eurasian-African species of the genus ORTHOPOXVIRUS: A single nucleotide mismatch resulting in a unique amino acid substitution in smallpox virus was used to design a hybridization probe pair with a specific sensor probe that allows reliable differentiation of smallpox virus from other orthopoxviruses by melting-curve analysis. The applicability was demonstrated by successful amplification of 120 strains belonging to the orthopoxvirus species variola, vaccinia, camelpox, mousepox, cowpox, and monkeypox virus. The melting temperatures (T(m)s) determined for 46 strains of variola virus (T(m)s, 55.9 to 57.8 degrees C) differed significantly (P = 0.005) from those obtained for 11 strains of vaccinia virus (T(m)s, 61.7 to 62.7 degrees C), 15 strains of monkeypox virus (T(m)s, 61.9 to 62.2 degrees C), 40 strains of cowpox virus (T(m)s, 61.3 to 63.7 degrees C), 8 strains of mousepox virus (T(m), 61.9 degrees C), and 8 strains of camelpox virus (T(m)s, 64.0 to 65.0 degrees C). As most of the smallpox virus samples were derived from infected cell cultures and tissues, smallpox virus DNA could be detected in a background of human DNA. By applying probit regression analysis, the analytical sensitivity was determined to be 4 copies of smallpox virus target DNA per sample. The DNAs of several human herpesviruses as well as poxviruses other than orthopoxviruses were not detected by this method. The assay proved to be a reliable technique for the detection of orthopoxviruses, with the advantage that it can simultaneously identify variola virus.

Feline orthopoxvirus infection transmitted from cat to human.

We report the case of a 56-year-old female patient who presented with an inflamed, ulcerated lesion on the left side of her neck after contact (scratch) with a cat living in the patient's house. Satellite lesions developed despite local treatment and parenteral clindamycin. Histopatholgic examination and the Tzanck test showed evidence of a viral infection. Subsequent transmission electron microscopy of scrap tissue and material from a fresh pustule exhibited multiple typical poxvirus particles, predominantly in remnants of scaled-off layers of degenerated keratinocytes, and virus particles in intermingled phagocytes, leading to the diagnosis of feline Orthopoxvirus (cowpox virus) infection. These results were verified by polymerase chain reaction and sequencing. Concern has been raised as to whether discontinuation of smallpox vaccine would cause an increase in Orthopoxvirus infection, but this has not yet shown to be the case.

[Identification of orthopoxvirus species using oligonucleotide micro-chips]. / Vidovaia identifikatsiia ortopoksvirusov na oligonukleotidnykh mikrochipakh.

A method for describing the Orthopoxviruses that are pathogenic both to man and animals is described in the article. The method is based on hybridization of a fluorescently labelled amplified DNA sample with oligonucleotides, which were immobilized in a microchip. Species-specific regions within the crmB gene encoding a viral analogue of the tumor necrosis factor receptor, i.e. an important gene determining the pathogenicity of the mentioned Orthopoxviruses type, were used as a target for identification. The identification procedure takes around 6 hours and does not demand any costly equipment (a portable fluorescent microscope can be used).

Species-level identification of orthopoxviruses with an oligonucleotide microchip.

A method for species-specific detection of orthopoxviruses pathogenic for humans and animals is described. The method is based on hybridization of a fluorescently labeled amplified DNA specimen with the oligonucleotide DNA probes immobilized on a microchip (MAGIChip). The probes identify species-specific sites within the crmB gene encoding the viral analogue of tumor necrosis factor receptor, one of the most important determinants of pathogenicity in this genus of viruses. The diagnostic procedure takes 6 h and does not require any sophisticated equipment (a portable fluorescence reader can be used).