It has been well established that populations of RNA viruses transmitted throughout serial bottlenecks suffer from significant fitness declines as a consequence of the accumulation of deleterious mutations by the onset of Muller's ratchet. Bottlenecks are unavoidably linked to different steps of the infectious cycle of most plant RNA viruses, such as vector-mediated transmissions and systemic colonization of new leaves. Here we report evidence for fitness declines by the accumulation of deleterious mutations in the potyvirus Tobacco etch virus (TEV). TEV was inoculated into the nonsystemic host Chenopodium quinoa, and local lesions were isolated and used to initiate 20 independent mutation accumulation lineages. Weekly, a random lesion from each lineage was isolated and used to inoculate the next set of plants. At each transfer, the Malthusian growth rate was estimated. After 11 consecutive transfers, all lineages suffered significant fitness losses, and one even became extinct. The average rate of fitness decline was 5% per day. The average pattern of fitness decline was consistent with antagonistic epistasis between deleterious mutations, as postulated for antiredundant genomes. Temporal fitness fluctuations were not explained by random noise but reflected more complex underlying processes related to emergence and self-organization phenomena.Due to the lack of proofreading of their replicases, RNA viruses show the highest mutation rates in nature (12). For this reason, along with short generation times and large population sizes, RNA virus populations usually consist of highly heterogeneous mixtures known as quasispecies (11). In a defined environment, the mutant spectrum of a viral population is generally centered on one or several sequences that are fitter, but nonetheless often represent a minor proportion of the mutant distribution (11). Therefore, associated with the inherent stochasticity of transmission or tissue colonization events, viral populations are continuously regenerated from a few individual genomes, and, thus, a finite probability exists that the new population carries an increased mutational load relative to the most-fit members of the ancestral population. Repeated genetic bottleneck events followed by low-fidelity genome replication may lead to substantial fitness losses. In large populations, where purifying selection is a strong force, genomes carrying reversion or second-site compensatory mutations quickly increase in frequency. However, when the effective population size is small, compensatory mutations might not arise (3, 49). Muller (42) predicted that when mutation rates are high and population sizes small, this process occurs in an irreversible ratchet-like manner that leads to the gradual decrease of fitness in a population, particularly in asexual organisms (24). Indeed, the onset of Muller's ratchet further reduces population size, thus accelerating additional mutation accumulation and leading to extinction in a process known as mutational meltdown (23).The operation of Muller's...
