A poliovirus-susceptible transgenic mouse model as a possible replacement for the monkey neurovirulence test of oral poliovirus vaccine

Oncolytic viruses against cancer, promising or delusion?

Cancer treatment is one of the most challenging topics in medical sciences. Different methods such as chemotherapy, tumor surgery, and immune checkpoint inhibitors therapy (ICIs) are potential approaches to treating cancer and killing tumor cells, but clinical studies have shown that they have been successful for a limited group of patients. Using viruses as a treatment can be considered as an effective treatment in the field of medicine. This is considered as a potential treatment, especially in comparison to chemotherapy, which has severe side effects related to the immune system. Most oncolytic viruses (OVs) have the potential to multiply in cancer cells, which are more than normal cells in malignant tissue and can induce immune responses. Therefore, tons of efforts and research have been started on the utilization of OVs as a treatment for cancer and have shown promising in treating cancers with less side effects. In this article, we have gathered studies about oncolytic viruses and their effectiveness in cancer treatment.Please confirm if the author names are presented accurately and in the correct sequence (given name, middle name/initial, family name). Author 1 Given name: [Omid Salahi] Last name [Ardekani], Author 2 Given name: [Mohammad Mehdi] Last name [Fazeli], Author 3 Given name: [Nillofar Asadi] Last name [Jemezghani]. Also, kindly confirm the details in the metadata are correct.Confirmed.

The Use of Next-Generation Sequencing for the Quality Control of Live-Attenuated Polio Vaccines

BACKGROUND

Next-generation sequencing (NGS) analysis was compared to the current MAPREC (mutational analysis by polymerase chain reaction and restriction enzyme cleavage) assay for quality control of live-attenuated oral polio vaccine (OPV).

METHODS

MAPREC measures reversion of the main OPV attenuating mutations such as uracil (U) to cytosine (C) at nucleotide 472 in the 5' noncoding region of type 3 OPV. Eleven type 3 OPV samples were analyzed by 8 laboratories using their in-house NGS method.

RESULTS

Intraassay, intralaboratory, and interlaboratory variability of NGS 472-C estimates across samples and laboratories were very low, leading to excellent agreement between laboratories. A high degree of correlation between %472-C results by MAPREC and NGS was observed in all laboratories (Pearson correlation coefficient r = 0.996). NGS estimates of sequences at nucleotide 2493 with known polymorphism among type 3 OPV lots also produced low assay variability and excellent between-laboratory agreement.

CONCLUSIONS

The high consistency of NGS data demonstrates that NGS analysis can be used as high-resolution test alternative to MAPREC, producing whole-genome profiles to evaluate OPV production consistency, possibly eliminating the need for tests in animals. This would be very beneficial for the quality assessment of next-generation polio vaccines and, eventually, for other live-attenuated viral vaccines.

The polio-eradication programme and issues of the end game

Poliovirus causes paralytic poliomyelitis, an ancient disease of humans that became a major public-health issue in the 20th century. The primary site of infection is the gut, where virus replication is entirely harmless; the two very effective vaccines developed in the 1950s (oral polio vaccine, or OPV, and inactivated polio vaccine, or IPV) induce humoral immunity, which prevents viraemic spread and disease. The success of vaccination in middle-income and developing countries encouraged the World Health Organization to commit itself to an eradication programme, which has made great advances. The features of the infection, including its largely silent nature and the ability of the live vaccine (OPV) to evolve and change in vaccine recipients and their contacts, make eradication particularly challenging. Understanding the pathogenesis and virology of the infection is of major significance as the programme reaches its conclusion.

Neonatal rhesus monkey is a potential animal model for studying pathogenesis of EV71 infection

Data from limited autopsies of human patients demonstrate that pathological changes in EV71-infected fatal cases are principally characterized by clear inflammatory lesions in different parts of the CNS; nearly identical changes were found in murine, cynomolgus and rhesus monkey studies which provide evidence of using animal models to investigate the mechanisms of EV71 pathogenesis. Our work uses neonatal rhesus monkeys to investigate a possible model of EV71 pathogenesis and concludes that this model could be applied to provide objective indicators which include clinical manifestations, virus dynamic distribution and pathological changes for observation and evaluation in interpreting the complete process of EV71 infection. This induced systemic infection and other collected indicators in neonatal monkeys could be repeated; the transmission appears to involve infecting new monkeys by contact with feces of infected animals. All data presented suggest that the neonatal rhesus monkey model could shed light on EV71 infection process and pathogenesis.

Massively parallel sequencing for monitoring genetic consistency and quality control of live viral vaccines

Intrinsic genetic instability of RNA viruses may lead to the accumulation of revertants during manufacture of live viral vaccines, requiring rigorous quality control to ensure vaccine safety. Each lot of oral poliovirus vaccine (OPV) is tested for neurovirulence in animals and also for the presence of neurovirulent revertants. Mutant analysis by PCR and restriction enzyme cleavage (MAPREC) is used to measure the frequency of neurovirulent mutations at the 5' untranslated region (UTR) of the viral genome that correlate with the level of neurovirulence determined by the monkey neurovirulence test. However, MAPREC can only monitor mutations at a few genomic loci and miss mutations at other sites that could adversely affect vaccine quality. Here we propose to use massively parallel sequencing (MPS) for sensitive detection and quantification of all mutations in the entire genome of attenuated viruses. Analysis of vaccine samples and reference preparations demonstrated a perfect agreement with MAPREC results. Quantitative MPS analysis of validated reference preparations tested by MAPREC produced identical results, suggesting that the method could take advantage of the existing reference materials and be used as a replacement for the MAPREC procedure in lot release of OPV. Patterns of mutations present at a low level in vaccine preparations were characteristic of seed viruses used for their manufacture and could be used for identification of individual batches. This approach may represent the ultimate tool for monitoring genetic consistency of live viral vaccines.

Basic concept of development and practical application of animal models for human diseases

The "humanized mouse" is a mouse harboring functioning human tissues used as in vivo human models for both physiological and pathological conditions. The NOD/Shi-scid IL2rgamma(null) (NOG) mouse, an excellent immunodeficient mouse used as the basis for the humanized mouse, requires strict genetic and environmental control for production and use in experiments. Genetic control using marker-assisted selection is described. In addition, NOG mice are easily affected by microbiological and proximate environmental factors, which can cause severe damage to the mice in some cases. Therefore, rigorous microbiological and environmental controls are necessary to ensure reproducibility of experimental results. At the end of this chapter, future aspects of the application of "humanized mice" based on novel super-immunodeficient mice such as NOG mice and Rag2(null) IL2rgamma(null) mice in biomedical research and testing are briefly reviewed.

Oncolytic viruses in cancer therapy

Oncolytic virotherapy is a promising form of gene therapy for cancer, employing nature’s own agents to find and destroy malignant cells. The purpose of this review is to provide an introduction to this very topical field of research and to point out some of the current observations, insights and ideas circulating in the literature. We have strived to acknowledge as many different oncolytic viruses as possible to give a broader picture of targeting cancer using viruses. Some of the newest additions to the panel of oncolytic viruses include the avian adenovirus, foamy virus, myxoma virus, yaba-like disease virus, echovirus type 1, bovine herpesvirus 4, Saimiri virus, feline panleukopenia virus, Sendai virus and the non-human coronaviruses. Although promising, virotherapy still faces many obstacles that need to be addressed, including the emergence of virus-resistant tumor cells.

A poliomyelitis model through mucosal infection in transgenic mice bearing human poliovirus receptor, TgPVR21

Transgenic mice bearing the human poliovirus receptor (TgPVR) are less susceptible to oral inoculation, although they are susceptible to parenteral inoculation. We investigated the susceptibility of TgPVR 21 line [Arch. Virol. 130 (1994) 351] to poliovirus through various mucosal routes. Intranasal inoculation of a neurovirulent Mahoney strain (OM1) caused flaccid paralysis with viral replication in the central nervous system at a dose of 10(6) cell culture infectious dose (CCID50), in contrast, no paralysis following oral or intragastric inoculation of the same dose. Intranasal inoculation of a vaccine strain, Sabin 1, at 10(6) CCID50, resulted in no paralysis. Initial replication of poliovirus in the nasal cavity was confirmed by virus isolation and detection of negative-stranded replicative intermediates by RT-PCR and viral antigens using a high-sensitive immunohistochemistry and genome/transcripts by in situ hybridization. Poliovirus-specific IgG antibodies were elevated in the sera of surviving TgPVR21. This model can be used as a mucosal infection model and for differentiation of neurovirulent and attenuated poliovirus strains.

Comparison of neuropathogenicity of poliovirus type 3 in transgenic mice bearing the poliovirus receptor gene and cynomolgus monkeys

To clarify the similarities of poliovirus infection in cynomolgus monkeys and transgenic mice bearing the poliovirus receptor, TgPVR21, we compared the pathological changes of these animals following intraspinal inoculation of two strains of poliovirus type 3 using immunohistochemical detection of the capsid antigen. All of the monkeys inoculated with 10(6) TCID(50) viruses showed flaccid paralysis 2 or 3 days post-inoculation (p.i.). TgPVR21 mice showed paralysis starting from 2 to 3 days p.i. Histologically, neurons having pyknotic nuclei and eosinophilic cytoplasm and neuronophagia were characteristically observed in both animals, but central chromatolysis was not observed in infected TgPVR21. The median lesion scores in the monkeys and TgPVR21 were well correlated, though the distribution of poliovirus-infected lesions in the central nervous system was different. In both animals the motor neurons and the brainstem nuclei responsible for flaccid paralysis were infected by the virus, while the cerebral cortex and thalamus were infected in the monkeys but not in TgPVR21. These results confirmed the reliability of neurovirulence tests using TgPVR21 as a substitute for monkeys, in respect to the spinal and brainstem lesions of poliovirus type 3.

Analysis of the accumulation of mutants in Sabin attenuated polio vaccine viruses passaged in Vero cells

To confirm the safety of oral poliomyelitis vaccine (OPV) cultured in Vero cells, the genetic stability of cultured polio vaccine viruses was analysed by MAPREC (mutant analysis by PCR and restriction enzyme cleavage). The rates of mutant accumulation of the viruses passaged in Vero cells under a low multiplicity of infection (MOI) condition (approximately 10(-3.5)CCID50/cell; the same as under usual OPV production conditions) were higher than those passaged in secondary cultured monkey kidney cells. However, the rates of mutant accumulation were restrained when the viruses were cultured under a high MOI condition (approximately 10(-1.5)CCID50/cell) in Vero cells. Furthermore, neurovirulence of the passaged viruses in pollovirus susceptible transgenic mice PVR-Tg21 was shown to correlate highly with the results of MAPREC. It is expected that our results will contribute to the large scale preparation of safe and effective OPV using Vero cells.

Characterisation of vaccine-derived polioviruses isolated from sewage and river water in Japan

BACKGROUND

A nucleotide change from U to C at position 472 in the 5' non-coding region of the type 3 poliovirus is associated with increased neurovirulence. Moreover, the proportion of type 3 polioviruses containing this mutation (472-C revertants) correlates with the neurovirulence of a particular sample. We used mutant analysis by PCR and restriction-enzyme cleavage (MAPREC) to estimate the neurovirulence of environmental samples obtained from Toyama prefecture, Japan.

METHODS

Sewage and river water were collected between October, 1993, and September, 1995, and concentrated samples were inoculated into three different cell types. Isolated type 3 viruses were analysed to determine whether they were derived from the live oral poliovirus vaccine strain; they were then tested for neurovirulence by MAPREC.

RESULTS

29 type 3 strains were isolated--all of which were vaccine-derived. 16 (55%) comprised between 2% and 91% 472-C revertants by MAPREC and were expected to have high neurovirulence. The remaining strains included less than 0.25% revertants, and were regarded as attenuated viruses. Both types were isolated about 3 months after routine oral poliovirus vaccine administrations in May and October. Three strains isolated from river water were of the virulent type.

INTERPRETATION

Our results emphasise that there is an environmental risk of vaccine-associated paralytic poliomyelitis as long as live oral poliovirus vaccine is not replaced by inactivated polio vaccine.

Development of a transgenic mouse neurovirulence test for oral poliovirus vaccine: international collaborative study 1993-1999

The neurovirulence safety of oral live poliovirus vaccine (OPV) has been tested in monkeys, because only primates are sensitive to all three types of poliovirus. The genetic engineering of transgenic mice susceptible to poliovirus led to studies on the suitability of these mice for a neurovirulence test of OPV. A WHO international collaborative study started with type-3 OPV in 1993 and was completed in 1999. The study produced a voluminous set of data proving that the TgPVR21 mice, inoculated with OPV samples into the lumbar cord, provided a test for neurovirulence of OPV as sensitive and reproducible as the monkey test. A statistical decision model for acceptance/rejection of type-3 vaccines using the transgenic mouse test has been developed. The mouse neurovirulence test showed a number of essential advantages over the monkey test. This is the first example of a successful introduction of transgenic animals into control of biologicals. In October 1999, the WHO Expert Committee on Biological Standardization approved TgPVR21 mice as alternative to the monkey model for neurovirulence testing of OPV type 3. A final step of the collaborative study with OPV types 1 and 2 is in progress, and data obtained so far are promising. Two breeding stations for production of TgPVR21 mice are being established in Asia and Europe.

Reevaluation of nucleotide sequences of wild-type and attenuated polioviruses of type 3

Published sequences of wild-type and attenuated Sabin strains of type 3 poliovirus (Leon/37 and Leon 12a(1)b) were derived from cDNA clones. Recent direct sequencing of Sabin 3 RNA showed that it differed from the published sequence in at least two sites. Here results of direct sequencing of genomes of three independently re-derived sub-strains of attenuated Sabin 3 poliovirus used for oral poliovirus vaccine (OPV) production in addition to the most widely used Pfizer sub-strain are reported. The results showed that all four sub-strains of attenuated type 3 poliovirus contain unique patterns of mutations. Two stocks of the wild-type progenitor Leon/37 strain were also sequenced. Analysis of the two samples of Leon/37 virus showed that one of them is much closer to the Sabin 3 strain, and is an intermediate product of the attenuation process. In addition, we created genetically engineered constructs which contained some of the mutations suspected for their possible role in neurovirulence, and tested them in monkeys and in transgenic mice sensitive to poliovirus. The results suggested that none of them increased neurovirulence of the virus, but some may improve virus replication. Therefore the only mutation occurring in Sabin 3 under vaccine production conditions that appears to affect neurovirulence of the virus is the well known U-->C reversion at nucleotide 472.

Detection of mutants in polio vaccine viruses using pooled antipoliovirus monoclonal antibodies

We prepared six monoclonal antibodies (mAbs) for type 1 polioviruses, and analysed their neutralizing specificities for use in safety tests in oral poliomyelitis vaccine (OPV) production. Pools of two or more individual mAbs showed high neutralizing activity against high-titre (approximately 10(7) CCID (50)/25 microl) of Sabin type 1 virus. It was demonstrated that the pooled mAbs can be utilized effectively in detection tests of adventitious viruses, which are among the safety tests in OPV production. Moreover, some pooled mAbs were shown to be capable of detecting very small amounts of type 1 virulent viruses and mutants in high-titre Sabin type 1 virus suspensions. Neutralizing antibody titres of these pooled mAbs decreased with increasing numbers of mutants containing neurovirulent activity in high-titre Sabin type 1 viruses which were repeatedly passaged in culture. It is expected that these pooled mAbs will contribute greatly to safety tests for OPV production.

Mutations in Sabin 2 strain of poliovirus and stability of attenuation phenotype

In this study, we attempted to identify the molecular determinants in the genome of the attenuated Sabin 2 vaccine strain of poliovirus that may change during vaccine production and result in an increase in monkey neurovirulence. An extensive search for suitable vaccine lots identified six batches that had failed the monkey neurovirulence test (MNVT). On repeated tests, these batches were found to have acceptable levels of monkey neurovirulence. One of the batches was additionally passaged six times under conditions used in vaccine production, and the resulting high-passage sample was screened for the presence of mutations and tested in monkeys. In addition to the previously described A --> G reversion at nucleotide 481, high-passage stock also contained a mutation in the VP1-coding region (3364 = G --> A) that consistently accumulated in the course of passaging. However, despite the presence of substantial amounts of these mutations, high-passage stock passed the MNVT. Replication of Sabin 2 poliovirus in the central nervous system of transgenic mice susceptible to poliovirus or in cultures of mouse cells, resulted in another mutation (3363 = A --> G). Even though its presence correlated with paralysis in mice, the introduction of 3363-G into the Sabin 2 genome did not increase neurovirulence of the virus. Previous studies identified the 481-G mutation as an important determinant of monkey neurovirulence. We prepared virus samples with varying amounts of genetically defined single mutants at this nucleotide and tested them in monkeys. The results demonstrated that even a 100% substitution at this site introduced into Sabin 2 strain did not increase monkey neurovirulence. The determination of the nucleotide sequence of an alternative strain used for the production of type 2 OPV (Chung 2) showed that it contained 100% of the wild-type 481-G but possessed an extremely low level of neurovirulence. These results demonstrate the remarkable stability of the attenuated phenotype of the Sabin 2 strain and show that (1) no batch of OPV 2 has ever repeatedly failed the MNVT, (2) growing the virus beyond the passage level allowed in vaccine production did not result in increased neurovirulence in monkeys, (3) a test for neurovirulence in transgenic mice may be more sensitive than the MNVT, and (4) determination of the mutational profile of vaccine batches detects inconsistencies in vaccine manufacturing processing that would not be detected by the MNVT.

Poliomyelitis in intraspinally inoculated poliovirus receptor transgenic mice

Mice transgenic with the human poliovirus receptor gene develop clinical signs and neuropathology similar to those of human poliomyelitis when neurovirulent polioviruses are inoculated into the central nervous system (CNS). Factors contributing to disease severity and the frequencies of paralysis and mortality include the poliovirus strain, dose, and gender of the mouse inoculated. The more neurovirulent the virus, as defined by monkey challenge results, the higher the rate of paralysis, mortality, and severity of disease. Also, the time to disease onset is shorter for more neurovirulent viruses. Male mice are more susceptible to polioviruses than females. TGM-PRG-3 mice have a 10-fold higher transgene copy number and produce 3-fold more receptor RNA and protein levels in the CNS than TGM-PRG-1 mice. CNS inoculations with type III polioviruses differing in relative neurovirulence show that these mouse lines are similar in disease frequency and severity, demonstrating that differences in receptor gene dosage and concomitant receptor abundance do not affect susceptibility to infection. However, there is a difference in the rate of accumulation of clinical signs. The time to onset of disease is shorter for TGM-PRG-3 than TGM-PRG-1 mice. Thus, receptor dosage affects the rate of appearance of poliomyelitis in these mice.

Characterization of mouse lines transgenic with the human poliovirus receptor gene

Two mouse lines transgenic with the human poliovirus receptor gene (PVR), TGM-PRG-1 and TGM-PRG-3, were characterized to determine whether transgene copy number and PVR expression levels influence susceptibility to poliovirus. The mouse lines have been bred for more than 10 generations and the transgene was stably transmitted to progeny as determined by Southern blot hybridization and restriction fragment length polymorphism. The transgene copy number is 10 in the TGM-PRG-3 mouse line and one in the TGM-PRG-1 mouse line. Abundance of PVR RNA is on average three-fold higher in TGM-PRG-3 relative to TGM-PRG-1 tissues, and the abundance of the receptor molecule is three-fold higher in TGM-PRG-3 central nervous system tissues compared to TGM-PRG-1 tissues as determined by Western blot analysis. When TGM-PRG-1 and TGM-PRG-3 mice were inoculated intracranially with a neurovirulent type III poliovirus strain, they developed clinical symptoms and CNS lesions characteristic of human poliomyelitis. These results indicate that the PVR gene is expressed as a functional receptor in the CNS of both mouse lines rendering the mice susceptible to poliovirus infection. Even though the two mouse lines have different copy numbers of the transgene and different levels of PVR RNA and protein, they are similar in their susceptibility to poliovirus.

Rare adverse events associated with oral poliovirus vaccine in Brazil

Oral poliovirus vaccine (OPV) developed by A. Sabin has been effectively used to control poliomyelitis in Brazil, and the last case with the isolation of a wild poliovirus strain occurred in March 1989. Although the vaccine controlled the circulation of wild strains and poliomyelitis cases associated with these strains were not detected during the last eight years, rare cases classified as vaccine-associated paralytic poliomyelitis (VAPP) have been detected. Molecular characterization studies of poliovirus strains isolated from VAPP cases and from healthy contacts have confirmed that the isolates are derived from the Sabin vaccine strains and also detected genomic modifications known or suspected to increase neurovirulence such as mutations and recombination. The molecular characterization of polioviruses isolated during the last eight years from paralysis cases classified as Guillain-Barré (GBS) syndrome and transverse myelitis (TM), and from facial paralysis (FP) cases also confirmed the vaccine origin of the strains and demonstrated mutations known to increase neurovirulence. Analysis of the epidemiologic data of these GBS, TM and FP cases demonstrated that in most of them the last OPV dose was given months or years before the onset of the disease and the isolation of the polioviruses. The temporal association between the isolation of these strains and the GBS, TM and FP suggested that the Sabin vaccine-derived poliovirus strains could also rarely trigger the diseases.