A single amino acid substitution in the envelope protein of chimeric yellow fever-dengue 1 vaccine virus reduces neurovirulence for suckling mice and viremia/viscerotropism for monkeys.

A chimeric yellow fever-dengue 1 (ChimeriVax-DEN1) virus was produced by the transfection of Vero cells with chimeric in vitro RNA transcripts. The cell culture supernatant was subjected to plaque purification for the identification of a vaccine candidate without mutations. Of 10 plaque-purified clones, 1 containing no mutation (clone J) was selected for production of the vaccine virus. During subsequent cell culture passaging of this clone for vaccine production, a single amino acid substitution (K to R) occurred in the envelope (E) protein at residue 204 (E204) (F. Guirakhoo, K. Pugachev, Z. Zhang, G. Myers, I. Levenbook, K. Draper, J. Lang, S. Ocran, F. Mitchell, M. Parsons, N. Brown, S. Brandler, C. Fournier, B. Barrere, F. Rizvi, A. Travassos, R. Nichols, D. Trent, and T. Monath, J. Virol. 78:4761-4775, 2004). The same mutation was observed in another clone (clone E). This mutation attenuated the virus in 4-day-old suckling mice inoculated by the intracerebral (i.c.) route and led to reduced viremia in monkeys inoculated by the subcutaneous or i.c. route. The histopathology scores of lesions in the brain tissue of monkeys inoculated with either the E204K or E204R virus were reduced compared to those for monkeys inoculated with the reference virus, a commercial yellow fever 17D vaccine (YF-VAX). Both viruses grew to significantly lower titers than YF-VAX in HepG2, a human hepatoma cell line. After intrathoracic inoculation into mosquitoes, both viruses grew to a similar level as YF-VAX, which was significantly lower than that of their wild-type DEN1 parent virus. A comparison of the E-protein structures of nonmutant and mutant viruses suggested the appearance of new intramolecular bonds between residues 204R, 261H, and 257E in the mutant virus. These changes may be responsible for virus attenuation through a change in the pH threshold for virus envelope fusion with the host cell membrane.

Safety and efficacy of chimeric yellow Fever-dengue virus tetravalent vaccine formulations in nonhuman primates.

To construct chimeric YF/DEN viruses (ChimeriVax-DEN), the premembrane (prM) and envelope (E) genes of yellow fever (YF) 17D virus were replaced with those of each wild-type (WT) dengue (DEN) virus representing serotypes 1 to 4. ChimeriVax-DEN1-4 vaccine viruses were prepared by electroporation of Vero cells with RNA transcripts prepared from viral cDNA (F. Guirakhoo, J. Arroyo, K. V. Pugachev, C. Miller, Z.-X. Zhang, R. Weltzin, K. Georgakopoulos, J. Catalan, S. Ocran, K. Soike, M. Ratteree, and T. P. Monath, J. Virol. 75:7290-7304, 2001; F. Guirakhoo, K. Pugachev, J. Arroyo, C. Miller, Z.-X. Zhang, R. Weltzin, K. Georgakopoulos, J. Catalan, S. Ocran, K. Draper, and T. P. Monath, Virology 298:146-159, 2002). Progeny viruses were subjected to three rounds of plaque purifications to produce the Pre-Master Seed viruses at passage 7 (P7). Three further passages were carried out using U.S. current Good Manufacturing Practices (cGMP) to produce the Vaccine Lot (P10) viruses. Preclinical studies demonstrated that the vaccine candidates are replication competent and genetically stable and do not become more neurovirulent upon 20 passages in Vero cells. The safety of a tetravalent vaccine was determined and compared to that of YF-VAX in a formal monkey neurovirulence test. Brain lesions produced by the tetravalent ChimeriVax-DEN vaccine were significantly less severe than those observed with YF-VAX. The immunogenicity and protective efficacy of four different tetravalent formulations were evaluated in cynomolgus monkeys following a single-dose subcutaneous vaccination followed by a virulent virus challenge 6 months later. All monkeys developed low levels of viremia postimmunization, and all the monkeys that had received equal concentrations of either a high-dose (5,5,5,5) or a low-dose (3,3,3,3) formulation seroconverted against all four DEN virus serotypes. Twenty-two (92%) of 24 monkeys were protected as determined by lack of viremia post-challenge. This report is the first to demonstrate the safety of a recombinant DEN virus tetravalent vaccine in a formal neurovirulence test, as well as its protective efficacy in a monkey challenge model.

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.

Chimeric yellow fever virus 17D-Japanese encephalitis virus vaccine: dose-response effectiveness and extended safety testing in rhesus monkeys.

ChimeriVax-JE is a live, attenuated recombinant virus prepared by replacing the genes encoding two structural proteins (prM and E) of yellow fever 17D virus with the corresponding genes of an attenuated strain of Japanese encephalitis virus (JE), SA14-14-2 (T. J. Chambers et al., J. Virol. 73:3095-3101, 1999). Since the prM and E proteins contain antigens conferring protective humoral and cellular immunity, the immune response to vaccination is directed principally at JE. The prM-E genome sequence of the ChimeriVax-JE in diploid fetal rhesus lung cells (FRhL, a substrate acceptable for human vaccines) was identical to that of JE SA14-14-2 vaccine and differed from sequences of virulent wild-type strains (SA14 and Nakayama) at six amino acid residues in the envelope gene (E107, E138, E176, E279, E315, and E439). ChimeriVax-JE was fully attenuated for weaned mice inoculated by the intracerebral (i.c.) route, whereas commercial yellow fever 17D vaccine (YF-Vax) caused lethal encephalitis with a 50% lethal dose of 1.67 log(10) PFU. Groups of four rhesus monkeys were inoculated by the subcutaneous route with 2.0, 3.0, 4.0, and 5. 0 log(10) PFU of ChimeriVax-JE. All 16 monkeys developed low viremias (mean peak viremia, 1.7 to 2.1 log(10) PFU/ml; mean duration, 1.8 to 2.3 days). Neutralizing antibodies appeared between days 6 and 10; by day 30, neutralizing antibody responses were similar across dose groups. Neutralizing antibody titers to the homologous (vaccine) strain were higher than to the heterologous wild-type JE strains. All immunized monkeys and sham-immunized controls were challenged i.c. on day 54 with 5.2 log(10) PFU of wild-type JE. None of the immunized monkeys developed viremia or illness and had mild residual brain lesions, whereas controls developed viremia, clinical encephalitis, and severe histopathologic lesions. Immunized monkeys developed significant (>/=4-fold) increases in serum and cerebrospinal fluid neutralizing antibodies after i.c. challenge. In a standardized test for neurovirulence, ChimeriVax-JE and YF-Vax were compared in groups of 10 monkeys inoculated i.c. and analyzed histopathologically on day 30. Lesion scores in brains and spinal cord were significantly higher for monkeys inoculated with YF-Vax. ChimeriVax-JE meets preclinical safety and efficacy requirements for a human vaccine; it appears safer than yellow fever 17D vaccine but has a similar profile of immunogenicity and protective efficacy.

Recombinant, chimaeric live, attenuated vaccine (ChimeriVax) incorporating the envelope genes of Japanese encephalitis (SA14-14-2) virus and the capsid and nonstructural genes of yellow fever (17D) virus is safe, immunogenic and protective in non-human primates.

Yellow fever 17D virus, a safe and effective live, attenuated vaccine, was used as a vector for genes encoding the protective antigenic determinants of a heterologous member of the genus Flavivirus, Japanese encephalitis (JE) virus, the leading cause of acute viral central nervous system infection and death throughout Asia. The viral envelope (prM and E) genes of a full-length cDNA clone of YF 17D virus were replaced with the corresponding genes of JE SA14-14-2, a strain licensed as a live, attenuated vaccine in China. Full-length RNA transcripts of the YF/JE chimaera were used to transfect Vero cells. The progeny virus (named 'ChimeriVax-JE'), was used to define safety after intracerebral (i.c.) inoculation of rhesus monkeys. Monkeys (N = 3) inoculated with a high dose (6.6 log10 pfu) developed a brief viremia, showed no signs of illness, developed high titers of anti-JE neutralizing antibody, and had minimal brain and spinal cord lesion scores according to criteria specified in the WHO monkey neurovirulence test. A control group of 3 monkeys that received a lower dose (4.2 log10 pfu) of commercial YF 17D vaccine had slightly higher lesion scores. To develop a lethal monkey model of JE for vaccine protection tests, we inoculated groups of monkeys i.c. or intranasally (i.n.) with a JE virus strain found to be highly neurovirulent and neuroinvasive for mice. Monkeys inoculated i.c., but not i.n., developed severe encephalitis after an incubation period of 8-13 days. The ChimeriVax-JE virus was passed in a cell line acceptable for human use (diploid fetal rhesus lung) and 4.3 or 5.3 log10 pfu were inoculated into groups of 3 monkeys by the subcutaneous route. All 6 animals developed brief viremias (peak titer < 2.0 log10 pfu/ml) and subsequently had anti-JE but no yellow fever neutralizing antibodies. On day 64, the monkeys were challenged i.c. with 5.5 log10 pfu of virulent JE virus. The immunized animals had no detectable viremia post-challenge, whereas 4 unimmunized controls became viremic. Only 1 of 6 (17%) vaccinated monkeys but 4 of 4 (100%) unvaccinated controls developed encephalitis. Histopathological examination 30 days after challenge confirmed that the protected, immunized animals had no or minimal evidence of encephalitis. These data demonstrated the ability of the ChimeriVax-JE to induce a rapid humoral immune response and to protect against a very severe, direct intracerebral virus challenge. Target areas of neuronal damage and inflammation in monkeys infected IC with wild-type JE, the chimaeric virus and YF 17D were similar, indicating that the histopathological scoring system used for the WHO yellow fever monkey neurovirulence test will be applicable to control testing of chimaeric seed viruses and vaccines.

New assays for the quality control of live oral poliovirus vaccine.

The strains of all three types of poliovirus used in the production of live oral poliomyelitis vaccine have been shown to yield vaccines that are both immunogenic and highly attenuated when administered orally to susceptible children and adults. Experience obtained for close to four decades with the vaccines prepared from these strains indicates that laboratory and animal tests described in the World Health Organization's (WHO) Requirements for Poliomyelitis Vaccines (Oral) do ensure the consistency of virus characteristics during vaccine production. Major advances in our understanding of the molecular basis of attenuation and reversion of polioviruses resulted in the development of a new generation of tests. These include an alternative in vivo neurovirulence test in transgenic mice that express the human poliovirus receptor and a new in vitro assay (mutant analysis by polymerase chain reaction and restriction enzyme cleavage, shortly MAPREC) that assess the consistency of vaccine production at a molecular level. A WHO collaborative study was initiated in 1993 with the objective of assessing transgenic mice as potential models for evaluation of the neurovirulence of type 3 vaccines. The results of the study showed that there is a very good correlation between the TgPVR21 mouse assay and the monkey neurovirulence test. Further studies are in progress to develop a statistical model for making regulatory decisions on accepting or rejecting batches of type 3 vaccine. A WHO collaborative study was initiated in 1991 to evaluate the MAPREC assay for type 3 vaccines. The results of this study showed that the MAPREC test was a sensitive, robust and standardized molecular assay suitable for process development for new manufacturers and for monitoring the consistency of existing vaccine production. Screening single virus harvests with MAPREC before pooling them into monovalent bulk vaccine will also improve the quality of the final product.

TgPVR21 mice for testing type-3 oral poliovirus vaccines: role of clinical observation and histological examination.

Transgenic mice susceptible to poliovirus (TgPVR mice) have been used to study poliovirus neurovirulence and attenuation. It was shown recently that mouse line TgPVR21 may be a suitable model to evaluate neurovirulence safety of oral poliovirus vaccine. It was important to determine whether TgPVR21 mice are sensitive enough to discriminate between type-3 reference and 'marginal' vaccines, i.e. those that failed the monkey test while containing only slightly increased amounts of neurovirulent revertants at position 472 of the viral genome as measured by a molecular assay MAPREC. Data presented here demonstrate that TgPVR21 mice are not less sensitive than monkeys in the detection of marginal vaccines. In contrast to the monkey neurovirulence test, which is based on histological examination of the CNS, the TgPVR21 mouse neurovirulence test revealed marginal vaccines by simple analysis of clinical signs without requiring a laborious histological examination.

Development of a neurovirulent testing system for oral poliovirus vaccine with transgenic mice.

Because only primates are susceptible to polioviruses, the neurovirulent safety and consistency of oral poliovirus vaccine (OPV) were assayed in the monkey neurovirulence test. After the development of transgenic (Tg) mice carrying the gene for human poliovirus receptor (PVR), the suitability of these mice to replace monkeys for OPV testing was evaluated. Two lines of Tg mice, TgPVR1 and TgPVR21, were tested. The TgPVR21 mice, inoculated in the spinal cord, were as sensitive as monkeys in discriminating between type-3 and type-2 OPV lots that had passed and those that had failed the monkey neurovirulence test. Results of the new molecular assay by polymerase chain reaction and restriction enzyme cleavage indicated that each OPV lot contained minuscule amounts of neurovirulent revertants in the viral genome. All type-3 OPV lots that failed the monkey neurovirulence test had higher percentages of 472-C revertants than did lots that passed this test. Analysis of multiple type-3 OPV lots also indicated a good correlation between the contents of 472-C revertants and results of the TgPVR21 mouse test. An overview of a significant set of data suggests that the TgPVR21 mouse model is suitable for the evaluation of type-3 and type-2 OPV. The necessity of the TgPVR mouse test for the neurovirulence of type-1 OPV, which is the most stable of the three Sabin strains, is under consideration.

Inactivated poliovirus vaccine protects transgenic poliovirus receptor mice against type 3 poliovirus challenge.

Transgenic (Tg) mice expressing the human poliovirus receptor (PVR) were vaccinated with inactivated poliovirus vaccine (IPV) and evaluated for induced immunity against type 3 poliomyelitis. One injection of monovalent type 3 IPV elicited protective immunity against wild-type poliovirus. In contrast, 2 injections of trivalent IPV were required for protection. Neutralizing antibody response and protection were vaccine dose-dependent. Administration of polio-immune mouse plasma protected unimmunized mice, demonstrating that neutralizing antibody was sufficient for immunity. IPV heated to remove its D antigen component did not induce protection in Tg PVR mice. IPV derived from a wild-type poliovirus strain gave better protection against wild-type viral challenge than IPV derived from an attenuated poliovirus strain. The newly developed Tg PVR mouse-protection test may be useful in evaluating existing IPV potency tests and for attempts to improve formulations of trivalent IPV or combined vaccines for childhood immunization schedules.

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

Two poliovirus-susceptible transgenic mouse (Tg PVR) strains, Tg1 and Tg21, were compared with the monkey test for their sensitivity to neurovirulence of live oral poliovirus vaccine (OPV). Intracerebral (i.c.) and intraspinal (i.s.) routes of inoculation were investigated to determine the most suitable combination of mouse strain and route. Evaluation of the mouse tests was performed using several indicators; clinical score and failure time were selected as the most efficient. Tg1 and Tg21 mice inoculated i.s. with type 2, and Tg21 mice inoculated i.s. with type 3 OPV were determined to be the most appropriate systems, whereas they are shown not to be suitable for type 1 OPV. The sensitivity of each of the two mouse models was at least equal to that of the monkey test, suggesting that these mouse systems might be considered as a potential replacement for the monkey test of OPV. However, more data are needed to establish regulatory criteria of acceptability for vaccine lots tested in Tg PVR mice. This is the first study conducted with Tg PVR mice with all three types of poliovirus vaccine preparations.

Succession of mutations in the Sabin strain of type 3 poliovirus replicating in the central nervous system of monkeys.

Sabin strains of oral poliovirus vaccine (OPV) undergo limited genetic changes during replication in cell cultures, the gastrointestinal tract of vaccinees, and the central nervous system of monkeys. Some of these changes are associated with loss of attenuation markers. Here we report the dynamics of mutant accumulation in the Sabin strain of poliovirus type 3 inoculated intraspinally into monkeys. Thr --> lle reversion in amino acid 6 of VP1 (2493 C --> U) occurred within the first few days postinoculation (p.i.), but decreased on later days and completely disappeared by Day 17 p.i. 472 U --> C reversion in the 5'-untranslated region appeared to accumulate slower and by Day 17 completely substituted for the vaccine-type nucleotide at this site. These results indicate that experimental infection of the central nervous system of monkeys consists of early and late phases in which a different genetic constitution of the virus is favored. In several isolates one additional neurovirulent revertant was found: a Phe --> Ser at amino acid 91 of VP3 (2034 U --> C). Since this mutation was never detected in vaccine lots and is strongly selected against in cell cultures at temperatures below 38.5 degrees, it does not threaten the safety of OPV.

Effects of gamma-IFN and NGF on subpopulations in a human neuroblastoma cell line: flow cytometric and morphological analysis.

Neuroblastomas are neural crest-derived tumors that contain neuronal, melanocyte, and Schwann cell precursors. We examined the effects of treatment with gamma-interferon (gamma-IFN) and nerve growth factor (NGF), alone, and in combination, on these progenitor subpopulations in the human neuroblastoma cell line, SH-SY5Y. Using fluorescence-activated flow cytometry (FACS), changes in expression of three differentiation-specific or -associated marker proteins, the 200 kD neurofilament protein, the myelin basic protein, and the S-100 protein, were analyzed. Growth rates and morphological changes associated with each treatment over the 2-wk incubation period were noted. The greatest effects were observed with combined IFN + NGF treatment. These were significant increases in expression of all three proteins, distinctive morphological signs of differentiation, and extensive inhibition of proliferation compared to control cultures. Treatment with NGF alone resulted in increased neurofilament protein expression and in the length and number of neurite extensions, but there was no effect on the growth rate. IFN induced striking morphological changes, significant inhibition of growth, and changes in protein expression that correlated with neuronal to non-neuronal subpopulation shifts due to the death of differentiated cells. When treatment was discontinued after 15 d, the morphological changes induced by NGF were reversed within 2-3 d, while those induced by IFN +/- NGF were present up to 4 wk post-treatment. Small, neuroblastic colonies were observed throughout the treatment period and within 4-6 wk after the cessation of treatment this cell-type fully reconstituted the cultures suggesting the presence of a stem cell. Our results indicate that treatment with gamma-IFN +/- NGF can regulate growth and induce, either stem cells or progenitor neuronal, Schwann and melanocyte subpopulations in the SH-SY5Y cell line to irreversibly differentiate.

Limited genetic changes in the Sabin 1 strain of poliovirus occurring in the central nervous system of monkeys.

Replication of attenuated poliovirus strains results in their partial deattenuation. Recently we identified mutations accumulating in the Sabin 1 poliovirus in cell cultures. Here we report genetic changes occurring in this virus during replication in the central nervous system (CNS) of monkeys. Viruses isolated from different parts of the CNS of rhesus monkeys (inoculated into the spinal cord) were screened for sequence heterogeneities and newly identified mutations were independently confirmed and quantified using mutant analysis by PCR and restriction enzyme cleavage (MAPREC). All consistently accumulating mutations identified in this study were located in untranslated regions: GU-->AU or GU-->GC substitution at a complementary pair formed by nucleotides 480 and 525, U-->C substitution at nucleotide 612, and GU-->AU or GU-->GC substitution of a base pair formed by the nucleotides 7427/7441 immediately preceding the poly(A) tract. All these mutations except one (7427) were previously identified in cell culture passages or stool isolates from vaccinees. Sequencing of 11 CNS isolates also identified a few random silent mutations that accumulated as neutral 'passengers', passively co-selected with genuinely selectable mutations present on the same RNA molecule. One isolate also contained the wild-type base at nucleotide 2741 (Ala88-->Thr in VP1). Our results demonstrate a remarkable genetic stability of the Sabin 1 poliovirus in the CNS of monkeys, suggesting that deattenuation is determined by a very limited number of mutations. These mutations can be assayed by MAPREC to monitor the consistency of oral poliovirus vaccine (OPV) production.

Microevolution of type 3 Sabin strain of poliovirus in cell cultures and its implications for oral poliovirus vaccine quality control.

Screening for sequence heterogeneities in Sabin Type 3 strains of attenuated poliovirus demonstrated mutations that consistently accumulate to significant levels following 10 passages in cultures of primary African green monkey kidney (AGMK) cells or continuous cultures of Vero cells. Fourteen newly identified mutations were quantified by mutant analysis by PCR and restriction enzyme cleavage in passages and in batches of commercial vaccines made in AGMK and Vero cells from the Sabin original (SO) seed virus and from a seed virus rederived by RNA plaque purification (RSO or "Pfizer" seed). Nine of the 14 mutations were reproducibly observed in more than one series of passages. Although 5 other mutations were observed in only one set of passages each, their content gradually increased to a high percentage, suggesting that all the mutations that we found accumulated consistently. SO-derived samples accumulated more mutations than did RSO-derived ones, and the number of mutations and the rates of their accumulation were higher in Vero than in AGMK cells. While the rates of accumulation of most mutations were higher when passaging was performed at 37 degrees, a U-->C transition at nucleotide 5832 occurred faster at 34 degrees, the temperature used for vaccine production. Analysis of Type 3 oral poliovirus vaccine (OPV) monopools made by six manufacturers found only 5 of these newly identified mutations in vaccine batches (nucleotides 3956, 4935, 5357, 5788, and 5832). Some of the mutations were found in trace amounts (less than 0.1%) while others were present at up to 1.8% levels. The pattern of these mutations was characteristic for the type of seed virus and the cell substrate but demonstrated no correlation with results of the monkey neurovirulence test. Therefore the only mutation occurring in Type 3 OPV which contributed to neurovirulence in monkeys was the previously described reversion at nucleotide 472. Quantitation of reversion at nucleotide 472 can be utilized for assessment of acceptability of vaccine lots, while other mutations can be used for monitoring the consistency of vaccine production.

Genetic stability and mutant selection in Sabin 2 strain of oral poliovirus vaccine grown under different cell culture conditions.

Mutations that consistently accumulated in the attenuated Sabin 2 strain of poliovirus during propagation in cell cultures were identified by sequence heterogeneity assay and quantified by mutant analysis by PCR and restriction enzyme cleavage (MAPREC). Eight additional sites previously identified in stool isolates were also examined by MAPREC in the virus passages. The pattern of selectable mutations and the rate of their accumulation depended on the type and confluence of the cell culture and the temperature of virus growth. Five unstable genomic sites were identified in Sabin 2 virus passaged 10 times at 34 degrees in African green monkey kidney (AGMK) cells, with the mutations accumulating in the range 1 to 24%. Accumulation of these mutations did not appear to result in a loss of attenuated phenotype since the virus passaged under these conditions passed the monkey neurovirulence test (MNVT). The content of the 481-G revertant known to be related to neurovirulence in monkeys did not increase. Thus, our results suggest that upon growth of Sabin 2 virus in AGMK cells at 34 degrees, the key determinant(s) of attenuation remained stable, and the mutations that occurred did not affect monkey neurovirulence. In virus passaged 10 times at 37 degrees in AGMK cells, 4 unstable genomic sites were identified, in some of them accumulating up to 12% of the mutants. This virus sample severely failed the MNVT. Virus passaged in Vero cells at 34 and 37 degrees accumulated mutants at 7 and 14 genomic sites, respectively, including 481-G in both cases, with almost complete substitution of the original nucleotides at some of the sites. We tested 44 commercial monopools of Type 2 OPV and found out that all of them contained 481-G revertants in the range 0.4-1.1%. An increase in the 481-G revertants in passaged viruses to the level of 4% and above correlated with failure of these samples by the MNVT. Since the pattern of selectable mutations differed in viruses grown in the two cell cultures used in this study, specific mutation profiles should be determined for each cell substrate used for vaccine production to assess manufacturing consistency.

Microevolution of Sabin 1 strain in vitro and genetic stability of oral poliovirus vaccine.

Mutants consistently accumulating in Sabin 1 poliovirus during serial passaging in vitro were identified by sequence heterogeneity assay and quantitated using mutant analysis by PCR and restriction enzyme cleavage (MAPREC). Only four unstable genomic sites were identified in virus passaged 10 times in African green monkey kidney (AGMK) cells, and eight sites in virus passaged in Vero cells. Mutations accumulated both in untranslated regions of RNA (nucleotides 480, 525 and 7441) and in coding sequences, as missense (nucleotides 1449, 4944, and 6203) or silent (nucleotides 1123 and 1141) mutations. The most prominent selectable mutations were found at complementary nucleotides 480 and 525 of the 5'-untranslated region (5'-UTR) of the Sabin strain, changing the G:U pair in F-domain to either A:U or G:C variants. These two variants have been shown previously to have an increased neurovirulence in monkeys. The G:C variant accumulated during passage in Vero cells, while A:U variant accumulated in CV-1 cells. Virus passaged in AGMK cells accumulated both variants. Higher temperature (37 instead of 34 degrees) strongly favored selection of mutants in Vero cells, had a smaller effect on mutant accumulation in AGMK cells, and had no effect in CV-1 cells. Monopools of type 1 oral poliovirus vaccine (OPV) made by seven manufacturers were found to contain both 480-A and 525-C revertants at a combined level of 1.1-2.7%. Viral samples with increased amounts of these revertants had higher neurovirulence in monkeys. Our results suggest that quantitation of these reversions by MAPREC may be prognostic for results of the monkey neurovirulence test (MNVT) and can be used for monitoring type 1 OPV consistency.

Consistent selection of mutations in the 5'-untranslated region of oral poliovirus vaccine upon passaging in vitro.

We have previously found that upon passaging type 3 oral poliovirus vaccine (OPV) in cell cultures the proportion of revertants at nucleotide 472 rapidly increases [Chumakov et al.: Proceedings of the National Academy of Sciences of the United States of America 88:199-203 1991]. Systematic study on the accumulation of these revertants showed that it was dependent on the multiplicity of infection and the temperature at which virus was grown. Revertants at position 472 of type 3 OPV accumulated faster in vaccines derived from Sabin Original (SO) substrain than from RNA-plaque purified (RSO) substrain. The rate of accumulation of 472-C revertants differed among cell lines and was higher in overgrown cell cultures suggesting that host factors are involved in the selection of mutants. We also found that accumulation of mutants occurred in vitro at position 480 in type 1 and position 481 in type 2 OPV, making the selection for revertants in domain F of the 5'-noncoding region a general phenomenon for all three Sabin strains. Assessment of the abundance of these mutants may be used for evaluation of the quality of OPV lots.