Gema Gómez-Mariano

Preextinction Viral RNA Can Interfere with Infectivity

ABSTRACT When the error rate during the copying of genetic material exceeds a threshold value, the genetic information cannot be maintained. This concept is the basis of a new antiviral strategy termed lethal mutagenesis or virus entry into error catastrophe. Critical for its success is preventing survival of residual infectious virus or virus mutants that escape the transition into error catastrophe. Here we document that mutated, preextinction foot-and-mouth disease virus (FMDV) RNA can interfere with and delay viral production up to 30 h when cotransfected in BHK-21 cells with standard RNA. Interference depended on the physical integrity of preextinction RNA and was not observed with unrelated RNAs or with nonmutated, defective FMDV RNA. These results suggest that this type of interference requires large size, preextinction FMDV RNA and is mediated neither by small interfering RNAs nor by RNAs that can compete with infectious RNA for host cell factors. A model based on the aberrant expression of mutated RNA as it is expected to occur in the initial stages of the transition into error catastrophe is proposed. Interference mediated by preextinction RNA indicates an advantage of mutagenesis versus inhibition in preventing the survival of virus escape mutants during antiviral treatments.

Evidence for quasispecies distributions in the human hepatitis A virus genome.

Nucleotide sequence analysis of multiple molecular clones of the hepatitis A virus (HAV), generated by reverse transcription-PCR of two capsid-coding regions, revealed a degree of heterogeneity compatible with a quasispecies structure in three clinical samples. Passage of plaque-purified reference strain HAV pHM175 43c in FRhK-4 cells documented the generation of a mutant distribution of HAV genomes. The mutant spectra showed mutation frequencies in the range of 1 x 10(-3) to 1 x 10(-4) substitutions per nucleotide, with a dominance of transition over transversion mutations. While in the VP3-coding region, nonsynonymous mutations were predominant; in the VP1-coding region they were uncommon. Around 50% of the amino acid replacements involved residues located at or near antigenic sites. Most of the detected mutations occurred at or in the vicinity of rare codons, suggesting a dynamics of mutation-selection, predominantly at and around rare codons. The results indicate that despite antigenic conservation, HAV replicates as a complex distribution of mutants, a feature of viral quasispecies.

Mutagenesis-Induced, Large Fitness Variations with an Invariant Arenavirus Consensus Genomic Nucleotide Sequence

ABSTRACT Enhanced mutagenesis may result in RNA virus extinction, but the molecular events underlying this process are not well understood. Here we show that 5-fluorouracil (FU)-induced mutagenesis of the arenavirus lymphocytic choriomeningitis virus (LCMV) resulted in preextinction populations whose consensus genomic nucleotide sequence remained unaltered. Furthermore, fitness recovery passages in the absence of FU, or alternate virus passages in the presence and absence of FU, led to profound differences in the capacity of LCMV to produce progeny, without modification of the consensus genomic sequence. Molecular genetic analysis failed to produce evidence of hypermutated LCMV genomes. The results suggest that low-level mutagenesis to enrich the viral population with defector, interfering genomes harboring limited numbers of mutations may mediate the loss of infectivity that accompanies viral extinction.

An RNA virus can adapt to the multiplicity of infection

RNA viruses evolve as complex distributions of mutants termed viral quasispecies. For this reason it is relevant to explore those environmental parameters that favour the selective advantage of some viral subpopulations over others. In the present study we provide direct evidence that the relative fitness of two competing viral subpopulations may depend on the multiplicity of infection (m.o.i.). Two closely related subpopulations of foot-and-mouth disease virus (FMDV) of serotype C, which differed in their history of cytolytic passages in BHK-21 cells, were subjected to growth-competition experiments in BHK-21 cells. One of the populations, termed S, was found to have a selective advantage over the other population, termed L, only when the competition passages were carried out at low m.o.i. In contrast, both populations, L and S, coexisted during serial passages carried out at high m.o.i. No differences between S and L were detected in assays of inhibition of infectivity by synthetic peptides, in cell binding-competition experiments, or in virulence for BHK-21 cells. However, FMDV S displayed increased heparin binding compared with L, and L higher virulence for Chinese hamster ovary (CHO) cells than S. These results with FMDV suggest that small differences in the interaction of the virus with the host cell may contribute to an m.o.i.-dependent selective advantage of one viral subpopulation over a closely related subpopulation. Therefore, different viral mutants from quasispecies replicating in vivo may be selected depending on the number of variant viruses relative to the number of susceptible cells.

Antigenic properties and population stability of a foot-and-mouth disease virus with an altered Arg-Gly-Asp receptor-recognition motif

The antigenic properties and genetic stability of a multiply passaged foot-and-mouth disease virus (FMDV) clone C-S8c1 with an Arg-Gly-Gly triplet (RGG) instead of the Arg-Gly-Asp (RGD) integrin-recognition motif at positions 141 to 143 of capsid protein VP1 are described. Clear antigenic differences between FMDV RGG and clone C-S8c1 have been documented in ELISA, enzyme-linked immunoelectrotransfer (Western) blot and neutralization assays using site A-specific monoclonal antibodies and anti-FMDV polyclonal antibodies from swine and guinea pigs. The results validate with a live virus the role of the RGD (in particular Asp-143) in recognition of (and neutralization by) antibodies, a role previously suggested by immunochemical and structural studies with synthetic peptides. The FMDV RGG was genetically stable in a large proportion of serial infections of BHK-21 cells. However, a revertant virus with RGD was generated in one out of six passage series. Interestingly, this revertant FMDV did not reach dominance but established an equilibrium with its parental FMDV RGG, accompanied by an increase of quasispecies complexity at the sequences around the RGG triplet. FMDV RGG exhibited a selective disadvantage relative to other RGD-containing clones isolated from the same parental FMDV population. The results suggest that large antigenic variations can be prompted by replacements at critical capsid sites, including those involved in receptor recognition. These critical replacements may yield viruses whose stability allows them to replicate efficiently and to expand the sequence repertoire of an antigenic site.

Dynamics of dominance of a dipeptide insertion in reverse transcriptase of HIV-1 from patients subjected to prolonged therapy.

A small proportion (0.8%) of individuals of a cohort of HIV-1 infected patients subjected to prolonged therapy with nucleoside analogues included a recently recognised dipeptide insertion in their RT (Ser-Ser or Ser-Gly between RT codons 69 and 70). To study the dynamics of dominance of genomes with this genetic change, sequential HIV-1 isolates from two patients were analyzed with regard to consensus sequences and complexity of mutant spectra. The two patients displayed completely different, complex evolutionary patterns leading to temporary dominance of dipeptide insertions. In one patient, a virus very closely related to an ancestor virus from the same patient overtook the population at late times, displacing genomes encoding a Ser-Ser insertion. In another patient the sequential dominance of genomes with Ser-Ser insertion-->no insertion-->Ser-Gly insertion was observed. These three types of genomes coexisted in the mutant spectrum of one HIV-1 isolate. Complexity was also reflected in the shape of phylogenetic trees derived with genomes from the mutant spectrum at each time point. The results suggest that HIV-1 genomes encoding a dipeptide insertion between RT codons 69 and 70 do not show a clear selective advantage over other genomes lacking the insertion. Such an absence of a clear selective advantage will favor that such genomes encoding this RT insertion become dominant only in a transient fashion, and following disparate kinetics in different patients.