Evolution of the connectivity and indispensability of a transferable gene: the simplicity hypothesis.

C T Jones, E Susko, J P Bielawski
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Abstract

Background: The number of interactions between a transferable gene or its protein product and genes or gene products native to its microbial host is referred to as connectivity. Such interactions impact the tendency of the gene to be retained by evolution following horizontal gene transfer (HGT) into a microbial population. The complexity hypothesis posits that the protein product of a transferable gene with lower connectivity is more likely to function in a way that is beneficial to a new microbial host compared to the protein product of a transferable gene with higher connectivity. A gene with lower connectivity is consequently more likely to be fixed in any microbial population it enters by HGT. The more recently proposed simplicity hypothesis posits that the connectivity of a transferable gene might increase over time within any single microbial population due to gene-host coevolution, but that differential rates of colonization of microbial populations by HGT in accordance with differences in connectivity might act to counter this and even reduce connectivity over time, comprising an evolutionary trade-off.

Results: We present a theoretical model that can be used to predict the conditions under which gene-host coevolution might increase or decrease the connectivity of a transferable gene over time. We show that the opportunity to enter new microbial populations by HGT can cause the connectivity of a transferable gene to evolve toward lower values, particularly in an environment that is unstable with respect to the function of the gene's protein product. We also show that a lack of such opportunity in a stable environment can cause the connectivity of a transferable gene to evolve toward higher values.

Conclusion: Our theoretical model suggests that the connectivity of a transferable gene can change over time toward higher values corresponding to a more sessile state of lower transferability or lower values corresponding to a more itinerant state of higher transferability, depending on the ecological milieu in which the gene exists. We note, however, that a better understanding of gene-host coevolutionary dynamics in natural microbial systems is required before any further conclusions about the veracity of the simplicity hypothesis can be drawn.

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可转移基因的连通性和不可或缺性的进化:简单性假说。
背景:可转移基因或其蛋白质产物与微生物宿主原生基因或基因产物之间相互作用的数量被称为连通性。这种相互作用影响了基因在水平基因转移(HGT)进入微生物种群后通过进化保留的趋势。复杂性假说认为,与具有更高连通性的可转移基因的蛋白质产物相比,具有较低连通性的可转移基因的蛋白质产物更有可能以有利于新微生物宿主的方式发挥作用。因此,连通性较低的基因更有可能在通过HGT进入的任何微生物群体中被固定。最近提出的简单性假说认为,由于基因与宿主的共同进化,可转移基因的连通性可能随着时间的推移而增加,但根据连通性的差异,HGT对微生物种群的不同定殖率可能会抵消这种情况,甚至随着时间的推移减少连通性,这包括进化权衡。结果:我们提出了一个理论模型,可以用来预测基因-宿主共同进化可能随着时间的推移增加或减少可转移基因的连通性的条件。我们表明,通过HGT进入新的微生物种群的机会可以导致可转移基因的连通性向较低的值进化,特别是在基因蛋白质产物功能不稳定的环境中。我们还表明,在稳定的环境中缺乏这样的机会会导致可转移基因的连通性向更高的值进化。结论:我们的理论模型表明,根据基因存在的生态环境,可转移基因的连通性可以随着时间的推移向更高的值变化,对应于更稳定的低可转移性状态,或更低的值对应于更流动的高可转移性状态。然而,我们注意到,在对简单性假设的准确性得出任何进一步的结论之前,需要更好地理解天然微生物系统中的基因-宿主共同进化动力学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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