Idiosyncratic evolvability among single-point ribosomal mutants towards multi-aminoglycoside resistance
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Newly-arising mutations can impact not only fitness but also an organism’s capacity for further adaptation ( i.e. , its evolvability). Understanding what determines evolvability differences is of great interest from both fundamental and applied perspectives. A general pattern observed across multiple microbes is that evolvability tends to decline with genotype fitness ( i.e. , the "rule of declining adaptability"), typically attributed to epistatic rather than mutational differences among genotypes. Here, we investigate whether common rpsL point mutations in Escherichia coli , conferring streptomycin resistance, may potentiate or hinder adaptation towards secondary aminoglycosides. We find a version of the rule of declining adaptability in which initially more-fit genotypes experience higher effective beneficial mutation rates but smaller effect sizes than their less-fit counterparts. Genome sequencing reveals the ribosome and electron transport chain as primary targets for adaptation. Second-step mutations typically confer cross-resistance across aminoglycosides, and some even restore fitness costs in the absence of drugs. However, some genotypes deviate markedly from the overall pattern, being completely unable to develop resistance to the secondary aminoglycosides. Such idiosyncratic dead-ends, if common among other systems involving single-point mutants, would expand the pool of potential targets for strategies to promote evolutionary robustness in biotechnology and combat multidrug resistance in clinical microbiology.
Author Summary
Identifying features that predict an organism’s ability to evolve (evolvability) is highly desirable in fundamental and applied microbial genetics. Here we show that outstanding disparities in evolvability can arise from single-point variants within a single gene. Specifically, we investigated whether common streptomycin-resistance mutations can facilitate or hinder adaptation against other aminoglycosides. Most mutations facilitated resistance evolution, prompting further resistance gains in proportion to initial resistance levels. However, a few cases totally diverged from this trend, acting as evolutionary dead-ends. These findings suggest a scenario in which strong, unpredictable genetic interactions stand out against a backdrop of predictable trends, bearing implications for ongoing debates on which model best captures global fitness patterns in microbes. From an applied standpoint, since streptomycin is commonly used in mycobacterial infections and agriculture, our results suggest that some circulating pathogenic strains may already be predisposed to developing multi-aminoglycoside resistance, potentially informing surveillance and intervention strategies.
