Dietary restriction (DR) increases life-span in organisms from yeast to mammals, presumably by slowing the accumulation of aging-related damage. Here we show that in Drosophila, DR extends life-span entirely by reducing the short-term risk of death. Two days after the application of DR at any age for the first time, previously fully fed flies are no more likely to die than flies of the same age that have been subjected to long-term DR. DR of mammals may also reduce short-term risk of death, and hence DR instigated at any age could generate a full reversal of mortality.
SummarySeveral members of the two-component signal transduction family have been implicated in the control of polar development in Caulobacter crescentus : PleC and DivJ, two polarly localized histidine sensor kinases; and the response regulators DivK and PleD. The PleD protein was shown previously to be required during the swarmer-to-stalked cell transition for flagellar ejection and efficient stalk biogenesis. Here, we present data indicating that PleD also controls the onset of motility and a cell density switch immediately preceding cell division. Constitutively active alleles of pleD or wspR , an orthologue from Pseudomonas fluorescens , almost completely suppressed C. crescentus motility and inhibited the increase in swarmer cell density during cell differentiation. The observation that these alleles also had a dominant-negative effect on motility in a pleC divJ and a pleC divK mutant background indicated that PleD is located downstream of the other components in the signal transduction cascade, which controls the activity of the flagellar motor. In addition, the presence of a constitutive pleD or wspR allele resulted in a doubling of the average stalk length. Together, this is consistent with a model in which the active form of PleD, PleD ~ P, negatively controls aspects of differentiation in the late predivisional cell, whereas it acts positively on polar development during the swarmer-to-stalked cell transition. In agreement with such a model, we found that DivJ, which localizes to the stalked pole during cell differentiation, positively controlled the in vivo phosphorylation status of PleD, and the swarmer pole-specific PleC kinase modulated this status in a negative manner. Furthermore, domain switch experiments demonstrated that the WspR GGDEF output domain from P. fluorescens is active in C. crescentus , favouring a more general function for this novel signalling domain over a specific role such as DNA or protein interaction. Possible roles for PleD and its Cterminal output domain in modulating the polar cell surface of C. crescentus are discussed.
Wrinkly spreader (WS) genotypes evolve repeatedly in model Pseudomonas populations undergoing adaptive radiation. Previous work identified genes contributing to the evolutionary success of WS. Here we scrutinize the GGDEF response regulator protein WspR and show that it is both necessary and sufficient for WS. Activation of WspR occurs by phosphorylation and different levels of activation generate phenotypic differences among WS genotypes. Five alleles of wspR, each encoding a protein with a single amino acid substitution, were generated by mutagenesis. Two alleles are constitutively active and cause the ancestral genotype to develop a WS phenotype; the phenotypic effects are allele specific and independent of phosphorylation. Three alleles contain changes in the GGDEF domain and when overexpressed in WS cause reversion to the ancestral phenotype. Ability to mimic this effect by overexpression of a liberated N-terminal domain shows that in WS, regulatory components upstream of WspR are overactive. To connect changes at the nucleotide level with fitness, the effects of variant alleles were examined in both structured and unstructured environments: alleles had adaptive and deleterious effects with trade-offs evident across environments. Despite the proclivity of mutations within wspR to generate WS, sequence analysis of wspR from 53 independently obtained WS showed no evidence of sequence change in this gene.
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