Fitness increase of memory genomes in a viral quasispecies

Viral quasispecies may contain a subset of minority genomes that reflect those genomic sequences that were dominant at an early phase of quasispecies evolution. Such minority genomes are referred to as memory in viral quasispecies. A memory marker previously characterized in foot-and-mouth disease virus (FMDV) is an internal oligoadenylate tract of variable length that became dominant upon serial plaque-to-plaque transfers of FMDV clones. During large population passages, genomes with internal oligoadenylate were outcompeted by wild-type revertants but remained in the mutant spectra as memory genomes. Here, we report a quantification of relative fitness of several FMDV clones, harboring internal oligoadenylate tracts of different length, and that were retrieved at early or late times (passage number) after implementation of memory. The results show that for any given length range of the oligoadenylate, maintenance in memory resulted in an increase in relative fitness, comparable to the increase undergone by the entire population. The fitness increase is in agreement with the Red Queen hypothesis, and implies a replicative memory mechanism. Thus, permanence of memory genomes may be a source of high fitness variants despite their initial low fitness, and despite having remained hidden in mutant spectra. This reinforces the interest of diagnosing minority genomes during chronic human and animal viral infections. © 2004 Elsevier Ltd. All rights reserved.This work was supported by grants BMC 2001-1823-C02-01, CAM 08.2/0046.1/2000, and CAM 08.2/0015/2001.1, and by Fundación Ramón Areces. A.A. and C.M.R.-J. were supported by predoctoral fellowships from CAM

Variabilité et evolution des populations virales: bilan et implications

National audienceRNA 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.Work in Madrid was supported by grants DGICYT PB94-0034-C02-01, DGES PM97-0060-C02-01, FIS 98/0054-01, Comunidad Autónoma de Madrid, and Fundación Ramón Areces

Evolution of Cell Recognition by Viruses: A Source of Biological Novelty with Medical Implications

Peer Reviewe

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

An RNA virus can adapt to the multiplicity of infection

International audienceRNA 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

Duration and fitness dependence of quasispecies memory

The duration and fitness dependence of memory in viral quasispecies evolving in cell culture have been investigated using two genetic markers of foot-and-mouth disease virus (FMDV). In lineages of antigenic variant FMDV RED, which reverted to FMDV RGD, memory FMDV RED genomes were detected after 50 infectious cycles, and memory level was fitness dependent. In growth-competition experiments between a reference FMDV RGD and two different FMDV RED populations, a 7.6-fold higher fitness of the initial FMDV RED population resulted in 30 to 100-fold higher memory level. In lineages of low-fitness clones containing an elongated internal polyadenylate tract, revertants lacking excess adenylate residues became dominant by passage 20. However, genomes including a larger number of adenylate residues were detected as memory genomes after at least 150 infectious cycles. Thus, quasispecies memory can be durable and is fitness dependent, as predicted from the growth competition of two mutant forms of a genome. An understanding of factors influencing quasispecies memory levels and duration may have implications for the extended diagnosis of viruses based on the quantification of minority genomes. © 2002 Academic Press.Work at CBMSO was supported by grants PM97-0060-C02-01, CAM 08.2/0046/2000, and Fundación Ramón Areces. Work at CAB was supported by the EU and INTA. C.M.R-J. and A.A. were supported by fellowships from Comunidad Autónoma de Madrid

Duration and fitness dependence of quasispecies memory

International audienceThe duration and fitness dependence of memory in viral quasispecies evolving in cell culture have been investigated using two genetic markers of foot-and-mouth disease virus (FMDV). In lineages of antigenic variant FMDV RED, which reverted to FMDV RGD, memory FMDV RED genomes were detected after 50 infectious cycles, and memory level was fitness dependent. In growth-competition experiments between a reference FMDV RGD and two different FMDV RED populations, a 7.6-fold higher fitness of the initial FMDV RED population resulted in 30 to 100-fold higher memory level. In lineages of low-fitness clones containing an elongated internal polyadenylate tract, revertants lacking excess adenylate residues became dominant by passage 20. However, genomes including a larger number of adenylate residues were detected as memory genomes after at least 150 infectious cycles. Thus, quasispecies memory can be durable and is fitness dependent, as predicted from the growth competition of two mutant forms of a genome. An understanding of factors influencing quasispecies memory levels and duration may have implications for the extended diagnosis of viruses based on the quantification of minority genomes