Two-component signal transduction systems are the predominant means by which bacteria sense and respond to environmental stimuli. Bacteria often employ tens or hundreds of these paralogous signaling systems, comprised of histidine kinases (HKs) and their cognate response regulators (RRs). Faithful transmission of information through these signaling pathways and avoidance of detrimental crosstalk demand exquisite specificity of HK-RR interactions. To identify the determinants of two-component signaling specificity, we examined patterns of amino acid coevolution in large, multiple sequence alignments of cognate kinase-regulator pairs. Guided by these results, we demonstrate that a subset of the coevolving residues is sufficient, when mutated, to completely switch the substrate specificity of the kinase EnvZ. Our results shed light on the basis of molecular discrimination in two-component signaling pathways, provide a general approach for the rational rewiring of these pathways, and suggest that analyses of coevolution may facilitate the reprogramming of other signaling systems and protein-protein interactions.
Two-component signal transduction systems enable bacteria to sense and respond to a wide range of environmental stimuli. Sensor histidine kinases transmit signals to their cognate response regulators via phosphorylation. The faithful transmission of information through two-component pathways and the avoidance of unwanted cross-talk require exquisite specificity of histidine kinase-response regulator interactions to ensure that cells mount the appropriate response to external signals. To identify putative specificity-determining residues, we have analyzed amino acid coevolution in two-component proteins and identified a set of residues that can be used to rationally rewire a model signaling pathway, EnvZ-OmpR. To explore how a relatively small set of residues can dictate partner selectivity, we combined alanine-scanning mutagenesis with an approach we call trajectory-scanning mutagenesis, in which all mutational intermediates between the specificity residues of EnvZ and another kinase, RstB, were systematically examined for phosphotransfer specificity. The same approach was used for the response regulators OmpR and RstA. Collectively, the results begin to reveal the molecular mechanism by which a small set of amino acids enables an individual kinase to discriminate amongst a large set of highly-related response regulators and vice versa. Our results also suggest that the mutational trajectories taken by two-component signaling proteins following gene or pathway duplication may be constrained and subject to differential selective pressures. Only some trajectories allow both the maintenance of phosphotransfer and the avoidance of unwanted cross-talk.
An ability to sense and respond to changes in extracellular phosphate is critical for the survival of most bacteria. For Caulobacter crescentus, which typically lives in phosphate-limited environments, this process is especially crucial. Like many bacteria, Caulobacter responds to phosphate limitation through a conserved two-component signaling pathway called PhoR-PhoB, but the direct regulon of PhoB in this organism is unknown. Here we used chromatin immunoprecipitation-DNA sequencing (ChIP-Seq) to map the global binding patterns of the phosphate-responsive transcriptional regulator PhoB under phosphate-limited and -replete conditions. Combined with genome-wide expression profiling, our work demonstrates that PhoB is induced to regulate nearly 50 genes under phosphate-starved conditions. The PhoB regulon is comprised primarily of genes known or predicted to help Caulobacter scavenge for and import inorganic phosphate, including 15 different membrane transporters. We also investigated the regulatory role of PhoU, a widely conserved protein proposed to coordinate phosphate import with expression of the PhoB regulon by directly modulating the histidine kinase PhoR. However, our studies show that it likely does not play such a role in Caulobacter, as PhoU depletion has no significant effect on PhoB-dependent gene expression. Instead, cells lacking PhoU exhibit striking accumulation of large polyphosphate granules, suggesting that PhoU participates in controlling intracellular phosphate metabolism. IMPORTANCEThe transcription factor PhoB is widely conserved throughout the bacterial kingdom, where it helps organisms respond to phosphate limitation by driving the expression of a battery of genes. Most of what is known about PhoB and its target genes is derived from studies of Escherichia coli. Our work documents the PhoB regulon in Caulobacter crescentus, and comparison to the regulon in E. coli reveals significant differences, highlighting the evolutionary plasticity of transcriptional responses driven by highly conserved transcription factors. We also demonstrated that the conserved protein PhoU, which is implicated in bacterial persistence, does not regulate PhoB activity, as previously suggested. Instead, our results favor a model in which PhoU affects intracellular phosphate accumulation, possibly through the high-affinity phosphate transporter.
Mammary epithelial regeneration implies the existence of cellular progenitors with retained replicative capacity, prolonged lifespan and developmental potency. Evidence exists that DN-p63 isoforms preserve these features by modulating p53 activity in basal epithelia. DN-p63 mRNA levels decline at the onset of differentiation suggesting that its transcriptional regulation may contribute to the initiation of differentiation. To study transcriptional regulation of DN-p63, a 10.3 kbp fragment containing the DN-p63 promoter was isolated. We report here that DN-p63 is a positive and negative transcriptional target of p53 and DN-p63-a, respectively. Disruption of p53 activity or expression abolishes the expression of DN-p63-a. This regulation is mediated by a p53-binding element sufficient to confer these activities to a heterologous promoter. Chromatin immune-precipitation indicates that, in asynchronously growing cells, p53 occupies this element. In response to DNA damage, DN-p63-a is recruited to this element as transcription of DN-p63 declines. Disruption of DN-p63-a expression had differential effects on the transcriptional regulation of several p53-target genes. These findings indicate that p53 contributes to the preservation of basal epithelia by driving the expression of DN-p63 isoforms. These studies also suggest that in response to genotoxic stress, DN-p63-a mediates the silencing of its own promoter thereby altering the pattern of p53-target gene expression.
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