[Intranasal vaccine against COVID-19 based on a recombinant variant of the Sendai virus (Paramyxoviridae: Respirovirus) strain Moscow].

INTRODUCTION: Intranasal vaccination using live vector vaccines based on non-pathogenic or slightly pathogenic viruses is the one of the most convenient, safe and effective ways to prevent respiratory infections, including COVID-19. Sendai virus is the best suited for this purpose, since it is respiratory virus and is capable of limited replication in human bronchial epithelial cells without causing disease. The aim of the work is to design and study the vaccine properties of recombinant Sendai virus, Moscow strain, expressing secreted receptor-binding domain of SARS-CoV-2 Delta strain S protein (RBDdelta) during a single intranasal immunization. MATERIALS AND METHODS: Recombinant Sendai virus carrying insertion of RBDdelta transgene between P and M genes was constructed using reverse genetics and synthetic biology methods. Expression of RBDdelta was analyzed by Western blot. Vaccine properties were studied in two models: Syrian hamsters and BALB/c mice. Immunogenicity was evaluated by ELISA and virus-neutralization assays. Protectiveness was assessed by quantitation of SARS-CoV-2 RNA in RT-PCR and histological analysis of the lungs. RESULTS: Based on Sendai virus Moscow strain, a recombinant Sen-RBDdelta(M) was constructed that expressed a secreted RBDdelta immunologically identical to natural SARS-CoV-2 protein. A single intranasal administration of Sen-RBDdelta(M) to hamsters and mice significantly, by 15 and 107 times, respectively, reduced replicative activity of SARS-CoV-2 in lungs of animals, preventing the development of pneumonia. An effective induction of virus-neutralizing antibodies has also been demonstrated in mice. CONCLUSION: Sen-RBDdelta(M) is a promising vaccine construct against SARS-CoV-2 infection and has a protective properties even after a single intranasal introduction.

[Prevalence and molecular genetic characteristics of parenteral hepatitis B, C and D viruses in HIV positive persons in the Novosibirsk region].

INTRODUCTION: Parenteral viral hepatitis (B, C, D) and HIV share modes of transmission and risk groups, in which the probability of infection with two or more of these viruses simultaneously is increased. Mutual worsening of the course of viral infections is important issue that occurs when HIV positive patients are coinfected with parenteral viral hepatitis. The aim of the study was to determine the prevalence of HCV, HBV and HDV in HIV positive patients in the Novosibirsk region and to give molecular genetic characteristics of their isolates. MATERIALS AND METHODS: Total 185 blood samples were tested for the presence of total antibodies to HCV, HCV RNA, HBV DNA and HDV RNA. The identified isolates were genotyped by amplification of the NS5B gene fragment for HCV, the polymerase gene for HBV and whole genome for HDV. RESULTS: The total antibodies to HCV were detected in 51.9% (95% CI: 44.758.9), HCV RNA was detected in 32.9% (95% CI: 26.639.5) of 185 studied samples. The distribution of HCV RNA positive cases completely repeated the distribution of HCV serological markers in different sex and age groups. The number of HCV infected among HIV positive patients increases with age. HCV subgenotypes distribution was as follows: 1b (52.5%), 3а (34.5%), 1а (11.5%), 2а (1.5%). 84.3% of detected HCV 1b isolates had C316N mutation associated with resistance to sofosbuvir and dasabuvir. The prevalence of HBV DNA in the studied samples was 15.2% (95% CI: 10.721.0). M204I mutation associated with resistance to lamivudine and telbivudine was identified in one HBV isolate. Two HDV isolates that belonged to genotype 1 were detected in HIV/HBV coinfected patients. CONCLUSION: The data obtained confirm the higher prevalence of infection with parenteral viral hepatitis among people living with HIV in the Novosibirsk region compared to the general population of that region. The genetic diversity of these viruses among HIV infected individuals is similar to that observed in the general population.

Reporter Transgenes for Monitoring the Antitumor Efficacy of Recombinant Oncolytic Viruses.

Accurate measurement of tumor size and margins is crucial for successful oncotherapy. In the last decade, non-invasive imaging modalities, including optical imaging using non-radioactive substrates, deep-tissue imaging with radioactive substrates, and magnetic resonance imaging have been developed. Reporter genes play the most important role among visualization tools; their expression in tumors and metastases makes it possible to track changes in the tumor growth and gauge therapy effectiveness. Oncolytic viruses are often chosen as a vector for delivering reporter genes into tumor cells, since oncolytic viruses are tumor-specific, meaning that they infect and lyse tumor cells without damaging normal cells. The choice of reporter transgenes for genetic modification of oncolytic viruses depends on the study objectives and imaging methods used. Optical imaging techniques are suitable for in vitro studies and small animal models, while deep-tissue imaging techniques are used to evaluate virotherapy in large animals and humans. For optical imaging, transgenes of fluorescent proteins, luciferases, and tyrosinases are used; for deep-tissue imaging, the most promising transgene is the sodium/iodide symporter (NIS), which ensures an accumulation of radioactive isotopes in virus-infected tumor cells. Currently, NIS is the only reporter transgene that has been shown to be effective in monitoring tumor virotherapy not only in preclinical but also in clinical studies.

[Mucosal immunity and vaccines against viral infections].

Mucosal immunity is realized through a structural and functional system called mucose-associated lymphoid tissue (MALT). MALT is subdivided into parts (clusters) depending on their anatomical location, but they all have a similar structure: mucus layer, epithelial tissue, lamina propria and lymphoid follicles. Plasma cells of MALT produce a unique type of immunoglobulins, IgA, which have the ability to polymerize. In mucosal immunization, the predominant form of IgA is a secretory dimer, sIgA, which is concentrated in large quantities in the mucosa. Mucosal IgA acts as a first line of defense and neutralizes viruses efficiently at the portal of entry, preventing infection of epithelial cells and generalization of infection. To date, several mucosal antiviral vaccines have been licensed, which include attenuated strains of the corresponding viruses: poliomyelitis, influenza, and rotavirus. Despite the tremendous success of these vaccines, in particular, in the eradication of poliomyelitis, significant disadvantages of using attenuated viral strains in their composition are the risk of reactogenicity and the possibility of reversion to a virulent strain during vaccination. Nevertheless, it is mucosal vaccination, which mimics a natural infection, is able to induce a fast and effective immune response and thus help prevent and possibly stop outbreaks of many viral infections. Currently, a number of intranasal vaccines based on a new vector approach are successfully undergoing clinical trials. In these vaccines, the safe viral vectors are used to deliver protectively significant immunogens of pathogenic viruses. The most tested vector for intranasal vaccines is adenovirus, and the most significant immunogen is SARSCoV-2 S protein. Mucosal vector vaccines against human respiratory syncytial virus and human immunodeficiency virus type 1 based on Sendai virus, which is able to replicate asymptomatically in cells of bronchial epithelium, are also being investigated.

[The Challenges of Vaccine Development Against Betacoronaviruses: Antibody Dependent Enhancement and Sendai Virus as a Possible Vaccine Vector].

To design an effective and safe vaccine against betacoronaviruses, it is necessary to elicit a combination of strong humoral and cell-mediated immune responses as well as to minimize the risk of antibody-dependent enhancement of viral infection. This phenomenon was observed in animal trials of experimental vaccines against SARS-CoV-1 and MERS-CoV that were developed based on inactivated coronavirus or vector constructs expressing the spike protein (S) of the virion. The substitution and glycosylation of certain amino acids in the antigenic determinants of the S-protein, as well as its conformational changes, can lead to the same effect in a new experimental vaccine against SARS-CoV-2. This review outlines approaches for developing vaccines against the new SARS-CoV-2 coronavirus that are based on non-pathogenic viral vectors. For efficient prevention of infections caused by respiratory pathogens the ability of the vaccine to stimulate mucosal immunity in the respiratory tract is important. Such a vaccine can be developed using non-pathogenic Sendai virus vector, since it can be administered intranasally and induce a mucosal immune response that strengthens the antiviral barrier in the respiratory tract and provides reliable protection against infection. The mucosal immunity and the production of IgA antibodies accompanying its development reduces the likelihood of developing an antibody-dependent infection enhancement, which is usually associated only with immunopathological IgG antibodies.

The Challenges of Vaccine Development against Betacoronaviruses: Antibody Dependent Enhancement and Sendai Virus as a Possible Vaccine Vector.

To design an effective and safe vaccine against betacoronaviruses, it is necessary to use their evolutionarily conservative antigenic determinants that will elicit the combination of strong humoral and cell-mediated immune responses. Targeting such determinants minimizes the risk of antibody-dependent enhancement of viral infection. This phenomenon was observed in animal trials of experimental vaccines against SARS-CoV-1 and MERS-CoV that were developed based on inactivated coronavirus or vector constructs expressing the spike protein (S) of the virion. The substitution and glycosylation of certain amino acids in the antigenic determinants of the S-protein, as well as its conformational changes, can lead to the same effect in a new experimental vaccine against SARS-CoV-2. Using more conservative structural and accessory viral proteins for the vaccine antigenic determinants will help to avoid this problem. This review outlines approaches for developing vaccines against the new SARS-CoV-2 coronavirus that are based on non-pathogenic viral vectors. For efficient prevention of infections caused by respiratory pathogens the ability of the vaccine to stimulate mucosal immunity in the respiratory tract is important. Such a vaccine can be developed using non-pathogenic Sendai virus vector, since it can be administered intranasally and induce a mucosal immune response that strengthens the antiviral barrier in the respiratory tract and provides reliable protection against infection.

[Combination of Oncolytic Virotherapy and CAR T/NK Cell Therapy for the Treatment of Cancer].

Multiple lines of evidence indicate that CAR-T cell based therapy and oncolytic virotherapy display robust performance in both immunocompetent and immunodeficient mouse models. Rare, yet highly successful attempts to combine these therapeutic platforms have also been reported. Interestingly, both approaches have shown pronounced efficacy in human trials, albeit these were limited to just a handful of malignancies. Specifically, CD19-specific CAR-T cell products (Kymriah and Yescarta) have been highly effective against B cell lymphomas and leukemias, whereas administering oncolytic viruses resulted in pronounced responses in melanoma (Imlygic and Rigvir) and nasopharyngeal carcinoma (Oncorine) patients. It is well established that efficacy of virotherapy as a standalone approach is largely restricted by the pre-existing and mounting immune response against viral antigens, and requires a relatively functional immune system, which is not typical for cancer patients, with the current antitumor therapy schemes. On the other hand, the most important challenges faced by the current CAR-T cell therapy formats include the lack of targetable tumor-specific surface antigens, tumor cell heterogeneity, and immunosuppressive tumor microenvironment, not to mention the unacceptably high costs. Remarkably, combining the two approaches may help address their individual bottlenecks. Namely, local acute inflammatory reaction induced by the viral infection may reverse tumor-associated immunosuppression and lead to more efficient homing and penetration of CAR-expressing lymphocytes into the tumor stroma; combined viral and CAR-mediated cytotoxicity may ensure the production of immunogenic cell debris and efficient presentation of tumor neoantigens, and potently recruit the patient's own bystander immune cells to attack cancer cells. Thus, testing the combinations of CAR-based and virolytic approaches in the clinical setting appears both logical and highly promising.

[Oncolytic Paramyxoviruses: Mechanism of Action, Preclinical and Clinical Studies].

Preclinical studies demonstrate that a broad spectrum of human and animal malignant cells can be killed by oncolytic paramyxoviruses, which includes cells of ecto-, endo- and mesodermal origin. In clinical trials, significant reduction or even complete elimination of primary tumors and established metastases has been reported. Different routes of virus administration (intratumoral, intravenous, intradermal, intraperito-neal, or intrapleural) and single- vs. multiple-dose administration schemes have been explored. The reported side effects were grades 1 and 2, with the most common among them being mild fever. There are certain advantages in using paramyxoviruses as oncolytic agents compared to members of other virus families exist. Thanks to cytoplasmic replication, paramyxoviruses do not integrate the host genome or engage in recombination, which makes them safer and more attractive candidates for widely used therapeutic oncolysis than ret-roviruses or some DNA viruses. The list of oncolytic Paramyxoviridae members includes the attenuated measles virus, mumps virus, low pathogenic Newcastle disease, and Sendai viruses. Metastatic cancer cells frequently overexpress certain surface molecules that can serve as receptors for oncolytic paramyxoviruses. This promotes specific viral attachment to these malignant cells. Paramyxoviruses are capable of inducing efficient syncytium-mediated lysis of cancer cells and elicit strong immune stimulation, which dramatically enforces anticancer immune surveillance. In general, preclinical studies and phases I-III of clinical trials yield very encouraging results and warrant continued research of oncolytic paramyxoviruses as a particularly valuable addition to the existing panel of cancer-fighting approaches.

Mechanisms of Oncolysis by Paramyxovirus Sendai.

Some viral strains of the Paramyxoviridae family may be used as anti-tumor agents. Oncolytic paramyxoviruses include attenuated strains of the measles virus, Newcastle disease virus, and Sendai virus. These viral strains, and the Sendai virus in particular, can preferentially induce the death of malignant, rather than normal, cells. The death of cancer cells results from both direct killing by the virus and through virus-induced activation of anticancer immunity. Sialic-acid-containing glycoproteins that are overexpressed in cancer cells serve as receptors for some oncolytic paramyxoviruses and ensure preferential interaction of paramyxoviruses with malignant cells. Frequent genetic defects in interferon and apoptotic response systems that are common to cancer cells ensure better susceptibility of malignant cells to viruses. The Sendai virus as a Paramyxovirus is capable of inducing the formation of syncytia, multinuclear cell structures which promote viral infection spread within a tumor without virus exposure to host neutralizing antibodies. As a result, the Sendai virus can cause mass killing of malignant cells and tumor destruction. Oncolytic paramyxoviruses can also promote the immune-mediated elimination of malignant cells. In particular, they are powerful inducers of interferon and other cytokynes promoting antitumor activity of various cell components of the immune response, such as dendritic and natural killer cells, as well as cytotoxic T lymphocytes. Taken together these mechanisms explain the impressive oncolytic activity of paramyxoviruses that hold promise as future, efficient anticancer therapeutics.

[Apoptin enhances the oncolytic activity of vaccinia virus].

Chicken anemia virus gene encoding apoptin, a selective killer of cancer cells was synthesized and inserted into vaccinia virus (strain L-IVP) genome. The insertion has replaced major part of the viral C11R gene encoding viral growth factor (VGF), which is important for the virulence. The recombinant virus VVdGF-ApoS24/2 was obtained through the transient dominant selection technique with the use of puromycin resistance gene as the selective marker. The expression apoptin gene from a synthetic early-late promoter of vaccinia virus effectively provides accumulation of the protein in the cells infected with the VVdGF-ApoS24/2 virus. Despite the presence of virus growth factor signal peptide at apoptin N-terminal secretion of the recombinant protein into culture medium did not occur. The recombinant virus VVdGF-ApoS24/2 was found to have a significantly greater selective lyticactivity on human cancer cell lines (A549, A431, U87MG, RD and MCF7) as compared with the parent strain L-IVP and its variant VVdGF2/6 with the deletion of the C11R gene. The results suggest that the use of apoptin represents a promising approach for improving the natural anticancer activities of vaccinia virus.

[Oncolytic properties of some orthopoxviruses, adenoviruses and parvoviruses in human glioma cells].

UNLABELLED: Currently one of the most promising approaches in development of cancer virotherapy is based on the ability of oncolytic viruses to selective infection and lysis of tumor cells. AIM: The goal of the study was to identify and evaluate perspective oncolytic viruses capable of selectively destroying human glioma cells. PATIENTS AND METHODS: Original GB2m, GA14m and GB22m glioma cell cultures derived from patients were used for evaluating in vitro oncolytic activity of some typical orthopoxviruses, adenoviruses and parvoviruses. RESULTS: The oncolytic activity in the human glioma cell models was confirmed for LIVP and WR strains of vaccinia virus, Adel2 and Ad2del strains with deletions within E1B/55K gene and derived from human adenoviruses type 2 and 5, respectively. CONCLUSIONS: We consider these oncolytic viruses as promising agents for the treatment of human malignant glioma.

[Oncolytic poxviruses].

The latest data on selection and construction of poxviruses capable of specifically lysing tumor cells of different genesis, inducing antitumor immunity and apoptosis of malignant cells are discussed. The review concerns several directions: virus attenuation, insertion of immunomodulatory protein genes, and anti-tumor protein genes. Thymidine kinase and viral growth factor genes make the greatest contribution to the virus attenuation as their inactivation results in the virus inability to replicate in non-dividing cells, thereby contributing to increased selectivity with respect to tumor cells. Among the immunomodulatory proteins, interleukins 2, 12, and granulocyte-macrophage colony-stimulating factor proved to be most promising for oncolytic virotherapy. An attempt to use p53 protein gene expressed by vaccinia virus for addressed apoptosis of tumor cells was reported. The use of the double and triple viral recombinants carrying genes of multidirectional action seems to be most promising. Encouraging results were obtained using vaccinia virus in the oncotherapy with prodrugs and angiogenesis inhibitors. At present, two poxviral strains are undergoing Phase III clinical trials as anti-tumor preparations in the USA.

[Orthopoxvirus genes for kelch-like proteins. III. Construction of mousepox (ectromelia) virus variants with targeted gene deletions].

Mousepox (ectromelia) virus genome contains four genes encoding for kelch-like proteins EVM018, EVM027, EVM150 and EVM167. A complete set of insertion plasmids was constructed to allow the production of recombinant ectromelia viruses with targeted deletions of one to four genes of kelch family both individually (single mutants) and in different combinations (double, triple and quadruple mutants). It was shown that deletion of any of the three genes EVMO18, EVM027 or EVM167 resulted in reduction of 50% lethal dose (LD50) by five and more orders in outbred white mice infected intraperitoneally. Deletion of mousepox kelch-gene EVM150 did not influence the virus virulence. Two or more kelch-genes deletion also resulted in high level of attenuation, which could evidently be due to the lack of three genes EVM167, EVM018 and/or EVM027 identified as virulence factors. The local inflammatory process on the model of intradermal injection of mouse ear pinnae (vasodilatation level, hyperemia, cutaneous edema, arterial thrombosis) was significantly more intensive for wild type virus and virulent mutant deltaEVM150 in comparison with avirulent mutant AEVM167.

[Investigation of the impact of cowpox virus BTB/kelch gene deletion on some characteristics of infection in vitro].

The biological properties of cowpox virus (CPXV) mutants with target deletion of 4 of the 6 BTB/kelch genes (D11L, C18L, G3L, and A56R) were examined in CV-1 cell cultures. There were changes in mutant temperature sensitivity and a reduction in a viral cytopathic effect. The mutant-infected culture yielded a smaller number of cells with actin-related long cellular protrusions (63 of 300 cells) as compared with wild CPXV (127 of 300). The length of the protrusions was 20-60 and 40-120 microm, respectively). Confocal microscopy revealed the formation of large globed structures containing both actin and CPXV antigens in the cells infected with quadruple mutants. These globed structures were recognized as incomplete protrusions. The findings show that the formation of long protrusions in the cells infected with wild type CPXV represents a type of specific viral potency related to the activity of BTB/kelch genes whose deletion results in cellular insufficiency to form full-fledged protrusions.

[Detection of the virus of hepatitis E isolates and elucidation of the possibility of their replication in vitro].

Blood serum samples collected from patients with acute hepatitis symptoms admitted to Infectious Disease Hospitals of Novosibirsk, Barnaul, and Irkutsk were studied. The serum samples were tested for the IgM and IgG antibodies to HEV using ELISA. Seropositive samples were tested using RT-PCR for HEV RNA. Two HEV strains were isolated, and thus HEV infection was identified for West Siberia. One of this strains is classified as HEV genotype I; the other, as genotype III. Cell culturing of these strains in green monkey kidney (4647) cells showed an ability of HEV genotype I strain to cause persistent infection.

Comparative study of pathological changes in the mouse viscera in infection caused by two orthopoxviruses.

The mechanisms of infection development in intraperitoneal inoculation of mice by ectromelia virus strain K-1 and cowpox strain EP-2 were studied. Ultrastructural parameters of virus assembly and maturation are described. Differences in the types of cells replicating the viruses and in the type of visceral injuries were detected. The studies showed a local type of strain EP-2 cowpox infection and dissemination of ectromelia strain K-1.

[Reproduction of cowpox virus strain EP-2 isolated from an elephant in primary fibroblast cultures and chorion-allantoic chick embryos].

Electron microscopy was used to study the reproduction of cowpox virus strain EP-2 in the cells of a primary fibroblast cultures (PFC) and chorion-allantoic membrane (CAM) of chick embryos (CE). The sequential stages of viral morphogenesis and the structure of A-type inclusions were described. The parameters of viral reproduction in PFC and CE CAM were compared. The formation of crystalloid tubular structures in PFC, unusual electron dense inclusions in the cells of CE CAN, and different variants of A-type inclusions in the cells of a pock was found. The histological and ultrastructural characteristics of pocks in CE CAM are described.

[Genetic diversity of hepatitis A virus in Siberia].

The nucleotide sequences of a region of VP1/2A genes of a large group of hepatitis A virus (HAV) isolates circulating in Siberia (the Altai Territory, the Irkutsk and Novosibirsk Regions) were determined. Comparison of these sequences with those of prototype HAV of genotypes IA, IB, and IIA revealed their high similarity to prototype genotype IA strains. The above domains were shown to contain the types of viruses, which were close to both the European subtypes of HAV genotypes IA (78.3%) and the Far Eastern subtypes of this genotype (21.7%). The similar comparison of the derived amino acid sequences suggests that VP1 and 2A contains the amino acid substitutions that are typical of this geographical region.

[Genetic variability of hepatitis B virus isolates among population of Shuryskarsky area of Yamal-Nenets autonomous region].

UNLABELLED: The purpose of this work was to determine occurrence of serological markers of hepatites B and to describe subtypes of a superficial antigen and genotypes of hepatitis B virus (HBV) isolates among indigenous population of Yamal-Nenets Autonomous Region (YNAR), Russia. METHODS: We investigated 657 serum samples from inhabitants of Shuryskarsky area of YNAR. ELISA method was used to define the hepatitis B markers: HBsAg, anti-HBs (total) and anti-HBc (IgG and IgM). The HBsAg-positive samples were PCR-tested for the presence of HBV DNA. Genotyping of isolates was by sequencing of the Pre-Sl/Pre-82/S region of HBV genome and phylogenetic analysis. Definition of HBsAg subtypes was executed by two methods: ELISA with subtype-specific monoclonal antibodies and S-gene nucleotide sequence analysis. RESULTS: The following occurrence of hepatitis B markers was observed: HBsAg - 3.2%, anti-HBs (total) - 36.2%, anti-HBc IgG - 30.3%, anti-HBc IgM - 1.6%. Frequency of carrying even one of the markers in the observed population was 47.5%. HBV DNA was found in 17 HBsAg-positive samples. Pre-SI, Pre-S2 and S regions sequences were determined for all HBV DNA-positive samples. The phylogenetic analysis showed an accessory of all investigated HBV isolates to genotype D. HBsAg subtypes distribution appeared the following: ayw2 - 23.5%, ayw3 - 70.6%, adw2 - 5.9%. Results of definition of the subtype ELISA method and by the analysis of S gene nucleotide sequences have coincided in 10/11 (90.1%) cases. CONCLUSIONS: The indigenous population of Shuryskarsky area of YNAR belongs to groups with average HBV carrying. Absolute domination of genotype D (subtypes ayw2, ayw3 and adw2) was revealed. High percentage of concurrence of HBsAg subtypes detected by the ELISA method and method of the analysis of S gene primary structure (90%) was observed. Sequencing of HBV S-gene is preferable to define HBsAg subtypes.

[Fusion proteins encoded by orf 129L of ectromelia and orf A30L of smallpox viruses cross-react with neutralizing monoclonal antibodies].

Open reading frame (orf) 129L of ectromelia (EV) and orf A30L of smallpox viruses (SPV) encoding fusion proteins were cloned and expressed in E. coli cells. The recombinant polypeptides (prA30L H pr129L) were purified from cell lysates by Ni-NTA chromatography. Recombinant polypeptides were able to form trimers in buffered saline and they destroyed under treatment with SDS and 2-mercaptoethanol. Reactivity of prA30L, pr129L and orthopoxvirus proteins was analyzed by ELISA and Western blotting with panel of 22 monoclonal antibodies (MAbs) against orthopoxviruses (19 against EV, 2 MAbs against vaccinia virus and 1 Mabs against cowpox virus). This data allowed us to conclude that there are 12 EV-specific epitopes of pr129L and EV fusion proteins, ten orthopox-specific epitopes of EV, VV, CPV fusion proteins, from them 9 orthopox-specific epitopes of prA30L and SPV fusion proteins. Five Mabs, which cross-reacted with orthopox-specific epitopes, were able to neutralize the VV on Vero cells and from them two MAbs has neutralizing activity against smallpox virus. Our findings demonstrate that 129L fusion protein have EV-specific epitopes, that EV 129L and SPV A30L fusion proteins have a several orthopox-specific epitopes to induce a neutralizing antibodies against human pathogenic orthopoxviruses.