Coxsackieviruses and quasispecies theory: evolution of enteroviruses.

Enterovirus populations display quasispecies dynamics, characterized by high rates of mutation and recombination, followed by competition, selection, and random drift acting on heterogeneous mutant spectra. Direct experimental evidence indicates that high mutation rates and complex mutant spectra can serve for the adaptation of enteroviruses to complex environments. Studies with the RNA-dependent RNA polymerase of picornaviruses suggest that multiple enzyme sites may influence the template-copying fidelity (incorporation of incorrect vs correct nucleotide) during RNA replication. Mutation and recombination are an unavoidable consequence of the molecular mechanisms inherent to the process of viral genome replication and underlie the diversification of enterovirus genomes as they multiply in human and animal hosts. The diversity of disease manifestations associated with closely related enteroviruses is probably attributable to profound biological effects of some mutations that, because of their limited number, do not necessarily affect the phylogenetic position of the virus. The combination of highly dynamic mutant spectra with unpredictable alterations of biological behavior by minimal genetic change defies classical classification schemes. The result is the need to update the grouping of enteroviruses quite frequently into genetic and serological types and subtypes. The tolerance of enterovirus genomes to remain replication-competent despite multiple mutation and recombination events encourages the engineering of live-attenuated vaccines. Also, the application of quasispecies theory to an understanding of the limits of viral genomes to accept mutations, together with an increasingly deeper understanding of the mechanisms of mutagenesis by nucleoside analogs, has paved the way for the application of lethal mutagenesis as a new antiviral strategy.

Population bottlenecks in quasispecies dynamics.

The characteristics of natural populations result from different stochastic and deterministic processes that include reproduction with error, selection, and genetic drift. In particular, population fluctuations constitute a stochastic process that may play a very relevant role in shaping the structure of populations. For example, it is expected that small asexual populations will accumulate mutations at a higher rate than larger ones. As a consequence, in any population the fixation of mutations is accelerated when environmental conditions cause population bottlenecks. Bottlenecks have been relatively frequent in the history of life and it is generally accepted that they are highly relevant for speciation. Although population bottlenecks can occur in any species, their effects are more noticeable in organisms that form large and heterogeneous populations, such as RNA viral quasispecies. Bottlenecks can also positively select and isolate particles that still keep the ability to infect cells from a disorganized population created by crossing the error threshold.

Population dynamics of RNA viruses: the essential contribution of mutant spectra.

Cells and their viral and cellular parasites are genetically highly diverse, and their genomes contain signs of past and present variation and mobility. The great adaptive potential of viruses, conferred on them by high mutation rates and quasispecies dynamics, demands new strategies for viral disease prevention and control. This necessitates a more detailed knowledge of viral population structure and dynamics. Here we review studies with the important animal pathogen Foot-and-mouth disease virus (FMDV) that document modulating effects of the mutant spectra that compose viral populations. As a consequence of interactions within mutant spectra, enhanced mutagenesis may lead to viral extinction, and this is currently investigated as a new antiviral strategy, termed virus entry into error catastrophe.

Foot-and-mouth disease virus evolution: exploring pathways towards virus extinction.

Foot-and-mouth disease virus (FMDV) is genetically and phenotypically variable. As a typical RNA virus, FMDV follows a quasispecies dynamics, with the many biological implications of such a dynamics. Mutant spectra provide a reservoir of FMDV variants, and minority subpopulations may become dominant in response to environmental demands or as a result of statistical fluctuations in population size. Accumulation of mutations in the FMDV genome occurs upon subjecting viral populations to repeated bottleneck events and upon viral replication in the presence of mutagenic base or nucleoside analogs. During serial bottleneck passages, FMDV survive during extended rounds of replication maintaining low average relative fitness, despite linear accumulation of mutations in the consensus genomic sequence. The critical event is the occurrence of a low frequency of compensatory mutations. In contrast, upon replication in the presence of mutagens, the complexity of mutant spectra increases, apparently no compensatory mutations can express their fitness-enhancing potential, and the virus can cross an error threshold for maintenance of genetic information, resulting in virus extinction. Low relative fitness and low viral load favor FMDV extinction in cell culture. The comparison of the molecular basis of resistance to extinction upon bottleneck passage and extinction by enhanced mutagenesis is providing new insights in the understanding of quasispecies dynamics. Such a comparison is contributing to the development of new antiviral strategies based on the transition of viral replication into error catastrophe.

Evidence for positive selection in the capsid protein-coding region of the foot-and-mouth disease virus (FMDV) subjected to experimental passage regimens.

We present sequence data from two genomic regions of foot-and-mouth disease virus (FMDV) subjected to several experimental passage regimens. Maximum-likelihood estimates of the nonsynonymous-to-synonymous rate ratio parameter (d(N)/d(S)) suggested the action of positive selection on some antigenic sites of the FMDV capsid during some experimental passages. These antigenic sites showed an accumulation of convergent amino acid replacements during massive serial cytolytic passages and also in persistent infections of FMDV in cell culture. This accumulation was most significant at the antigenic site A (the G-H loop of capsid VP1), which includes an Arg-Gly-Asp (RGD) cellular recognition motif. Our analyses also identified a subregion of VP3, part of the fivefold axis of FMDV particles, that also appeared to be subjected to positive selection of amino acid replacements. From these results, we can conclude that under the restrictive conditions imposed either by the presence of the monoclonal antibodies, by the persistent infections, or by the competition processes established between different variants of the viral population, amino acid replacement in some capsid-coding regions can be positively selected toward an increase of those mutants with a higher capability to infect the cell.

Memory in viral quasispecies.

Biological adaptive systems share some common features: variation among their constituent elements and continuity of core information. Some of them, such as the immune system, are endowed with memory of past events. In this study we provide direct evidence that evolving viral quasispecies possess a molecular memory in the form of minority components that populate their mutant spectra. The experiments have involved foot-and-mouth disease virus populations with known evolutionary histories. The composition and behavior of the viral population in response to a selective constraint were influenced by past evolutionary history in a way that could not be predicted from examination of consensus nucleotide sequences of the viral populations. The molecular memory of the viral quasispecies influenced both the nature and the intensity of the response of the virus to a selective constraint.

Genomic nucleotide sequence of a foot-and-mouth disease virus clone and its persistent derivatives. Implications for the evolution of viral quasispecies during a persistent infection.

The consensus nucleotide sequence of the entire genome of foot-and-mouth disease virus (FMDV) (biological clone C-S8c1) has been completed, and compared with that of two persistent derivatives R99 and R146, rescued after 99 and 146 passages of the carrier BHK-21 cells. Consensus sequences were determined directly from supernatants of persistently infected cells, without intervening cytolytic amplification of the viruses. These genomic sequences have also been compared with that of FMDV R100, a virus that was also rescued from persistently infected cells, but that was subjected to cytolytic amplification prior to sequencing. Mutation frequencies for R99 and R146 relative to C-S8c1 were in the range of 2.8x10(-3) to 7.7x10(-3) substitutions per nucleotide for the 5'-UTR and the L-, P1-, P2- and P3-coding regions. No mutations were fixed in the polymerase (3D)-coding region. Striking contrasts were noted regarding the distribution of mutation types along the persistent genomes, notably the complete absence of transversion mutations within the 5'-UTR, compared with 53% transversions in the L- and P1-coding regions. The sequencing results presented here, combined with previous sequences of FMDV C-S8c1 genomes at the onset of persistence, provide evidence of sequence fluctuations with a non-linear accumulation of mutations during prolonged persistence, a hallmark of quasispecies dynamics.

Lack of evolutionary stasis during alternating replication of an arbovirus in insect and mammalian cells.

The evolution of vesicular stomatitis virus (VSV) in a constant environment, consisting of either mammalian or insect cells, has been compared to the evolution of the same viral population in changing environments consisting in alternating passages in mammalian and insect cells. Fitness increases were observed in all cases. An initial fitness loss of VSV passaged in insect cells was noted when fitness was measured in BHK-21 cells, but this effect could be attributed to a difference of temperature during VSV replication at 37 degrees C in BHK-21 cells. Sequencing of nucleotides 1-4717 at the 3' end of the VSV genome (N, P, M and G genes) showed that at passage 80 the number of mutations accumulated during alternated passages (seven mutations) is similar or larger than that observed in populations evolving in a constant environment (two to four mutations). Our results indicate that insect and mammalian cells can constitute similar environments for viral replication. Thus, the slow rates of evolution observed in natural populations of arboviruses are not necessarily due to the need for the virus to compromise between adaptation to both arthropod and vertebrate cell types.

Multiple molecular pathways for fitness recovery of an RNA virus debilitated by operation of Muller's ratchet.

Repeated bottleneck passages of RNA viruses result in fitness losses due to accumulation of deleterious mutations. We have analysed the molecular events underlying fitness recovery of a highly debilitated foot- and-mouth disease virus (FMDV) clone, upon serial passage in BHK-21 cells. The debilitated clone included an unusual, internal polyadenylate extension preceding the second functional AUG initiation codon, and a number of additional mutations scattered throughout the genome. Comparison of entire genomic nucleotide sequences in the course of passaging documented that loss of the internal polyadenylate was the first event in the process of fitness recovery. Further increases of fitness were associated with very few true reversions and with the accumulation of additional mutations affecting non-coding and coding regions. Remarkably, four biological subclones of the same debilitated FMDV clone gained fitness through three separate molecular pathways regarding correction of the internal polyadenylate: (i) a true reversion to yield the wild-type sequence at the second functional AUG; (ii) a shortening of the internal polyadenylate tract; or (iii) a deletion of 69 residues spanning the site of the polyadenylate extension. The results document that an RNA virus can find multiple pathways to reach alternative high fitness peaks on the fitness landscape.

[Variability and development of viral populations: assessment and implications]. / Variabilité et evolution des populations virales: bilan et implications.

RNA virus populations consist of complex distributions of closely related but not identical genomes known as viral quasi-species. The quasi-species concept describes the dynamics of these genomes subjected to a continuous process of variation, competition, and selection. Quasi-species dynamics has broad implications not only in the understanding of the molecular mechanisms underlying adaptation of RNA viruses but also in the design of strategies for control and prevention of viral disease. Viral load and genetic heterogeneity have a determinant influence on the adaptation of RNA virus to their environment. Vaccines designed to control diseases caused by highly variable viruses must contain several B and T epitopes to provide an ample and diversified immune response. Similarly, antiviral drugs should be used in combination therapy to minimize selection of resistant viruses. The theoretical model of quasi-species has opened the way for new antiviral therapies based on augmentation of the mutation rate during replication of viral RNA. Finally the quasi-species concept provides the basis for defining the selective factors that could influence the evolution of RNA virus and promote the emergence or reemergence of viral diseases.

Quasispecies structure and persistence of RNA viruses.

Viral quasispecies are closely related (but nonidentical) mutant and recombinant viral genomes subjected to continuous genetic variation, competition, and selection. Quasispecies structure and dynamics of replicating RNA enable virus populations to persist in their hosts and cause disease. We review mechanisms of viral persistence in cells, organisms, and populations of organisms and suggest that the critical interplay between host and viral influences (including in some cases the quasispecies organization) is the main driving force for long-term survival of viruses in nature.

Rapid selection in modified BHK-21 cells of a foot-and-mouth disease virus variant showing alterations in cell tropism.

With persistent foot-and-mouth disease virus (FMDV) in BHK-21 cells, there is coevolution of the cells and the resident virus; the virulence of the virus for the parental BHK-21 cells is gradually increased, and the cells become partially resistant to FMDV. Here we report that variants of FMDV C3Arg/85 were selected in a single infection of partially resistant BHK-21 cells (termed BHK-Rb cells). Indirect immunofluorescence showed that the BHK-Rb cell population was heterogeneous with regard to susceptibility to C3Arg/85 infection. Infection of BHK-Rb cells with C3Arg/85 resulted in an early phase of partial cytopathology which was followed at 6 to 10 days postinfection by the shedding of mutant FMDVs, termed C3-Rb. The selected C3-Rb variants showed increased virulence for BHK-21 cells, were able to overcome the resistance of modified BHK-21 cells to infection, and had acquired the ability to bind heparin and to infect wild-type Chinese hamster ovary (CHO) cells. A comparison of the genomic sequences of the parental and modified viruses revealed only two amino acid differences, located at the surface of the particle, at the fivefold axis of the viral capsid (Asp-9-->Ala in VP3 and either Gly-110-->Arg or His-108-->Arg in VP1). The same phenotypic and genotypic modifications occurred in a highly reproducible manner; they were seen in a number of independent infections of BHK-Rb cells with viral preparation C3Arg/85 or with clones derived from it. Neither amino acid substitutions in other structural or nonstructural proteins nor nucleotide substitutions in regulatory regions were found. These results prove that infection of partially permissive cells can promote the rapid selection of virus variants that show alterations in cell tropism and are highly virulent for the same cells.

Population dynamics in the evolution of RNA viruses.

RNA virus quasispecies are subjected to processes of positive Darwinian selection, to a very active and continuous negative selection and to random genetic drift. The course of RNA virus evolution is often unpredictable, and recent results suggest that even highly conserved motifs, once regarded as essential for infectivity, may be rendered dispensable by singular evolutionary events. An immediate consequence of the quasispecies genetic organization of RNA viruses is a surprising ability to gain fitness once a minimal replication ability is established in a biological environment. The unique features of RNA genetics should not be underestimated since they are at the basis of the emergence of new viral diseases and of the current difficulties to control many diseases associated variable viruses.

Mutational analysis of discontinuous epitopes of foot-and-mouth disease virus using an unprocessed capsid protomer precursor.

An unprocessed capsid precursor (P1) of foot-and-mouth disease virus (FMDV) has been expressed in mammalian cells to study discontinuous epitopes involved in viral neutralization. Amino acid replacements found in virus-escape mutants were engineered in the P1 precursor by site-directed mutagenesis of the plasmid. In all cases the replacements abolished recognition of unprocessed P1 by the relevant monoclonal antibodies (MAbs), paralleling the effects of the corresponding substitutions in neutralization of infectious FMDV. Five capsid surface residues within the same discontinuous antigenic area that were never found replaced in escape mutants were also engineered in P1. None of the substitutions affected antibody recognition, suggesting that these residues were not directly involved in the interaction with the antibodies tested. The results validate site-directed mutagenesis of constructs encoding capsid precursors as an approach to probe the structure of viral discontinuous epitopes not amenable to analysis with synthetic peptides.

The foot-and-mouth disease RNA virus as a model in experimental phylogenetics.

Phylogenetic reconstruction methods are subject to two types of limitations: our knowledge about the true history of organisms and the gross simplification implied in the numerical simulation models of the relationships between them. In such a situation, experimental phylogenetics provides a way to assess the accuracy of the phylogenetic reconstruction methods. Nonetheless, this capacity is only feasible for organisms in which replication and mutation rates are high enough to provide valuable data. On the other hand, experimental phylogenetics also provides insights on the main evolutionary processes acting on viral variability under different population dynamics. Our study with the foot-and-mouth disease virus (FMDV) strongly suggests that the phylogenetic reconstruction methods can infer erroneous phylogenies due to nucleotide convergences between isolates belonging to different experimental lineages. We also point out that the diverse evolutionary mechanisms acting in different experimental dynamics generate alterations and change the frequencies of genetic variants, which can lead to the misinterpretation of the real evolutionary history.

Genetic lesions associated with Muller's ratchet in an RNA virus.

The molecular basis of Muller's ratchet has been investigated using the important animal pathogen foot-and-mouth disease virus (FMDV). Clones from two FMDV populations were subjected to serial plaque transfers (repeated bottleneck events) on host BHK-21 cells. Relative fitness losses were documented in 11 out of 19 clones tested. Small fitness gains were observed in three clones. One viral clone attained an extremely low plating efficiency, suggesting that accumulation of deleterious mutations had driven the virus near extinction. Nucleotide sequence analysis revealed unique genetic lesions in multiply transferred clones that had never been seen in FMDVs isolated in nature or subjected to massive infections in cell culture. In particular, a frequent internal polyadenylate extension has identified a mutational hot spot on the FMDV genome. Furthermore, amino acid residue substitutions in internal capsid sites which are severely restricted during FMDV evolution, amounted to half of capsid replacements in the transferred clones. In addition, a striking dominance of non-synonymous replacements fixed upon large population infections of FMDV was not observed upon serial plaque transfers. The nucleotide sequence of the entire genome of a severely debilitated clone suggests that very few mutations may be sufficient to drive FMDV near extinction. The results provide an account of the molecular basis of Muller's ratchet for an RNA virus, and insight into the types of genetic variants which populate the mutant spectra of FMDV quasispecies.

Long-term, large-population passage of aphthovirus can generate and amplify defective noninterfering particles deleted in the leader protease gene.

During serial undiluted passage of a clonal population of foot-and-mouth disease virus (FMDV C-S8c1) in BHK-21 cells, two species of defective RNA were generated and selected. Sequence analysis revealed that they included deletions within the L-coding region, and retained the correct reading frame for viral protein synthesis. These deleted RNAs directed the synthesis of capsid protein VP1, were packaged in particles sedimenting with standard virus, required homologous infectious helper virus in order to produce viral particles, but did not interfere with the replication of helper virus. While detection of defective particles in FMDV required more than 100 serial passages, once produced, these defective RNAs could be stably maintained upon further passages in the FMDV C-S8c1 quasispecies. Furthermore, a high fitness, monoclonal-antibody-resistant virus was able to replace the standard virus and support the amplification of the deleted particles. This is the first description of naturally occurring, defective particles of FMDV.

Basic concepts in RNA virus evolution.

A hallmark of RNA genomes is the error-prone nature of their replication and retrotranscription. The major biochemical basis of the limited replication fidelity is the absence of proofreading/repair and postreplicative error correction mechanisms that normally operate during replication of cellular DNA. In spite of this unique feature of RNA replicons, the dynamics of viral populations seems to follow the same basic principles that classical population genetics has established for higher organisms. Here we review recent evidence of the profound effects that genetic bottlenecks have in enhancing the deleterious effects of Muller's ratchet during RNA virus evolution. The validity of the Red Queen hypothesis and of the competitive exclusion principle for RNA viruses are viewed as the expected result of the highly variable and adaptable nature of viral quasispecies. Viral fitness, or ability to replicate infectious progeny, can vary a million-fold within short time intervals. Paradoxically, functional and structural studies suggest extreme limitations to virus variation. Adaptability of RNA viruses appears to be based on the occupation of very narrow portions of sequence space at any given time.

Large deletions in the 5'-untranslated region of foot-and-mouth disease virus of serotype C.

Nucleotide sequences of the 5'-untranslated region (5'-UTR), at the 3'-side of the poly C tract, have been compared for 21 isolates of foot-and-mouth disease virus (FMDV) of serotype C from Europe, South America and The Philippines. A deletion of 43 nucleotides is present in the European isolates as compared with most American isolates. A larger deletion of 86 nucleotides is present in some viruses from South America and The Philippines. These deletions include the loss of one or two pseudoknot structures predicted in this region of the 5'-UTR. In addition, multiple point mutations have allowed the derivation of a phylogenetic tree which defines a grouping of isolates very similar to that derived from the capsid gene sequences of the same viruses. The study provides evidence that deletion (or addition) events must be very frequent during evolution of FMDV type C, since viruses which are phylogenetically very closely related (they belong to the same tree branch) may differ in the presence or absence of these deletions. Implications for FMDV evolution are discussed.

Molecular evolution of aphthoviruses.

Aphthoviruses are an important group of animal pathogens. A combination of genetic and structural studies has revealed one of the main principles governing their evolution: severe limitations to variation imposed by functional and structural constraints, in conjunction with high mutation and recombination rates operating during genome replication. Evolution occurs by positive selection and random drift acting on complex quasispecies distributions. The mutant composition of a quasi-species (or mutant spectrum) is largely dictated by tolerance to nucleotide and amino acid substitutions in viral RNAs and proteins, which must remain functionally competent. We review recent evidence to support this proposal, and we suggest that similar concepts may apply to other RNA viruses as well.