Genomic and phenotypic evolution of Escherichia coli in a novel citrate-only resource environment

Evolutionary innovations allow populations to colonize new ecological niches. We previously reported that aerobic growth on citrate (Cit+) evolved in an Escherichia coli population during adaptation to a minimal glucose medium containing citrate (DM25). Cit+ variants can also grow in citrate-only medium (DM0), a novel environment for E. coli. To study adaptation to this niche, we founded two sets of Cit+ populations and evolved them for 2500 generations in DM0 or DM25. The evolved lineages acquired numerous parallel mutations, many mediated by transposable elements. Several also evolved amplifications of regions containing the maeA gene. Unexpectedly, some evolved populations and clones show apparent declines in fitness. We also found evidence of substantial cell death in Cit+ clones. Our results thus demonstrate rapid trait refinement and adaptation to the new citrate niche, while also suggesting a recalcitrant mismatch between E. coli physiology and growth on citrate.

A Comparison of the Costs and Benefits of Bacterial Gene Expression

To study how a bacterium allocates its resources, we compared the costs and benefits of most of the proteins inEscherichia coliK-12 during growth in minimal glucose medium. Proteins that are important for fitness are usually highly expressed, and 95% of these proteins are expressed at above 13 parts per million (ppm). Conversely, proteins that do not measurably benefit the host tend to be weakly expressed, with a median expression of 13 ppm. In aggregate, genes with no detectable benefit account for 31% of protein production, or about 22% if we correct for genetic redundancy. Although some of the apparently unnecessary expression could have subtle benefits in minimal glucose medium, the majority of the burden is due to genes that are important in other conditions. We propose that over 10% of the cell’s protein is “on standby” in case conditions change.

Induction of the Sugar-Phosphate Stress Response Allows Saccharomyces cerevisiae 2-Methyl-4-Amino-5-Hydroxymethylpyrimidine Phosphate Synthase To Function in Salmonella enterica

ABSTRACTThiamine pyrophosphate is a required cofactor for all forms of life. The pyrimidine moiety of thiamine, 2-methyl-4-amino-5-hydroxymethylpyrimidine phosphate (HMP-P), is synthesized by different mechanisms in bacteria and plants compared to fungi. In this study,Salmonella entericawas used as a host to probe requirements for activity of the yeast HMP-P synthase, Thi5p. Thi5p synthesizes HMP-P from histidine and pyridoxal-5-phosphate and was reported to use a backbone histidine as the substrate, which would mean that it was a single-turnover enzyme. Heterologous expression of Thi5p did not complement anS. entericaHMP-P auxotroph during growth with glucose as the sole carbon source. Genetic analyses described here showed that Thi5p was activated inS. entericaby alleles ofsgrRthat induced the sugar-phosphate stress response. Deletion ofptsG(encodes enzyme IICB [EIICB] of the phosphotransferase system [PTS]) also allowed function of Thi5p and requiredsgrRbut notsgrS.This result suggested that the role ofsgrSin activation of Thi5p was to decrease PtsG activity. In total, the data herein supported the hypothesis that one mechanism to activate Thi5p inS. entericagrown on minimal medium containing glucose (minimal glucose medium) required decreased PtsG activity and an unidentified gene regulated by SgrR.IMPORTANCEThis work describes a metabolic link between the sugar-phosphate stress response and the yeast thiamine biosynthetic enzyme Thi5p when heterologously expressed inSalmonella entericaduring growth on minimal glucose medium. Suppressor analysis (i) identified a mutant class of the regulator SgrR that activate sugar-phosphate stress response constitutively and (ii) determined that Thi5p is conditionally active inS. enterica. These results emphasized the power of genetic systems in model organisms to uncover enzyme function and underlying metabolic network structure.

Functional Genomics: Expression Analysis ofEscherichia coli Growing on Minimal and Rich Media

ABSTRACT DNA arrays of the entire set of Escherichia coli genes were used to measure the genomic expression patterns of cells growing in late logarithmic phase on minimal glucose medium and on Luria broth containing glucose. Ratios of the transcript levels for all 4,290E. coli protein-encoding genes (cds) were obtained, and analysis of the expression ratio data indicated that the physiological state of the cells under the two growth conditions could be ascertained. The cells in the rich medium grew faster, and expression of the majority of the translation apparatus genes was significantly elevated under this growth condition, consistent with known patterns of growth rate-dependent regulation and increased rate of protein synthesis in rapidly growing cells. The cells grown on minimal medium showed significantly elevated expression of many genes involved in biosynthesis of building blocks, most notably the amino acid biosynthetic pathways. Nearly half of the known RpoS-dependent genes were expressed at significantly higher levels in minimal medium than in rich medium, and rpoS expression was similarly elevated. The role of RpoS regulation in these logarithmic phase cells was suggested by the functions of the RpoS dependent genes that were induced. The hallmark features of E. coli cells growing on glucose minimal medium appeared to be the formation and excretion of acetate, metabolism of the acetate, and protection of the cells from acid stress. A hypothesis invoking RpoS and UspA (universal stress protein, also significantly elevated in minimal glucose medium) as playing a role in coordinating these various aspects and consequences of glucose and acetate metabolism was generated. This experiment demonstrates that genomic expression assays can be applied in a meaningful way to the study of whole-bacterial-cell physiology for the generation of hypotheses and as a guide for more detailed studies of particular genes of interest.