Secondary structure of poliovirus RNA: correlation of computer-predicted with electron microscopically observed structure

Viral uncoating is directional: exit of the genomic RNA in a common cold virus starts with the poly-(A) tail at the 3'-end

Upon infection, many RNA viruses reorganize their capsid for release of the genome into the host cell cytosol for replication. Often, this process is triggered by receptor binding and/or by the acidic environment in endosomes. In the genus Enterovirus, which includes more than 150 human rhinovirus (HRV) serotypes causing the common cold, there is persuasive evidence that the viral RNA exits single-stranded through channels formed in the protein shell. We have determined the time-dependent emergence of the RNA ends from HRV2 on incubation of virions at 56°C using hybridization with specific oligonucleotides and detection by fluorescence correlation spectroscopy. We report that psoralen UV crosslinking prevents complete RNA release, allowing for identification of the sequences remaining inside the capsid. We also present the structure of uncoating intermediates in which parts of the RNA are condensed and take the form of a rod that is directed roughly towards a two-fold icosahedral axis, the presumed RNA exit point. Taken together, in contrast to schemes frequently depicted in textbooks and reviews, our findings demonstrate that exit of the RNA starts from the 3′-end. This suggests that packaging also occurs in an ordered manner resulting in the 3′-poly-(A) tail becoming located close to a position of pore formation during conversion of the virion into a subviral particle. This directional genome release may be common to many icosahedral non-enveloped single-stranded RNA viruses.

Viral infection requires safe transfer of the viral genome from within the protective protein shell into the host cell's cytosol. For many viruses this happens after uptake into endosomes, where receptor-binding and/or the acidic pH trigger conformational modifications or disassembly of the shell, allowing the nucleic acids to escape. For example, common cold viruses are converted into subviral particles still containing the single-stranded positive sense RNA genome; subsequently, the RNA escapes into the cytoplasm, leaving behind empty capsids. We triggered this process by heating HRV2 to 56°C and found that 3′- and 5′-end emerged with different kinetics. Crosslinking prevented complete RNA egress and upon nuclease digestion only sequences derived from the 5′-end were protected. Part of the RNA remaining within the viral shell adopted a rod-like shape pointing towards one of the two-fold axes where the RNA is presumed to exit in single-stranded form. Egress thus commences with the poly-(A) tail and not with the genome-linked peptide VPg. This suggests that assembly and uncoating are well-coordinated to avoid tangling, kinetic traps, and/or simultaneous exit of the two RNA ends at different sites.

Functional formation of domain V of the poliovirus noncoding region: significance of unpaired bases

Previously we have shown that polioviruses with mutations that disrupt the predicted secondary structure of the 5' noncoding region of domain V are temperature sensitive for growth. Non-temperature-sensitive revertant viruses had mutations that re-formed secondary structure by a direct back mutation of changes in the opposite strand. We mutated unpaired regions and selected revertants of viruses with single base deletions, where no obvious back mutation was available in order to gain information on secondary structure. Results indicated that conservation of length of a three base loop between two double-stranded stems was essential for a functional domain V to form. The requirement for the unpaired "hinge" base at 484 which is implicated in the attenuation of Sabin 2 was also confirmed. Results also underline the necessity for functional folding over local secondary structure stability.

Coding changes in the poliovirus protease 2A compensate for 5'NCR domain V disruptions in a cell-specific manner

Polioviruses are single-stranded RNA viruses with an unusually long noncoding region (NCR) at the 5' end predicted to have an elaborate secondary structure made up of six domains. Mutations in domain V of the poliovirus 5'NCR that disrupt secondary structure are responsible for attenuation of the virus and a temperature-sensitive (ts) phenotype in vitro. In addition to direct back mutation or compensatory second site mutation in the 5'NCR as previously documented, the ts phenotype was found to be compensated for in monkey kidney cells in vitro by a coding change in the protease 2A. These coding changes were found throughout the protease with no obvious pattern or trend. They were not all found to be equivalent and limited in ability to compensate for the severest domain V disruption. The compensatory effect of the 2A changes was found to be cell specific, having no effect on monkey neurovirulence and in a mouse cell line but a significant effect in two monkey cell lines and a human epithelial line.

Mutations of the HIV type 1 V3 loop under selection pressure with neutralizing monoclonal antibody NM-01

Variants of human immunodeficiency virus type 1 (HIV-1) were selected for resistance to the neutralizing monoclonal antibody (MAb) NM-01. MAb NM-01 recognizes the center of the third hypervariable domain (V3 loop) of the envelope gp120, and neutralizes diverse HIV-1 strains. In the continuous presence of MAb NM-01, transmission and propagation of molecularly cloned HIV-1 were performed in vitro to isolate escape variants. The polymerase chain reaction-single-strand conformation polymorphism and sequence analyses of these variants indicated that the antigenic change against MAb NM-01 is due to a single base substitution resulting in one amino acid interchange within the recognition site of MAb NM-01 in the V3 loop. Mutational analyses also demonstrated a nonrandom event of variability and the existence of mutational hot spots in the V3 loop. The bias of variability could be interpreted by the specificity of error-prone replication by HIV-1 reverse transcriptase. Furthermore, the results suggest that distribution of mutability might correlate closely with the stability of the secondary structure of RNA encoding the V3 loop region.

Reciprocal relationship between stem-loop potential and substitution density in retroviral quasispecies under positive Darwinian selection

Nucleic acids have the potential to form intrastrand stem-loops if complementary bases are suitably located. Computer analyses of poliovirus and retroviral RNAs have revealed a reciprocal relationship between "statistically significant" stem-loop potential and "sequence variability." The statistically significant stem-loop potential of a nucleic acid segment has been defined as a function of the difference between the folding energy of the natural segment (FONS) and the mean folding energy of a set of randomized (shuffled) versions of the natural segment (FORS-M). Since FONS is dependent on both base composition and base order, whereas FORS-M is solely dependent on base composition (a genomic characteristic), it follows that statistically significant stem-loop potential (FORS-D) is a function of base order (a local characteristic). In retroviral genomes, as in all DNA genomes studied, positive FORS-D values are widely distributed. Thus there have been pressures on base order both to encode specific functions and to encode stem-loops. As in the case of DNA genomes under positive Darwinian selection pressure, in HIV-1 specific function appears to dominate in rapidly evolving regions. Here high sequence variability, expressed as substitution density (not indel density), is associated with negative FORS-D values (impaired base-order-dependent stem-loop potential). This suggests that in these regions HIV-1 genomes are under positive selection pressure by host defenses. The general function of stem-loops is recombination. This is a vital process if, from among members of viral "quasispecies," functional genomes are to be salvaged. Thus, for rapidly evolving RNA genomes, it is as important to conserve base-order-dependent stem-loop potential as to conserve other functions.

The 5'-untranslated region of picornaviral genomes

Picornaviruses are small naked icosahedral viruses with a single-stranded RNA genome of positive polarity. According to current taxonomy, the family includes four genera: Enterouirus (polioviruses, coxsackieviruses, echoviruses, and other enteroviruses), Rhinovirus, Curdiouirus [encephalomyocarditis virus (EMCV), mengovirus, Theiler's murine encephalomyelitis virus (TMEV)], and Aphthouirus [foot-and-mouth disease viruses (FMDV)]. There are also some, as yet, unclassified picornaviruses [e.g., hepatitis A virus (HAW] that should certainly be assessed as a separate genus. Studies on the molecular biology of picornaviruses might be divided into two periods: those before and after the first sequencing of the poliovirus genome. The 5'-untranslated region (5-UTR) of the viral genome was one of the unexpected problems. This segment proved to be immensely long: about 750 nucleotides or ∼10% of the genome length. There were also other unusual features (e.g., multiple AUG triplets preceding the single open reading frame (ORF) that encodes the viral polyprotein). This chapter shows that the picornaviral 5-UTRs are not only involved in such essential events as the synthesis of viral proteins and RNAs that could be expected to some extent, although some of the underlying mechanisms appeared to be quite a surprise, but also may determine diverse biological phenotypes from the plaque size or thermosensitivity of reproduction to attenuation of neurovirulence. Furthermore, a close inspection of the 5-UTR structure unravels certain hidden facets of the evolution of the picornaviral genome. Finally, the conclusions drawn from the experiments with the picornaviral5-UTRs provide important clues for understanding the functional capabilities of the eukaryotic ribosomes.

New model for the secondary structure of the 5' non-coding RNA of poliovirus is supported by biochemical and genetic data that also show that RNA secondary structure is important in neurovirulence

A secondary structure model for the 5' non-coding RNA of poliovirus has been derived by comparing computer-generated folding patterns of equivalent sequences from a number of related enteroviruses and rhinoviruses and identifying compensating mutations that suggest conservation of a common secondary structure. Although certain elements are similar, the new model differs considerably from a previously published minimal energy structure and is consistent with the observed sensitivity of in vitro RNA transcripts of infectious poliovirus cDNA to RNases and modifying chemicals. The sequence of a neurovirulent revertant of an attenuated mutant provides additional evidence for an interaction between a region known to be important for neurovirulence, sequence 471-483, and nucleotides 528 to 538.

Conserved structural domains in the 5'-untranslated region of picornaviral genomes: an analysis of the segment controlling translation and neurovirulence

A model of secondary structure common for the central part (ca. 400 nucleotides) of the 5'-untranslated regions (5'-UTR) of all the so far sequenced genomes of polioviruses, coxsackieviruses, and rhinoviruses was derived on the basis of evolutionary and thermodynamic considerations. According to the model, this part of the genome comprises three domains, which appear to be involved, at least in the poliovirus genome, in the control of viral neurovirulence and in vitro translation. Some salient features of this model were supported by investigating RNAs of five poliovirus and one coxsackievirus strains with respect to their accessibility to modifications with dimethyl sulfate and sensitivity to single-strand- and double-strand-specific nucleases. In contrast to the previous suggestion, no major changes in the conformation of the Sabin vaccine poliovirus type 3 5'-UTR due to the transition in position 472 were observed. The biological relevance of the conserved primary and secondary structure elements in the picornaviral 5'-UTRs is discussed.

An internal 5'-noncoding region required for translation of poliovirus RNA in vitro

A truncated poliovirus RNA that contains the entire 5'-noncoding region as well as some capsid protein-coding sequences was produced from cloned cDNA inserted into an SP6 transcription vector and subsequently was translated in a mixed rabbit reticulocyte-HeLa cell lysate. Deletions or modifications of regions of the 5'-noncoding sequences had significant effects upon the efficiency of translation. The presence of a 60-nucleotide sequence located at positions 567 to 627 appeared to be essential for active ribosome binding and translation of this uncapped RNA.

Comparative sequence analysis of the 5' noncoding region of the enteroviruses and rhinoviruses

A comparative sequence analysis of the 5' noncoding region of a subgroup of the picornaviruses, including the polioviruses, coxsackie B3, and the human rhinoviruses, reveals the conservation of certain features despite the divergence of sequence. In this subgroup, for which nine complete sequences are available, two long stretches of sequence, two pyrimidine-rich regions, and 22 hairpins are conserved. Based on these results, similar secondary structures encompassing the entire 5' noncoding regions of these viruses are predicted. The fact that sequence divergence occurred only in a manner that allowed conservation of these structures implicates a biologically functional role for this region. The possible roles it may have in the picornavirus life cycle are discussed.

Crossover regions in foot-and-mouth disease virus (FMDV) recombinants correspond to regions of high local secondary structure

The RNA genome of foot-and-mouth disease virus (FMDV) was analysed for the degree of inverted complementarity and thus potential secondary structure using the procedure of Pustell and Kafatos [Nucleic Acids Res (1982) 10: 4765-4782]. Regions of crossover in 42 FMDV recombinants [King et al. (1985) Virus Res 3: 373-384; Saunders et al. (1985) J Virol 56: 921-929] and regions lacking crossovers were assigned an average secondary structure score against which the number of observed recombinants was plotted. In general it was found that the mean value of potential secondary structure is significantly higher in crossover zones than in recombination-free zones. Recombination increased much more steeply with increasing secondary structure in the part of the genome coding for non-structural proteins than in the 5' third of the genome coding for structural proteins.

Defined recombinants of poliovirus and coxsackievirus: sequence-specific deletions and functional substitutions in the 5'-noncoding regions of viral RNAs

We describe the isolation of a variant of a polio--coxsackie recombinant virus (PCV110) containing a genomic RNA with a chimeric 5'-noncoding region. The variant virus [designated PCV110(1)] has growth and biosynthetic properties that are quite different from the original, temperature-sensitive isolate of the recombinant virus [designated PCV110(4)]. Nucleotide sequencing of the 5'-noncoding region of RNA from PCV110(1) revealed a 4-base deletion within the substituted coxsackievirus region of the chimeric genome that may contribute to the loss of temperature sensitivity of this variant recombinant virus. In addition, we have generated new recombinant viruses that contain (1) coxsackievirus sequences within the N66-N627 region of the poliovirus genome and (2) coxsackievirus sequences substituted from N1-N627 in the poliovirus genome. These recombinant viruses are not temperature sensitive for growth at 37 degrees and have biosynthetic properties similar to those of wild-type poliovirus. Our results provide evidence that replicase recognition signals encoded in the 5' noncoding regions of enterovirus genomic RNAs are not strictly sequence specific.

The visna virus genome: evidence for a hypervariable site in the env gene and sequence homology among lentivirus envelope proteins

The complete nucleotide sequence of the visna virus 1514 genome was determined. Our sequence confirms the relationship of visna virus and other lentiviruses to human immunodeficiency virus (HIV) both at the level of sequence homology and of genomic organization. Sequence homology is shown to extend to the transmembrane proteins of lentivirus env genes; this homology is strongest in the extracellular domain, suggesting that close structural and functional similarities may also exist among these envelope proteins. Comparison of our data with the sequence of visna virus LV1-1, an antigenic variant derived from strain 1514, demonstrates that the rate of divergence has been about 1.7 x 10(-3) substitutions per nucleotide per year in vivo. This rate is orders of magnitude higher than that for most DNA genomes, but agrees well with estimates of the rate for HIV. A statistically significant cluster of mutations in the env gene appears to represent a hypervariable site and may correspond to the epitope responsible for the antigenic differences between 1514 and LV1-1. Analysis of the potential RNA folding pattern of the visna virus env gene shows that this hypervariable site falls within a region with little potential for intramolecular base pairing. This correlation of hypervariability with lack of RNA secondary structure is strengthened by the fact that it also holds for a hypervariable site in the env gene of HIV.

Studies of frequently recurring substructures in human alpha-like globin mRNA precursors

In general, the results obtained from secondary structure prediction algorithms are often inconsistent with those obtained experimentally. The reason for this disagreement is that the experimentally determined structures have higher free energies (as judged by the currently used "energy rules") than the predicted ones. To overcome this limitation we have developed a new approach which incorporates the frequencies of occurrence of substructures in the growing mRNA chain. This has been accomplished by simulating the folding process of pre-mRNAs. Using this approach we have significantly improved current helical structural prediction for 142 analyzed tRNAs and 16 S rRNA. We have next applied this method to the human alpha-like globins. Comparison of the structures obtained by running the currently used algorithms with those computed by the new method indicates that the final most stable secondary structure contains some infrequently occurring substructures. In addition, some of the frequently recurring substructures are not included in the final structure. Comparison of the simulated folding processes of the human alpha-like globin pre-mRNAs reveals some conserved helices and hairpin loop structures in those frequently recurring substructures. Among these several compensating base changes (transitions and transversions) have been identified.

Studies on the recombination between RNA genomes of poliovirus: the primary structure and nonrandom distribution of crossover regions in the genomes of intertypic poliovirus recombinants

A series of intertypic (type 3/type 1) poliovirus recombinants was obtained whose crossover sites were expected to be located in the middle of the viral genome, between the loci encoding type-specific antigenic properties, on the 5' side, and an altered sensitivity to guanidine, on the 3' side. The primary structures of the crossover regions in the genomes of these recombinants were determined by the primer extension method. The length of the crossover sites (the uninterrupted sequences shared by the recombinant and both parental genomes that are flanked, in the recombinant RNAs, by two heterotypic segments) varied between 2 and 32 nucleotides, but the majority of the sites were 5 nucleotides long or shorter. The crossover sites were nonrandomly distributed over the presumably available genome region: only a single such site was found within the gene for polypeptide 2A, whereas an apparent clustering of the crossover sites was encountered in other genomic segments. When the crossover sites were superimposed on a model of the secondary structure of the relevant region of the viral RNA molecule, a pattern consistent with the previously proposed mechanism of poliovirus recombination (L.I. Romanova, V.M. Blinov, E.A. Tolskaya, E.G. Viktorova, M.S. Kolesnikova, E.I. Guseva, and V.I. Agol (1986) Virology 155, 202-213) was observed. It is suggested that the nonrandom distribution of the crossover sites in the genomes of intertypic poliovirus recombinants was due to two factors: the existence of preferred sites for recombination, and selection against recombinants with a lowered level of viability.

Geographic distribution of wild poliovirus type 1 genotypes

Determination of the patterns of genomic variation among RNA virus isolates is a powerful approach for establishing their epidemiologic interrelationships. The standard technique for such studies, ribonuclease T1 oligonucleotide fingerprinting, can detect similarities only among very closely related isolates. The rapid evolution of the poliovirus genome during transmission in humans requires the application of alternate methods to identify more distant relationships. To obtain a substantially broader view of the distribution of wild poliovirus type 1 genotypes in nature, we compared 150 bases of genomic sequence information (encoding parts of the capsid protein VP1 and the noncapsid protein 2A) from 62 isolates obtained from poliomyelitis patients in five continents. The partial sequence information allowed us to (1) identify numerous geographic foci of endemic circulation of wild type 1 polioviruses, (2) reveal previously unsuspected links between cases in distant communities, (3) monitor the displacement from the environment of preexisting polioviruses by viruses from other regions, and (4) recognize the recombinant (vaccine-wild; wild-wild) origins of some epidemic polioviruses.

Potential secondary and tertiary structure in the genomic RNA of foot and mouth disease virus

The nucleotide sequence of the 5' untranslated region of foot and mouth disease virus (FMDV), serotype A10 has been determined. This completes the first total genomic sequence for any one serotype of FMDV. Analysis of the sequence to the 3' side of the poly (C) tract reveals the presence of a 24 nucleotide repeated motif which has homologies with a sequence located upstream of the transcriptional initiation site from several mammalian fibrinogen genes. The function of this element in FMDV is unclear. However, computer analysis of this region predicts the presence of a high degree of secondary and tertiary structure in which these repeats form an important part. The implications of these predictions are discussed.

Cooperative thermal denaturation of the assembly origin region of TMV RNA

The assembly origin (AO) region of the tobacco mosaic virus RNA melts in an usually narrow (2.5 degrees C) temperature range. In an 0.01 M phosphate buffer the melting temperature of AO was found to be 41.5 degrees C. This value corresponds to the regions with the most stable secondary/tertiary structure of the whole TMV RNA molecule. It is assumed that the AO region has a specific tertiary structure, which is maintained by the long-range interactions as well as by interactions of the pseudoknot type.

The entire nucleotide sequence of the genome of human hepatitis A virus (isolate MBB)

Hepatitis A virus (HAV) is an important human pathogen causing hepatitis, with high incidence in developed as well as in developing countries. No vaccines are available. In order to determine the primary structure of the HAV genome, we have prepared cDNAs from viral RNA and cloned these into plasmid pBR322. These clones were used to determine the entire nucleotide sequence of the HAV RNA by rapid sequencing methods. We have compared this sequence of 7470 bases to known partial sequences, and one complete sequence of HAV RNA which were obtained recently from different strains of HAV. It is hoped that a comparison of sequence data from different isolates will help in the elucidation of the unusual growth pattern of HAV. In addition, it might provide helpful information about the immunological determinants that elicit the antibody response to infection.

Poliovirus temperature-sensitive mutant containing a single nucleotide deletion in the 5'-noncoding region of the viral RNA

The effect on viral replication of deleting nucleotide 10 of the poliovirus RNA genome was determined. This deletion, which removes a base pair from a predicted hairpin structure in the viral RNA, was introduced into full-length cDNA. Virus recovered after transfection of HeLa cells with the mutated cDNA contained the expected deletion and was temperature sensitive for plaque formation. Analysis of viral replication by one-step growth experiments indicated that mutant virus production at the nonpermissive temperature was at least 100 times less than that of wild type virus, and release of virus from mutant-infected cells was delayed. The synthesis of positive- and negative-strand viral RNA in mutant virus-infected cells was temperature sensitive. Virus-specific protein synthesis in mutant virus-infected cells was not temperature sensitive but occurred at a slower rate than that of wild type virus at permissive and nonpermissive temperatures. Replication of the mutant virus was sensitive to actinomycin D, in contrast to the wild type parent virus, which was resistant to the drug. Mutant virus stocks contained a small percentage of ts+ viruses that were able to form plaques at the nonpermissive temperature. Nucleotide sequence analysis of genomic RNA from these ts+ viruses revealed a single base change at position 34 from a G to U. In the positive RNA strand, the effect of this mutation is to restore to the hairpin structure the single base pair whose formation was prevented by the original deletion. The ts+ pseudorevertants replicated to similar titers as wild type virus at 33 and 38.5 degrees and were partially sensitive to actinomycin D.

Circularization of retroviral genomic RNA and the control of RNA translation, packaging and reverse transcription

Translation, packaging and reverse transcription of the genomic RNA of retroviruses appear to be regulated by short and long range RNA-RNA interactions which take place within the 5'-600 nt and between the 5' and 3' untranslated sequences. The 5' (R and U5) and 3' (Dr and U3) domains of the genomic RNA together with the nucleic acid binding protein (NBP) would control the balance between the open state of the viral genomic RNA, correlated with an efficient RNA translation and the closed state, with the circular viral RNA efficiently packaged into virions. Retroviral NBP might well drive the packaging of the viral RNA as well as improve reverse transcription of the circular virion RNA.

Synthesis of plus- and minus-strand RNA from poliovirion RNA template in vitro

The poliovirus RNA polymerase, 3Dpol, was used to synthesize RNA in vitro in the presence of a host factor preparation from uninfected HeLa cells and poliovirion RNA as the template. The transcription products included molecules approximately twice the length of the template, apparently resulting from hairpin formation and template-directed elongation, as previously reported (D. C. Young, D. M. Tuschall, and J. B. Flanegan, J. Virol. 54:256-264, 1985). Other polyadenylated template RNAs also yielded products that were twice the length of the template. The polarity of the products synthesized from plus-strand poliovirus RNA template was analyzed by Southern blotting using labeled product RNA to probe single-stranded poliovirus DNAs cloned into M13 vectors. The results demonstrated that host factor-mediated polymerase products contain newly synthesized plus-strand sequences as well as the expected minus-strand sequences. Polymerase products primed with oligo(U) were all of minus-strand polarity.