Department of Biology, Stanford University, Stanford, CA 94305, USA.
Department of Physics, Stanford University, Stanford, CA 94305, USA.
Curr Biol. 2018 Feb 19;28(4):515-525.e6. doi: 10.1016/j.cub.2018.01.009. Epub 2018 Feb 8.
Few studies have "quantitatively" probed how adaptive mutations result in increased fitness. Even in simple microbial evolution experiments, with full knowledge of the underlying mutations and specific growth conditions, it is challenging to determine where within a growth-saturation cycle those fitness gains occur. A common implicit assumption is that most benefits derive from an increased exponential growth rate. Here, we instead show that, in batch serial transfer experiments, adaptive mutants' fitness gains can be dominated by benefits that are accrued in one growth cycle, but not realized until the next growth cycle. For thousands of evolved clones (most with only a single mutation), we systematically varied the lengths of fermentation, respiration, and stationary phases to assess how their fitness, as measured by barcode sequencing, depends on these phases of the growth-saturation-dilution cycles. These data revealed that, whereas all adaptive lineages gained similar and modest benefits from fermentation, most of the benefits for the highest fitness mutants came instead from the time spent in respiration. From monoculture and high-resolution pairwise fitness competition experiments for a dozen of these clones, we determined that the benefits "accrued" during respiration are only largely "realized" later as a shorter duration of lag phase in the following growth cycle. These results reveal hidden complexities of the adaptive process even under ostensibly simple evolutionary conditions, in which fitness gains can accrue during time spent in a growth phase with little cell division, and reveal that the memory of those gains can be realized in the subsequent growth cycle.
很少有研究“定量”探究适应性突变如何导致适应性增加。即使在简单的微生物进化实验中,完全了解潜在的突变和特定的生长条件,也很难确定在生长-饱和周期内,这些适应性增益发生在哪个阶段。一个常见的隐含假设是,大多数好处来自于指数增长速度的提高。在这里,我们反而表明,在分批连续传代实验中,适应性突变体的适应性增益可以由一个生长周期中积累的益处主导,但要在下一个生长周期才能实现。对于数千个进化后的克隆体(大多数只有一个突变),我们系统地改变了发酵、呼吸和静止阶段的长度,以评估它们的适应性,这是通过条形码测序来衡量的,它取决于生长-饱和-稀释周期的这些阶段。这些数据表明,虽然所有适应性谱系都从发酵中获得了相似且适度的益处,但对于最高适应性突变体来说,大多数益处来自呼吸阶段所消耗的时间。通过对十几个此类克隆体进行的单细胞培养和高分辨率的成对适应性竞争实验,我们确定了在呼吸过程中“积累”的益处只有在随后的生长周期中,由于迟滞期的持续时间缩短,才能“实现”。这些结果揭示了适应性过程的隐藏复杂性,即使在看似简单的进化条件下也是如此,在这些条件下,适应性增益可以在细胞分裂较少的生长阶段积累,并且这些增益的记忆可以在下一个生长周期中实现。