布奇内拉
生物
使负有责任或义务
寄主(生物学)
自然选择
遗传漂变
选择(遗传算法)
人口
基因组
遗传学
人口瓶颈
瓶颈
固定(群体遗传学)
进化生物学
共生细菌
传输(电信)
否定选择
平衡选择
共生
遗传变异
等位基因
基因
细菌
生态学
微卫星
电气工程
工程类
社会学
嵌入式系统
人口学
人工智能
计算机科学
作者
Julie Perreau,Bo Zhang,Gerald P. Maeda,Mark Kirkpatrick,Nancy A. Moran
标识
DOI:10.1073/pnas.2102467118
摘要
Numerous animal lineages have maternally inherited symbionts that are required for host reproduction and growth. Endosymbionts also pose a risk to their hosts because of the mutational decay of their genomes through genetic drift or to selfish mutations that favor symbiont fitness over host fitness. One model for heritable endosymbiosis is the association of aphids with their obligate bacterial symbiont, Buchnera We experimentally established heteroplasmic pea aphid matrilines containing pairs of closely related Buchnera haplotypes and used deep sequencing of diagnostic markers to measure haplotype frequencies in successive host generations. These frequencies were used to estimate the effective population size of Buchnera within hosts (i.e., the transmission bottleneck size) and the extent of within-host selection. The within-host effective population size was in the range of 10 to 20, indicating a strong potential for genetic drift and fixation of deleterious mutations. Remarkably, closely related haplotypes were subject to strong within-host selection, with selection coefficients as high as 0.5 per aphid generation. In one case, the direction of selection depended on the thermal environment and went in the same direction as between-host selection. In another, a new mutant haplotype had a strong within-host advantage under both environments but had no discernible effect on host-level fitness under laboratory conditions. Thus, within-host selection can be strong, resulting in a rapid fixation of mutations with little impact on host-level fitness. Together, these results show that within-host selection can drive evolution of an obligate symbiont, accelerating sequence evolution.
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