La viruela símica como enfermedad zoonótica viral y reemergente en el actual contexto sanitario mundial / Mpox as a Viral Zoonotic Disease Reemerging in the Current Global Health Context

Introducción: La viruela símica es una enfermedad zoonótica que también se trasmite de persona a persona por contacto estrecho. En el brote actual hasta el 31 de agosto de 2022 se reportaban 50 496 casos diagnosticados en 101 países, por lo que se consideró una situación preocupante por la Organización Mundial de la Salud. Objetivo: Exponer información actualizada sobre la viruela símica en el contexto sanitario actual. Métodos: Se realizó una búsqueda de literatura científica en las bases de datos ScienceDirect, PubMed/Medline, SciELO y Google Académico, mediante los descriptores o palabras relacionadas con la enfermedad, para encontrar revisiones, comunicados, informes, distintos artículos de revistas, entre otros documentos especializados de producción científica. Se seleccionó un total de 30 citas, actualizadas en su totalidad. Desarrollo: Desde su identificación en humanos se han reportado brotes de viruela símica en varios países; el más preocupante, ha sido el de reciente declaración en 2022, debido a la presencia de casos en países no endémicos, con un alcance geográfico extenso. Las manifestaciones clínicas pueden cursar con síntomas leves, como erupciones en la cara y el resto del cuerpo, fiebre, cefalea, mialgias y fatiga, por lo que no constituye una enfermedad potencialmente mortal; sin embargo, de presentarse comorbilidades la evolución podría ser tórpida. Conclusiones: La presencia de casos de viruela símica en humanos se ha mantenido desde su aparición, sin encontrar un tratamiento específico y vacunas autorizadas para su administración, lo que podría generar un aumento de contagios y fallecidos(AU)

Introduction: Mpox is a zoonotic disease also transmitted from person to person by close contact. The current outbreak, up to August 31, 2022, reported 50 496 diagnosed cases from 101 countries; therefore; it was considered a situation of concern by the World Health Organization. Objective: To present updated information on Mpox in the current health context. Methods: A scientific literature search was carried out in the databases ScienceDirect, PubMed/Medline, SciELO and Google Scholar, using descriptors or words related to the disease, in order to find reviews, communications, reports, different journal articles, among other specialized documents of scientific production. A total of 30 entirely updated citations were selected. Development: Since Mpox was identified in humans, outbreaks of the disease have been reported in several countries; the most worrisome has been reported recently in 2022, due to the presence of cases in nonendemic countries, with an extensive geographical scope. The clinical manifestations may occur with mild symptoms, such as rash on the face or the rest of the body, fever, headache, myalgia and fatigue; therefore, it is not a potentially mortal disease. However, in case of comorbidity, the evolution could be torpid. Conclusions: Mpox cases in humans has been present since its appearance, without any specific treatment or vaccines authorized to be administered, which could generate an increase in contagions and deaths(AU)

Mpox multi-antigen mRNA vaccine candidates by a simplified manufacturing strategy afford efficient protection against lethal orthopoxvirus challenge.

Current unprecedented mpox outbreaks in non-endemic regions represent a global public health concern. Although two live-attenuated vaccinia virus (VACV)-based vaccines have been urgently approved for people at high risk for mpox, a safer and more effective vaccine that can be available for the general public is desperately needed. By utilizing a simplified manufacturing strategy of mixing DNA plasmids before transcription, we developed two multi-antigen mRNA vaccine candidates, which encode four (M1, A29, B6, A35, termed as Rmix4) or six (M1, H3, A29, E8, B6, A35, termed as Rmix6) mpox virus antigens. We demonstrated that those mpox multi-antigen mRNA vaccine candidates elicited similar potent cross-neutralizing immune responses against VACV, and compared to Rmix4, Rmix6 elicited significantly stronger cellular immune responses. Moreover, immunization with both vaccine candidates protected mice from the lethal VACV challenge. Investigation of B-cell receptor (BCR) repertoire elicited by mpox individual antigen demonstrated that the M1 antigen efficiently induced neutralizing antibody responses, and all neutralizing antibodies among the top 20 frequent antibodies appeared to target the same conformational epitope as 7D11, revealing potential vulnerability to viral immune evasion. Our findings suggest that Rmix4 and Rmix6 from a simplified manufacturing process are promising candidates to combat mpox.

Recombinant Virus-like Particles of Human Parvovirus B19 with the Internal Location of VP1 Unique Region Produced by Hansenula polymorpha.

Human parvovirus B19 (HPV B19) is pathogenic to human, which can cause fifth disease, transient aplastic crisis, arthritis, myocarditis, autoimmune disorders, hydrops fetalis, and so on. Currently, no approved vaccines or antiviral drugs are available against HPV B19, and thus the development of effective vaccines is needed. The capsid of HPV B19 is composed of two types of proteins, i.e., the major capsid protein VP2 and the minor protein VP1. Previous experimental studies have shown that the dominant immune responses against HPV B19 are elicited by VP1, especially the unique region on the N-terminus of VP1. It has been found that VP2 alone or VP2 and VP1 together can assemble into virus-like particle (VLP). The VLP structure formed by VP2 has been resolved, however, the location of VP1 in the capsid, especially the location of VP1 unique region with strong immunogenicity, is still not clear. In the present work, using the Hansenula polymorpha expression system developed by our laboratory, two kinds of recombinant HPV B19 VLPs were expressed, i.e., the VLP co-assembled by VP1 and VP2 (VP1/VP2 VLP) and the VLP whose VP1 content was improved (VP1h/VP2 VLP). The expression, purity, and morphology of these two VLPs were characterized, and then their immunogenic properties were investigated and compared with those of the VLP containing VP2 alone (VP2 VLP) previously developed by our group. Furthermore, the location of the VP1 unique region in the VLPs was determined by using the immunogold electron microscopy (IGEM). Our experimental results show that the VP1h/VP2 VLP elicits a stronger neutralization against the HPV B19 than VP2 and VP1/VP2 VLPs, which implies that the increase of VP1 content significantly improves the level of neutralizing antibodies. In addition, the IGEM observations suggest that the unique region of VP1 may be located inside the recombinant VLP. The VLPs recombinantly expressed by our Hansenula polymorpha system may serve as a promising candidate immunogen for HPV B19 vaccine development.

Genomic Sequencing and Phylogenomics of Cowpox Virus.

Cowpox virus (CPXV; genus Orthopoxvirus; family Poxviridae) is the causative agent of cowpox, a self-limiting zoonotic infection. CPXV is endemic in Eurasia, and human CPXV infections are associated with exposure to infected animals. In the Fennoscandian region, five CPXVs isolated from cats and humans were collected and used in this study. We report the complete sequence of their genomes, which ranged in size from 220-222 kbp, containing between 215 and 219 open reading frames. The phylogenetic analysis of 87 orthopoxvirus strains, including the Fennoscandian CPXV isolates, confirmed the division of CPXV strains into at least five distinct major clusters (CPXV-like 1, CPXV-like 2, VACV-like, VARV-like and ECTV-Abatino-like) and can be further divided into eighteen sub-species based on the genetic and patristic distances. Bayesian time-scaled evolutionary history of CPXV was reconstructed employing concatenated 62 non-recombinant conserved genes of 55 CPXV. The CPXV evolution rate was calculated to be 1.65 × 10-5 substitution/site/year. Our findings confirmed that CPXV is not a single species but a polyphyletic assemblage of several species and thus, a reclassification is warranted.

Nota Técnica N. 2/2022 - SES/ASREA - 18776 - Nota técnica de manejo da Monkeypox em gestantes, puérperas e lactantes / Technical Note N. 2/2022 - SES/ASREA- 18776 - Technical note on the management of Monkeypox in pregnant, postpartum and lactating women

A presente nota técnica tem como objetivo orientar os profissionais de saúde em relação à condução dos casos suspeitos e/ou confirmados de Monkeypox em gestantes, puérperas e lactantes. A Monkeypox (MPX) ou Varíola M é uma doença causada pelo vírus Monkeypox do gênero Orthopoxvirus e família Poxviridae. Trata-se de uma zoonose viral cuja transmissão pode ocorrer por meio do contato desprotegido com lesões ou fluidos corporais (contato sexual, saliva, olhos, cavidade oral) e/ou materiais contaminados (roupa de cama, vestes, utensílios domésticos)

This technical note aims to guide health professionals in relation to the management of suspected and/or confirmed cases of Monkeypox in pregnant, postpartum and lactating women. Monkeypox (MPX) or Smallpox M is a disease caused by the Monkeypox virus of the genus Orthopoxvirus and family Poxviridae. It is a viral zoonosis whose transmission can occur through unprotected contact with injuries or bodily fluids (sexual contact, saliva, eyes, sinus oral) and/or contaminated materials (bedding, clothing, household items)

Viruela símica: zoonosis emergente con impacto global / Monkeypox: emerging zoonosis with unprecedentedglobal impact

El virus de la viruela símica es un orthopoxvirus de características zoonóticas endémico en las regiones de África Central y África Occidental, donde causa brotes desde 1970. En las últimas décadas se registró un aumento exponencial de casos, probablemente asociado a la disminución en la inmunidad conferida por la vacuna antivariólica, discontinuada luego de la erradicación de la viruela. En los últimos años se registraron casos esporádicos fuera del continente africano, siempre relacionados epidemiológicamente a la permanencia en áreas endémicas o contacto con animales infectados. Desde el 13 de mayo de 2022 se encuentra en curso el mayor brote de viruela símica registrado fuera de las áreas endémicas de África, con casos en los cinco continentes. La extensión, el impacto y la duración del brote permanecen aún inciertos.

Monkeypox virus is an orthopoxvirus with zoonotic characteristics endemic in Central and West Africa regions, where it has caused outbreaks since 1970. An exponential increase in cases has been registered in the last decades, probably associated with a decrease in the immunity conferred by the smallpox vaccine, discontinued after smallpox eradication. In recent years, sporadic cases have been reported outside the African continent, always epidemiologically related to permanence in endemic areas or contact with infected animals. Since May 13, 2022, the largest monkeypox outbreak ever reported outside Africa endemic areas, with cases on the five continents, is unfolding. The extent, impact and duration of this outbreak still remain uncertain

Use of JYNNEOS (Smallpox and Monkeypox Vaccine, Live, Nonreplicating) for Preexposure Vaccination of Persons at Risk for Occupational Exposure to Orthopoxviruses: Recommendations of the Advisory Committee on Immunization Practices - United States, 2022.

Certain laboratorians and health care personnel can be exposed to orthopoxviruses through occupational activities. Because orthopoxvirus infections resulting from occupational exposures can be serious, the Advisory Committee on Immunization Practices (ACIP) has continued to recommend preexposure vaccination for these persons since 1980 (1), when smallpox was eradicated (2). In 2015, ACIP made recommendations for the use of ACAM2000, the only orthopoxvirus vaccine available in the United States at that time (3). During 2020-2021, ACIP considered evidence for use of JYNNEOS, a replication-deficient Vaccinia virus vaccine, as an alternative to ACAM2000. In November 2021, ACIP unanimously voted in favor of JYNNEOS as an alternative to ACAM2000 for primary vaccination and booster doses. With these recommendations for use of JYNNEOS, two vaccines (ACAM2000 and JYNNEOS) are now available and recommended for preexposure prophylaxis against orthopoxvirus infection among persons at risk for such exposures.

[Isolation of a new strain М-2020 of the camelpox virus (Poxviridae: Orthopoxvirus: Camelpox virus) in Republic of Kazakhstan and study of its reproduction in various biological systems].

INTRODUCTION: This article presents the results of isolation of camel smallpox virus (Poxviridae: Orthopoxvirus: Camelpox virus, CMLPV) and study of its reproductive properties on sensitive biological systems. MATERIAL AND METHODS: The epizootic strain M-96 of the virus as well as its attenuated variants KM-40 and KM-70 obtained by sequential passivation were used in the study. Isolation of the pathogen from suspension of biopsy specimens was performed on cell culture and in embryonated chicken eggs (ECEs). All experiments were performed with the number of replications ensuring obtaining reliable results. RESULTS: The CMLPV was isolated from the crusts and pox papules of the skin taken from sick camels (Camelus bactrianus) during an outbreak in various districts of the Mangistau region at the end of 2019. The signs of pathogen reproduction on chorio-allantoic membrane (CAM) were observed from 3 passages. The obtained virus caused formation of pathological changes on the CAM in the form of elevated dot or solid white formations separated from the surrounding tissue, with hemorrhagic foci in the center. The reproductive properties of the isolate on sensitive biological systems were determined in comparison with the epizootic CMLPV strain M-96, isolated earlier in the territory of Kazakhstan during the outbreak 23-24 years ago, as well as its attenuated variants. The isolated virus was given the conventional name M-2020. DISCUSSION: When studied in two sensitive cultivation systems (cell culture and ECEs), strain M-96 and its attenuated variants KM-40, KM-70, which were used in the experiments as a control, demonstrated high infectious activity with titer 4.75-6.75 lg TCID50/cm3, while for the examined isolate M-2020 of CMLPV had the significantly lower values (3.00-4.75 lg TCID50/cm3, p > 0,05).

A recombinant rabies virus expressing Echinococcus granulosus EG95 induces protective immunity in mice.

Cystic echinococcosis (CE), caused by Echinococcus granulosus (E, is a zoonosis with a worldwide distribution, resulting in heavy impact to public health and social economics. In this study, we generated a recombinant rabies virus (RABV) expressing EG95 protein of E. granulosus (LBNSE-EG95) as a bivalent candidate vaccine for use in sheep and cattle against CE and rabies, which is another severe health threat in CE-endemic areas. It was found that EG95 was successfully expressed without altering the pathogenicity of parent LBNSE vector. Further study showed that LBNSE-EG95 immunization in mice elicited activation of dendric cells (DCs) and B cells and induced Th1-/Th2-mediated cellular immune responses, leading to robust production of RABV neutralizing antibodies and high level of EG95-sepecific antibodies with more than 90% protection against CE. In addition, single dose of LBNSE-EG95 conferred full protection against lethal RABV challenge in mice. Collectively, these results suggest that the recombinant LBNSE-EG95 has the potential to be developed as an efficient bivalent vaccine for sheep and cattle use in endemic areas of CE and rabies.

Rasgos clínicos y epidemiológicos de la viruela símica / Clinical and epidemiological features of monkeypox

La viruela símica (VS) es una enfermedad viral, zoonótica que afecta principalmente a los primates y se transmite a humanos. Dicho virus fue aislado inicialmente de un mono de laboratorio en la República Democrática del Congo en 1970 y a partir de allí, ha circulado en el continente africano, principalmente en República Democrática del Congo, Sudán del Sur, Camerún, República Centroafricana, Liberia, Nigeria, Sierra Leona y República del Congo; durante las últimas cinco décadas. Desde el año 2003 se reportaron casos fuera de África, específicamente en Estados Unidos, Reino Unido, Israel y Singapur; mientras que en mayo de 2022, la OMS; reportó un brote de VS humano en varios países de Europa y América, con más de 38000 casos en 93 países y cinco muertes en África, además de la ausencia de vínculos directos con países endémicos y un cambio en el patrón de transmisión; lo que conllevó al organismo a declarar el brote como emergencia de salud pública de interés internacional. La VS cursa con fiebre, cefalea, mialgias, linfadenopatia y lesiones dérmicas; y aunque la enfermedad no es fácilmente transmisible con tendencia a la curación espontánea; los casos observados actualmente no son típicos, con lesiones similares a las producidas por la viruela humana. La presente revisión tiene el objetivo de actualizar los conocimientos acerca de los rasgos clínicos y epidemiológicos de la VS, para comprender la presentación del brote actual y brindar herramientas que permitan diagnosticar y tratar eficazmente a los pacientes afectados(AU)

Monkeypox (MPX) is a viral, zoonotic disease that mainly affects primates and is transmitted to humans. This virus was initially isolated from a laboratory monkey in the Democratic Republic of the Congo in 1970 and since then has circulated on the African continent, mainly in the Democratic Republic of the Congo, South Sudan, Cameroon, the Central African Republic, Liberia, Nigeria, Sierra Leone, and Republic of the Congo; during the last five decades. Since 2003, cases have been reported outside of Africa, specifically in the United States, the United Kingdom, Israel, and Singapore; while in May 2022, the WHO; reported an outbreak of human MPX in several countries in Europe and America, with more than 38,000 cases in 93 countries and five deaths in Africa, in addition to the absence of direct links with endemic countries and a change in the pattern of transmission; which led the agency to declare the outbreak a public health emergency of international concern. MPX presents with fever, headache, myalgia, lymphadenopathy, and skin lesions; and although the disease is not easily transmissible with a tendency to spontaneous healing; the cases currently observed are not typical, with lesions similar to those produced by smallpox. This review aims to update knowledge about the clinical and epidemiological features of MPX, to understand the presentation of the current outbreak and provide tools that allow effective diagnosis and treatment of affected patients(AU)

Fatal Cowpox Virus Infection in Human Fetus, France, 2017.

Cowpox virus (CPXV) has an animal reservoir and is typically transmitted to humans by contact with infected animals. In 2017, CPXV infection of a pregnant woman in France led to the death of her fetus. Fetal death after maternal orthopoxvirus (smallpox) vaccination has been reported; however, this patient had not been vaccinated. Investigation of the patient's domestic animals failed to demonstrate prevalence of CPXV infection among them. The patient's diagnosis was confirmed by identifying CPXV DNA in all fetal and maternal biopsy samples and infectious CPXV in biopsy but not plasma samples. This case of fetal death highlights the risk for complications of orthopoxvirus infection during pregnancy. Among orthopoxviruses, fetal infection has been reported for variola virus and vaccinia virus; our findings suggest that CPXV poses the same threats for infection complications as vaccinia virus.

A class of viral inducer of degradation of the necroptosis adaptor RIPK3 regulates virus-induced inflammation.

The vaccine strain against smallpox, vaccinia virus (VACV), is highly immunogenic yet causes relatively benign disease. These attributes are believed to be caused by gene loss in VACV. Using a targeted small interfering RNA (siRNA) screen, we identified a viral inhibitor found in cowpox virus (CPXV) and other orthopoxviruses that bound to the host SKP1-Cullin1-F-box (SCF) machinery and the essential necroptosis kinase receptor interacting protein kinase 3 (RIPK3). This "viral inducer of RIPK3 degradation" (vIRD) triggered ubiquitination and proteasome-mediated degradation of RIPK3 and inhibited necroptosis. In contrast to orthopoxviruses, the distantly related leporipoxvirus myxoma virus (MYXV), which infects RIPK3-deficient hosts, lacks a functional vIRD. Introduction of vIRD into VACV, which encodes a truncated and defective vIRD, enhanced viral replication in mice. Deletion of vIRD reduced CPXV-induced inflammation, viral replication, and mortality, which were reversed in RIPK3- and MLKL-deficient mice. Hence, vIRD-RIPK3 drives pathogen-host evolution and regulates virus-induced inflammation and pathogenesis.

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.

Recombinant Orthopoxvirus Primes Colon Cancer for Checkpoint Inhibitor and Cross-Primes T Cells for Antitumor and Antiviral Immunity.

Although it is known that oncolytic viruses can inflame and recruit immune cells to otherwise immunosuppressed tumor microenvironments, the influence of the antiviral immune response on antitumor immunity is less clear across viral platforms and tumor types. CF33 is a recombinant orthopoxvirus backbone effective against colon cancer. We tested derivatives of CF33 with and without immune-checkpoint inhibition (anti-PD-L1) in mouse models of colon cancer. Results showed that the efficacy of CF33 backbone with J2R deletion (single-deleted) against colon cancer is not altered by additional deletion of F14.5L in vitro or in vivo CF33 infection upregulated PD-L1 expression on tumor cells and led to an increased influx of lymphocytes and macrophages in tumors. Also, the levels of active CD8+ (IFNγ+) T cells in the virus-treated tumors were higher than those in control-treated tumors. Furthermore, a combination of CF33 derivatives with anti-PD-L1 resulted in durable tumor regression and long-term survival, resistant to tumor rechallenge. Analysis of immune cells from the treated mice showed that tumor-specific T cell activation occurred more robustly in tumors treated with the virus and that T cells were more strongly activated against the virus than against tumor, in an MHC-I-dependent manner. Our findings warrant further studies on the role of cross-priming of T cells against viral and tumor antigens, in the overall success of viroimmunotherapy.

CRISPR/Cas9 as an antiviral against Orthopoxviruses using an AAV vector.

A vaccine for smallpox is no longer administered to the general public, and there is no proven, safe treatment specific to poxvirus infections, leaving people susceptible to infections by smallpox and other zoonotic Orthopoxviruses such as monkeypox. Using vaccinia virus (VACV) as a model organism for other Orthopoxviruses, CRISPR-Cas9 technology was used to target three essential genes that are conserved across the genus, including A17L, E3L, and I2L. Three individual single guide RNAs (sgRNAs) were designed per gene to facilitate redundancy in rendering the genes inactive, thereby reducing the reproduction of the virus. The efficacy of the CRISPR targets was tested by transfecting human embryonic kidney (HEK293) cells with plasmids encoding both SaCas9 and an individual sgRNA. This resulted in a reduction of VACV titer by up to 93.19% per target. Following the verification of CRISPR targets, safe and targeted delivery of the VACV CRISPR antivirals was tested using adeno-associated virus (AAV) as a packaging vector for both SaCas9 and sgRNA. Similarly, AAV delivery of the CRISPR antivirals resulted in a reduction of viral titer by up to 92.97% for an individual target. Overall, we have identified highly specific CRISPR targets that significantly reduce VACV titer as well as an appropriate vector for delivering these CRISPR antiviral components to host cells in vitro.

[Development of the drug oncolytic immunotherapy based on vaccinia viruses (Vaccinia virus, Orthopoxvirus, Chordopoxvirinae, Poxviridae) against breast cancer.]

INTRODUCTION: Currently, new directions in cancer therapy are actively developing, one of which is oncolytic immunotherapy. This approach would be to use of viruses as cancer specific cytolytic agents capable of stimulating both the tumor-specific and non-specific immune response. The objective paper was obtain a recombinant vaccinia virus containing genes encoding immunostimulating molecules and study oncolytic and immunostimulating properties of recombinant virus. MATERIAL AND METHODS: MTT test, ELISA, methods of transient dominant selection. RESULTS: The recombinant vaccinia virus (L-IVP_oncoB) were obtained with deletion of the gene encoding thymidine kinase and had an integrated gene encoding GM-CSF. Also the virus have deletion of the gene encoding viral growth factor and integrated genes encoding synthetic tumor-specific polyepitopic immunogens. It was shown that the modifications made to the viral genome did not affect the growth characteristics of the virus when cultured on CV-1 and 4647 cell cultures, and the cytopathogenic efficacy of the virus was determined in relation to cancer cultures of cells of various genesis. In in vivo experiment, it was revealed that the polyepitopic construct in the genome L-IVP_oncoB is able to initiate a change in the profile of cytokines. DISCUSSION: The obtained data characterized L-IVP_oncoB as a promising cytopathogenic and immunostimulating agent and showed the need for further study of its properties as means of oncolytic immunotherapy. CONCLUSION: The basic experiments on the evaluation of the biological properties of the obtained L-IVP_oncoB, which are necessary for the characterization of the oncolytic virus, have been carried out.

Identification of CP77 as the Third Orthopoxvirus SAMD9 and SAMD9L Inhibitor with Unique Specificity for a Rodent SAMD9L.

Orthopoxviruses (OPXVs) have a broad host range in mammalian cells, but Chinese hamster ovary (CHO) cells are nonpermissive for vaccinia virus (VACV). Here, we revealed a species-specific difference in host restriction factor SAMD9L as the cause for the restriction and identified orthopoxvirus CP77 as a unique inhibitor capable of antagonizing Chinese hamster SAMD9L (chSAMD9L). Two known VACV inhibitors of SAMD9 and SAMD9L (SAMD9&L), K1 and C7, can bind human and mouse SAMD9&L, but neither can bind chSAMD9L. Clustered regularly interspaced short palindromic repeat (CRISPR)-Cas9 knockout of chSAMD9L from CHO cells removed the restriction for VACV, while ectopic expression of chSAMD9L imposed the restriction for VACV in a human cell line, demonstrating that chSAMD9L is a potent restriction factor for VACV. In contrast to K1 and C7, cowpox virus CP77 can bind chSAMD9L and rescue VACV replication in cells expressing chSAMD9L, indicating that CP77 is yet another SAMD9L inhibitor but has a unique specificity for chSAMD9L. Binding studies showed that the N-terminal 382 amino acids of CP77 were sufficient for binding chSAMD9L and that both K1 and CP77 target a common internal region of SAMD9L. Growth studies with nearly all OPXV species showed that the ability of OPXVs to antagonize chSAMD9L correlates with CP77 gene status and that a functional CP77 ortholog was maintained in many OPXVs, including monkeypox virus. Our data suggest that a species-specific difference in rodent SAMD9L poses a barrier for cross-species OPXV infection and that OPXVs have evolved three SAMD9&L inhibitors with different specificities to overcome this barrier.IMPORTANCE Several OPXV species, including monkeypox virus and cowpox virus, cause zoonotic infection in humans. They are believed to use wild rodents as the reservoir or intermediate hosts, but the host or viral factors that are important for OPXV host range in rodents are unknown. Here, we showed that the abortive replication of several OPXV species in a Chinese hamster cell line was caused by a species-specific difference in the host antiviral factor SAMD9L, suggesting that SAMD9L divergence in different rodent species poses a barrier for cross-species OPXV infection. While the Chinese hamster SAMD9L could not be inhibited by two previously identified OPXV inhibitors of human and mouse SAMD9&L, it can be inhibited by cowpox virus CP77, indicating that OPXVs encode three SAMD9&L inhibitors with different specificities. Our data suggest that OPXV host range in broad rodent species depends on three SAMD9&L inhibitors with different specificities.

Identifying and Tracking Low-Frequency Virus-Specific TCR Clonotypes Using High-Throughput Sequencing.

Tracking antigen-specific T cell responses over time within individuals is difficult because of lack of knowledge of antigen-specific TCR sequences, limitations in sample size, and assay sensitivities. We hypothesized that analyses of high-throughput sequencing of TCR clonotypes could provide functional readouts of individuals' immunological histories. Using high-throughput TCR sequencing, we develop a database of TCRß sequences from large cohorts of mice before (naive) and after smallpox vaccination. We computationally identify 315 vaccine-associated TCR sequences (VATS) that are used to train a diagnostic classifier that distinguishes naive from vaccinated samples in mice up to 9 months post-vaccination with >99% accuracy. We determine that the VATS library contains virus-responsive TCRs by in vitro expansion assays and virus-specific tetramer sorting. These data outline a platform for advancing our capabilities to identify pathogen-specific TCR sequences, which can be used to identify and quantitate low-frequency pathogen-specific TCR sequences in circulation over time with exceptional sensitivity.