Reduction of the rate of poliovirus protein synthesis through large-scale codon deoptimization causes attenuation of viral virulence by lowering specific infectivity

Exploring the utility of de novo gene synthesis with the aim of designing stably attenuated polioviruses (PV), we followed two strategies to construct PV variants containing synthetic replacements of the capsid coding sequences either by deoptimizing synonymous codon usage (PV-AB) or by maximizing synonymous codon position changes of the existing wild-type (wt) poliovirus codons (PV-SD). Despite 934 nucleotide changes in the capsid coding region, PV-SD RNA produced virus with wild-type characteristics. In contrast, no viable virus was recovered from PV-AB RNA carrying 680 silent mutations, due to a reduction of genome translation and replication below a critical level. After subcloning of smaller portions of the AB capsid coding sequence into the wt background, several viable viruses were obtained with a wide range of phenotypes corresponding to their efficiency of directing genome translation. Surprisingly, when inoculated with equal infectious doses (PFU), even the most replication-deficient viruses appeared to be as pathogenic in PV-sensitive CD155tg (transgenic) mice as the PV(M) wild type. However, infection with equal amounts of virus particles revealed a neuroattenuated phenotype over 100-fold. Direct analysis indicated a striking reduction of the specific infectivity of PV-AB-type virus particles. Due to the distribution effect of many silent mutations over large genome segments, codon-deoptimized viruses should have genetically stable phenotypes, and they may prove suitable as attenuated substrates for the production of poliovirus vaccines.     

Genetic Inactivation of Poliovirus Infectivity by Increasing the Frequencies of CpG and UpA Dinucleotides within and across Synonymous Capsid Region Codons

Replicative fitness of poliovirus can be modulated systematically by replacement of preferred capsid region codons with synonymous unpreferred codons. To determine the key genetic contributors to fitness reduction, we introduced different sets of synonymous codons into the capsid coding region of an infectious clone derived from the type 2 prototype strain MEF-1. Replicative fitness in HeLa cells, measured by plaque areas and virus yields in single-step growth experiments, decreased sharply with increased frequencies of the dinucleotides CpG (suppressed in higher eukaryotes and most RNA viruses) and UpA (suppressed nearly universally). Replacement of MEF-1 capsid codons with the corresponding codons from another type 2 prototype strain (Lansing), a randomization of MEF-1 synonymous codons, increased the %G+C without increasing CpG, and reductions in the effective number of codons used had much smaller individual effects on fitness. Poliovirus fitness was reduced to the threshold of viability when CpG and UpA dinucleotides were saturated within and across synonymous codons of a capsid region interval representing only ∼9% of the total genome. Codon replacements were associated with moderate decreases in total virion production but large decreases in the specific infectivities of intact poliovirions and viral RNAs. Replication of codon replacement viruses, but not MEF-1, was temperature sensitive at 39.5°C. Synthesis and processing of viral intracellular proteins were largely unaltered in most codon replacement constructs. Replacement of natural codons with synonymous codons with increased frequencies of CpG and UpA dinucleotides may offer a general approach to the development of attenuated vaccines with well-defined antigenicities and very high genetic stabilities.Diversification of genomic sequences is constrained in all biological systems. At the level of primary sequences, the range of variability in coding regions is restricted by the codon usage bias (CUB), whereby a subset of synonymous codons are preferentially used in translation (24, 53, 69). The intensity of the CUB and the specific set of preferred codons vary widely across biological systems (39). Intertwined with the CUB is the suppression of the dinucleotides CpG and TpA (or UpA in RNA viruses) in the genomes of higher eukaryotes (4, 7, 26, 61) and many of their RNA viruses and small DNA viruses (28, 49). Variation in the primary sequences of RNA virus genomes is further constrained by requirements to maintain essential secondary and higher-order structures (42, 54, 68).We previously described the modulation of the replicative fitness of the Sabin type 2 oral poliovirus vaccine (OPV) strain (Sabin 2) by systematically changing the CUB in the capsid region, replacing the naturally occurring preferred codons with an unpreferred synonymous codon (isocodon) for each of nine amino acids (8). We called our approach “codon deoptimization” to contrast with the process of codon optimization, which is frequently used to maximize expression of foreign proteins in heterologous host systems (1, 27, 70). Apart from its potential application to development of improved poliovirus vaccines (8, 13, 38), experimental investigations of codon deoptimization directly test the relationships between replicative fitness, the extent of CUB, and the intensity of CpG and UpA suppression. As a model system for such studies, polioviruses offer several favorable properties, including (i) intrinsically high error rates for the poliovirus RNA-dependent RNA polymerase (2, 14, 16, 65), (ii) very high evolution rates (25), (iii) short generation times (8 to 10 h) and large progeny yields of prototype polioviruses, and (iv) well-developed reverse genetics (9).In this report, we extend our codon deoptimization strategy to the type 2 wild poliovirus prototype strain MEF-1. As before, we restricted our replacement of synonymous codons to the capsid coding region, which encodes two of the defining properties of polioviruses, namely, (i) the capacity to bind the CD155 poliovirus receptor (PVR) (23) and (ii) the poliovirus type-specific neutralizing antigenic sites (35). No changes were made to the flanking 5′-untranslated region and noncapsid region sequences, as they contain essential secondary structural elements (42, 54, 68) and are frequently exchanged out by recombination during circulation of poliovirus in human populations (20, 30, 32). MEF-1 was selected because of its high fitness level (hence, its use as the type 2 component of the inactivated poliovirus vaccine [IPV]) and because of its neurovirulence for humans (15), for nontransgenic mice (52), and for transgenic mice expressing the PVR (71). Type 2 polioviruses were selected first for study because the Sabin 2 OPV strain is most frequently associated with vaccine-associated paralytic poliomyelitis in contacts of OPV recipients (57, 59), with prolonged excretion of immunodeficiency-associated vaccine-derived polioviruses (VDPVs) (10, 31, 60), and with the emergence of circulating VDPVs in areas of low OPV coverage (10, 31).Consistent with our previous findings, the fitness of MEF-1 decreased in proportion to the total number of synonymous replacement codons. Fitness was reduced most efficiently by increasing the frequencies of CpG and UpA dinucleotides within and across synonymous codons. Saturation of CpG and UpA in a small capsid interval (representing only ∼9% of the genome) reduced fitness to the threshold of viability, even though the MEF-1 amino acid sequence was unaltered. The most prominent biological effect of deoptimization of codon usage and the large-scale incorporation of CpG and UpA was a sharp reduction in virus specific infectivities. In contrast, translation and processing of viral proteins and yields of intact virus particles with native antigenicities were reduced only moderately by increased CpG and UpA frequencies. Codon deoptimization with concurrent increases in the frequencies of CpG and/or UpA dinucleotides in RNA virus genomes may provide a novel general approach to the rational design of improved attenuated vaccines with predictable and stable genetic properties.     

Slow fitness recovery in a codon-modified viral genome

Extensive synonymous codon modification of viral genomes appears to be an effective way of attenuating strains for use as live vaccines. An assumption of this method is that codon changes have individually small effects, such that codon-attenuated viruses will be slow to evolve back to high fitness (and thus to high virulence). The major capsid gene of the bacterial virus T7 was modified to have varying levels of suboptimal synonymous codons in different constructs, and fitnesses declined linearly with the number of changes. Adaptation of the most extreme design, with 182 codon changes, resulted in a slow fitness recovery by standards of previous experimental evolution with this virus, although fitness effects of substitutions were higher than expected from the average effect of an engineered codon modification. Molecular evolution during recovery was modest, and changes evolved both within the modified gene and outside it. Some changes within the modified gene evolved in parallel across replicates, but with no obvious explanation. Overall, the study supports the premise that codon-modified viruses recover fitness slowly, although the evolution is substantially more rapid than expected from the design principle.     

Mutational analysis of upstream AUG codons of poliovirus RNA.

The 5' untranslated region of poliovirus type 2 Lansing RNA consists of 744 nucleotides containing seven AUG codons which are followed by in-frame termination codons, thus forming short open reading frames (ORFs). To determine the biological significance of these small ORFs, all of the upstream AUG codons were mutated to UUG. The point mutations were introduced into an infectious poliovirus cDNA clone, and RNA transcribed in vitro from the altered cDNA was transfected into HeLa cells to recover the virus. Mutation of AUG 7 resulted in a virus (called R2-5NC-14) with a small-plaque phenotype, whereas mutation of the other six AUG codons produced virus with a wild-type plaque morphology. To determine whether the small-plaque phenotype of R2-5NC-14 was due to altered translational efficiency of the viral mRNA, we constructed chimeric mRNAs containing the 5' noncoding region of poliovirus mRNA fused to the chloramphenicol acetyltransferase (CAT) coding sequence. mRNA containing a mutated AUG 7 codon showed decreased translational efficiency in vitro. The results indicate that the upstream ORFs of poliovirus RNA are not essential for viral replication and do not act as barriers to the translation of poliovirus mRNA. AUG 7 and flanking sequences may play a positive acting role in poliovirus RNA translation.     

Factor-independent assembly of elongation-competent ribosomes by an internal ribosome entry site located in an RNA virus that infects penaeid shrimp

The Taura syndrome virus (TSV), a member of the Dicistroviridae family of viruses, is a single-stranded positive-sense RNA virus which contains two nonoverlapping reading frames separated by a 230-nucleotide intergenic region. This intergenic region contains an internal ribosome entry site (IRES) which directs the synthesis of the TSV capsid proteins. Unlike other dicistroviruses, the TSV IRES contains an AUG codon that is in frame with the capsid region, suggesting that the IRES initiates translation at this AUG codon by using initiator tRNAmet. We show here that the TSV IRES does not use this or any other AUG codon to initiate translation. Like the IRES in cricket paralysis virus (CrPV), the TSV IRES can assemble 80S ribosomes in the absence of initiation factors and can direct protein synthesis in a reconstituted system that contains only purified ribosomal subunits, eukaryotic elongation factors 1A and 2, and aminoacylated tRNAs. The functional conservation of the CrPV-like IRES elements in viruses that can infect different invertebrate hosts suggests that initiation at non-AUG codons by an initiation factor-independent mechanism may be more prevalent.     

Genome variability and capsid structural constraints of hepatitis a virus

The number of synonymous mutations per synonymous site (K(s)), the number of nonsynonymous mutations per nonsynonymous site (K(a)), and the codon usage statistic (N(c)) were calculated for several hepatitis A virus (HAV) isolates. While K(s) was similar to those of poliovirus (PV) and foot-and-mouth disease virus (FMDV), K(a) was 1 order of magnitude lower. The N(c) parameter provides information on codon usage bias and decreases when bias increases. The N(c) value in HAV was about 38, while in PV and FMDV, it was about 53. The emergence of 22 rare codons in front of 8 in PV and 7 in FMDV was detected. Most of the conserved rare codons of the P1 region were strategically located at the carboxy borders of beta barrels and alpha helices, their potential function being the assurance of proper folding of the capsid proteins through a decrease in the translation speed. This strategic location was not observed for amino acids encoded by the conserved rare codons of the 3D region. The percentage of bases with low pairing number values was higher in the latter region, suggesting a role of the conserved rare codons in the maintenance of RNA structure. Many of the rare codons in HAV are among the most frequent in humans, unlike in PV or in FMDV. This fact may be explained by the lack of cellular shutoff in HAV. One hypothesis is that HAV has evolved in order to avoid competition with its host for cellular tRNAs.     

Deterministic, compensatory mutational events in the capsid of foot-and-mouth disease virus in response to the introduction of mutations found in viruses from persistent infections

The evolution of foot-and-mouth disease virus (FMDV) (biological clone C-S8c1) in persistently infected cells led to the emergence of a variant (R100) that displayed increased virulence, reduced stability, and other modified phenotypic traits. Some mutations fixed in the R100 genome involved a cluster of highly conserved residues around the capsid pores that participate in interactions with each other and/or between capsid protomers. We have investigated phenotypic and genotypic changes that occurred when these replacements were introduced into the C-S8c1 capsid. The C3007V and M3014L mutations exerted no effect on plaque size or viral yield during lytic infections, or on virion stability, but led to a reduction in biological fitness; the D3009A mutation caused drastic reductions in plaque size and viability. Remarkably, competition of the C3007V mutant with the nonmutated virus invariably resulted in the fixation of the D3009A mutation in the C3007V capsid. In turn, the presence of the D3009A mutation invariably led to the fixation of the M3014L mutation. In both cases, two individually disadvantageous mutations led, together, to an increase in fitness, as the double mutants outcompeted the nonmutated genotype. The higher fitness of C3007V/D3009A was related to a faster multiplication rate. These observations provide evidence for a chain of linked, compensatory mutational events in a defined region of the FMDV capsid. Furthermore, they indicate that the clustering of unique amino acid replacements in viruses from persistent infections may also occur in cytolytic infections in response to changes caused by previous mutations without an involvement of the new mutations in the adaptation to a different environment.     

Attenuation of Tick-Borne Encephalitis Virus Using Large-Scale Random Codon Re-encoding

Large-scale codon re-encoding (i.e. introduction of a large number of synonymous mutations) is a novel method of generating attenuated viruses. Here, it was applied to the pathogenic flavivirus, tick-borne encephalitis virus (TBEV) which causes febrile illness and encephalitis in humans in forested regions of Europe and Asia. Using an infectious clone of the Oshima 5–10 strain ("wild-type virus"), a cassette of 1.4kb located in the NS5 coding region, was modified by randomly introducing 273 synonymous mutations ("re-encoded virus"). Whilst the in cellulo replicative fitness of the re-encoded virus was only slightly reduced, the re-encoded virus displayed an attenuated phenotype in a laboratory mouse model of non-lethal encephalitis. Following intra-peritoneal inoculation of either 2.10⁵ or 2.10⁶ TCID50 of virus, the frequency of viraemia, neurovirulence (measured using weight loss and appearance of symptoms) and neuroinvasiveness (detection of virus in the brain) were significantly decreased when compared with the wild-type virus. Mice infected by wild-type or re-encoded viruses produced comparable amounts of neutralising antibodies and results of challenge experiments demonstrated that mice previously infected with the re-encoded virus were protected against subsequent infection by the wild-type virus. This constitutes evidence that a mammalian species can be protected against infection by a virulent wild-type positive-stranded RNA virus following immunisation with a derived randomly re-encoded strain. Our results demonstrate that random codon re-encoding is potentially a simple and effective method of generating live-attenuated vaccine candidates against pathogenic flaviviruses.     

Demethylation and expression of methylated plasmid DNA stably transfected into HeLa cells.

In vitro methylation at CG dinucleotides (CpGs) in a transfecting plasmid usually greatly inhibits gene expression in mammalian cells. However, we found that in vitro methylation of all CpGs in episomal or non-episomal plasmids containing the SV40 early promoter/enhancer (SV40 Pr/E) driving expression of an antibiotic-resistance gene decreased the formation of antibiotic-resistant colonies by only approximately 30-45% upon stable transfection of HeLa cells. In contrast, when expression of the antibiotic-resistance gene was driven by the Rous sarcoma virus long terminal repeat or the herpes simplex virus thymidine kinase promoter, this methylation decreased the yield of antibiotic-resistant HeLa transfectant colonies approximately 100-fold. The low sensitivity of the SV40 Pr/E to silencing by in vitro methylation was probably due to demethylation upon stable transfection. This demethylation may be targeted to the promoter and extend into the gene. By genomic sequencing, we showed that four out of six of the transfected SV40 Pr/E's adjacent Sp1 sites were hotspots for demethylation in the HeLa transfectants. High frequency demethylation at Sp1 sites was unexpected for a non-embryonal cell line and suggests that DNA demethylation targeted to certain aberrantly methylated regions may function as a repair system for epigenetic mistakes.     

Mapping of sequences required for mouse neurovirulence of poliovirus type 2 Lansing.

Intracerebral inoculation of mice with poliovirus type 2 Lansing induces a fatal paralysis, while most other poliovirus strains are unable to cause disease in the mouse. To determine the molecular basis for Lansing virus neurovirulence, we determined the complete nucleotide sequence of the Lansing viral genome from cloned cDNA. The deduced amino acid sequence was compared with that of two mouse-avirulent strains. There are 83 amino acid differences between the Lansing and Sabin type 2 strain and 179 differences between the Lansing and Mahoney type 1 strain scattered throughout the genome. To further localize Lansing sequences important for mouse neurovirulence, four intertypic recombinants were isolated by exchanging DNA restriction fragments between the Lansing 2 and Mahoney 1 infectious poliovirus cDNA clones. Plasmids were transfected into HeLa cells, and infectious recombinant viruses were recovered. All four recombinant viruses, which contained the Lansing capsid region and different amounts of the Mahoney genome, were neurovirulent for 18- to 21-day-old Swiss-Webster mice by the intracerebral route. The genome of neurovirulent recombinant PRV5.1 contained only nucleotides 631 to 3413 from Lansing, encoding primarily the viral capsid proteins. Therefore, the ability of Lansing virus to cause paralysis in mice is due to the viral capsid. The Lansing capsid sequence differs from that of the mouse avirulent Sabin 2 strain at 32 of 879 amino acid positions: 1 in VP4, 5 in VP2, 4 in VP3, and 22 in VP1.     

Evolution of circulating wild poliovirus and of vaccine-derived poliovirus in an immunodeficient patient: a unifying model

We determined nucleotide sequences of the VP1 and 2AB genes and portions of the 2C and 3D genes of two evolving poliovirus lineages: circulating wild viruses of T geotype and Sabin vaccine-derived isolates from an immunodeficient patient. Different regions of the viral RNA were found to evolve nonsynchronously, and the rate of evolution of the 2AB region in the vaccine-derived population was not constant throughout its history. Synonymous replacements occurred not completely randomly, suggesting the need for conservation of certain rare codons (possibly to control translation elongation) and the existence of unidentified constraints in the viral RNA structure. Nevertheless the major contribution to the evolution of the two lineages came from linear accumulation of synonymous substitutions. Therefore, in agreement with current theories of viral evolution, we suggest that the majority of the mutations in both lineages were fixed as a result of successive sampling, from the heterogeneous populations, of random portions containing predominantly neutral and possibly adverse mutations. As a result of such a mode of evolution, the virus fitness may be maintained at a more or less constant level or may decrease unless more-fit variants are stochastically generated. The proposed unifying model of natural poliovirus evolution has important implications for the epidemiology of poliomyelitis.     

In vitro phenotypic markers of a poliovirus recombinant constructed from infectious cDNA clones of the neurovirulent Mahoney strain and the attenuated Sabin 1 strain.

Infectious cDNA corresponding to the entire genome of the attenuated Sabin strain of type 1 poliovirus has been inserted into EcoRI site of bacterial plasmid pBR325. Two consecutive PstI fragments (nucleotide positions 1814 to 3421) of the infectious cDNA of the Sabin 1 strain were replaced by the corresponding DNA fragments prepared from an infectious DNA clone of the genome of the virulent Mahoney strain of poliovirus type 1. The exchanged segment encodes capsid protein VP1 and part of capsid protein VP3, a region in which a large number of amino acid differences between the attenuated Sabin and the parental, neurovirulent Mahoney strain cluster. The recombinant virus was obtained by DNA transfection of HeLa S3 cells, and several in vitro phenotypes of the virus were compared with those of the parental viruses. The recombinant virus was recognized by a neutralizing monoclonal antibody specific to the Mahoney strain. Growth of the Sabin strain of poliovirus has been shown to be quite dependent upon the bicarbonate concentration (d marker). The growth of the recombinant virus, however, was not highly dependent upon the concentration of bicarbonate in cell culture media, and thus resembled that of the Mahoney strain. On the other hand, the temperature-sensitive multiplication (rct marker) and the small-plaque morphology of the recombinant virus corresponded to the phenotype of the Sabin 1 strain. The in vitro recombination of infectious cDNA clones of genomic RNA and subsequent analysis of the growth properties of the recombinant virus have allowed us to correlate specific mutations in the genome of an RNA virus with certain biological characteristics of that virus.     

trans-Encapsidation of a Poliovirus Replicon by Different Picornavirus Capsid Proteins

A trans-encapsidation assay was established to study the specificity of picornavirus RNA encapsidation. A poliovirus replicon with the luciferase gene replacing the capsid protein-coding region was coexpressed in transfected HeLa cells with capsid proteins from homologous or heterologous virus. Successful trans-encapsidation resulted in assembly and production of virions whose replication, upon subsequent infection of HeLa cells, was accompanied by expression of luciferase activity. The amount of luciferase activity was proportional to the amount of trans-encapsidated virus produced from the cotransfection. When poliovirus capsid proteins were supplied in trans, >2 × 10⁶ infectious particles/ml were produced. When coxsackievirus B3, human rhinovirus 14, mengovirus, or hepatitis A virus (HAV) capsid proteins were supplied in trans, all but HAV showed some encapsidation of the replicon. The overall encapsidation efficiency of the replicon RNA by heterologous capsid proteins was significantly lower than when poliovirus capsid was used. trans-encapsidated particles could be completely neutralized with specific antisera against each of the donor virus capsids. The results indicate that encapsidation is regulated by specific viral nucleic acid and protein sequences.     

An inducible mammalian amber suppressor: propagation of a poliovirus mutant

We describe a general protocol for controlled gene amplification, which allows conditional expression of high levels of amber suppressor activity in monkey kidney cells, and we demonstrate its use in the genetic analysis of animal viruses by the generation and propagation of the first nonsense mutant of poliovirus. A human amber suppressor tRNASer gene linked to the SV40 origin of replication and a second DNA carrying a temperature-sensitive SV40 large T antigen gene were cotransfected into monkey cells. Cell lines having stably integrated the DNAs were isolated. Shifting the cells from the nonpermissive temperature to a lower permissive temperature caused the amplification of the suppressor tRNA gene, which resulted in suppression efficiencies at amber codons of 50%-70%, as measured by suppression of an amber codon in the E. coli chloramphenicol acetyltransferase gene. A mutant of poliovirus, in which a serine codon in the replicase gene was converted to an amber codon, was efficiently propagated on the suppressor-positive cell lines. The mutant virus reverted to wild-type by a single base change to a serine codon at a frequency of approximately 2.5 x 10(-6), surprisingly low for a RNA genome.     

Endogenous 5-methylcytosine protects neighboring guanines from N7 and O6-methylation and O6-pyridyloxobutylation by the tobacco carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone

All CG dinucleotides along exons 5-8 of the p53 tumor suppressor gene contain endogenous 5-methylcytosine (MeC). These same sites (e.g., codons 157, 158, 245, 248, and 273) are mutational hot spots in smoking-induced lung cancer. Several groups used the UvrABC endonuclease incision assay to demonstrate that methylated CG dinucleotides of the p53 gene are the preferred binding sites for the diol epoxides of bay region polycyclic aromatic hydrocarbons (PAH). In contrast, effects of endogenous cytosine methylation on the distribution of DNA lesions induced by tobacco-specific nitrosamines, e.g., 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), have not been elucidated. In the work presented here, a stable isotope labeling HPLC-ESI-MS/MS approach was employed to analyze the reactivity of the N7 and O6 positions of guanines within hemimethylated and fully methylated CG dinucleotides toward NNK-derived methylating and pyridyloxobutylating species. 15N3-labeled guanine bases were placed within synthetic DNA sequences representing endogenously methylated p53 codons 154, 157, and 248, followed by treatment with acetylated precursors to NNK diazohydroxides. HPLC-ESI-MS/MS analysis was used to determine the relative yields of N7- and O6-guanine adducts at the 15N3-labeled position. In all cases, the presence of MeC inhibited the formation of N7-methylguanine, O6-methylguanine, and O6-pyridyloxobutylguanine at a neighboring G, with the greatest decrease observed in fully methylated dinucleotides and at guanines preceded by MeC. Furthermore, the O6-Me-dG/N7-Me-G molar ratios were decreased in the presence of the 5'-neighboring MeC, suggesting that the observed decline in O6-alkylguanine adduct yields is, at least partially, a result of an altered reactivity pattern in methylated CG dinucleotides. These results indicate that, unlike N2-guanine adducts of PAH diol epoxides, NNK-induced N7- and O6-alkylguanine adducts are not preferentially formed at the endogenously methylated CG sites within the p53 tumor suppressor gene.     

Replication of poliovirus in Xenopus oocytes requires two human factors.

We described a novel system to study poliovirus replication in Xenopus oocytes. Poliovirus RNA microinjected into Xenopus oocyte initiates a complete cycle of viral replication, yielding a high level of infectious viruses. Two distinct HeLa cell activities are required, one involved in initiation of translation and the other in RNA synthesis. The translation factor is a large cytoplasmic protein or complex, which is specifically used for initiation of poliovirus translation. The replication factor is required at early stages of RNA synthesis. Formation of infectious poliovirus is highly temperature dependent. At temperatures below 27 degrees C, capsid assembly appears to be impaired. The oocyte system described here could be useful in identifying and characterizing viral and cellular factors involved in virus replication.     

Structural analysis of human immunodeficiency virus type 1 Gag protein interactions, using cysteine-specific reagents.

We have examined structural interactions of Gag proteins in human immunodeficiency virus type 1 (HIV-1) particles by utilizing cysteine mutagenesis and cysteine-specific modifying reagents. In immature protease-minus but otherwise wild-type (wt) particles, precursor Pr55Gag proteins did not form intermolecular cystines naturally but could be cross-linked at cysteines, and cross-linking appeared to occur across nucleocapsid (NC) domains. Capsid (CA) proteins in wt mature viruses possess cysteines near their carboxy termini at gag codons 330 and 350, but these residues are not involved in natural covalent intermolecular bonds, nor can they be intermolecularly cross-linked by using the membrane-permeable cross-linker bis-maleimido hexane. The cysteine at gag codon 350 (C-350) is highly reactive to thiol-specific modifying reagents, while the one at codon 330 (C-330) appears considerably less reactive, even in the presence of ionic detergent. These results suggest that the HIV-1 CA C terminus forms an unusually stable conformation. Mutagenesis of C-350 to a serine residue in the mutant C350S (C-350 changed to serine) virtually eliminated particle assembly, attesting to the importance of this region. We also examined a C330S mutant, as well as mutants in which cysteines were created midway through the capsid domain or in the C-terminal section of the major homology region. All such mutants appeared wt on the basis of biochemical assays but showed greatly reduced infectivities, indicative of a postassembly, postprocessing replicative block. Interestingly, capsid proteins of mature major homology region mutant particles could be cysteine cross-linked, implying either that these mutations permit cross-linking of the native C-terminal CA cysteines or that major homology regions on neighbor capsid proteins are in close proximity in mature virions.     

Host-dependent restriction of mengovirus replication. II. Effect of host restriction on late viral RNA synthesis and viral maturation.

Restricted mengovirus replication in Mandin-Darby bovine kidney (MDBK) cells is characterized by a 400-fold reduction in infectious virus yield and a 40-fold increase in the production of noninfectious virus. Using conditions which insure that all MDBK cells are infected, virus-specific RNA and protein synthesis were measured in the restrictive host and in a permissive host for mengovirus, HeLa cells. Labeling kinetics and sucrose gradient analysis of mengovirus-specific RNA from MDBK cells show a reduction of 10-fold in virion RNA, 5-fold in double-stranded RNA, and 12.5-fold in single-stranded RNA. The viral RNA biosynthetic processes which occur late in the replicative cycle and result in the production of 90% of the single-stranded viral RNA that is packaged into capsid proteins in the permissive host are absent in restrictive MDBK cells. Viral protein synthesis as measured by labeled viral-specific polysome is decreased, and there is an accumulation of 80S subviral particles in the restricted host. It is suggested that restriction may act at a number of stages of viral replication and maturation.     

Extreme fitness differences in mammalian and insect hosts after continuous replication of vesicular stomatitis virus in sandfly cells.

Continuous, persistent replication of a wild-type strain of vesicular stomatitis virus in cultured sandfly cells for 10 months profoundly decreased virus replicative fitness in mammalian cells and greatly increased fitness in sandfly cells. After persistent infection of sandfly cells, fitness was over 2,000,000-fold greater than that in mammalian cells, indicating extreme selective differences in the environmental conditions provided by insect and mammalian cells. The sandfly-adapted virus also showed extremely low fitness in mouse brain cells (comparable to that in mammalian cell cultures). It also showed an attenuated phenotype, requiring a nearly millionfold higher intracranial dose than that of its parent clone to kill mice. A single passage of this adapted virus in BHK-21 cells at 37 degrees C restored fitness to near neutrality and also restored mouse neurovirulence. These results clearly illustrate the enormous capacity of RNA viruses to adapt to changing selective environments.     

Translational efficiency of poliovirus mRNA: mapping inhibitory cis-acting elements within the 5'' noncoding region.

Poliovirus mRNA contains a long 5' noncoding region of about 750 nucleotides (the exact number varies among the three virus serotypes), which contains several AUG codons upstream of the major initiator AUG. Unlike most eucaryotic mRNAs, poliovirus does not contain a m7GpppX (where X is any nucleotide) cap structure at its 5' end and is translated by a cap-independent mechanism. To study the manner by which poliovirus mRNA is expressed, we examined the translational efficiencies of a series of deletion mutants within the 5' noncoding region of the mRNA. In this paper we report striking translation system-specific differences in the ability of the altered mRNAs to be translated. The results suggest the existence of an inhibitory cis-acting element(s) within the 5' noncoding region of poliovirus (between nucleotides 70 and 381) which restricts mRNA translation in reticulocyte lysate, wheat germ extract, and Xenopus oocytes, but not in HeLa cell extracts. In addition, we show that HeLa cell extracts contain a trans-acting factor(s) that overcomes this restriction.