Multicellular eukaryotes demonstrate nongenetic, heritable phenotypic versatility in their adaptation to environmental changes. This inclusive inheritance is composed of interacting epigenetic, maternal, and environmental factors. Yet-unidentified maternal effects can have a pronounced influence on plant phenotypic adaptation to changing environmental conditions. To explore the control of phenotypy in higher plants, we examined the effect of a single plant nuclear gene on the expression and transmission of phenotypic variability in Arabidopsis (Arabidopsis thaliana). MutS HOMOLOG1 (MSH1) is a plant-specific nuclear gene product that functions in both mitochondria and plastids to maintain genome stability. RNA interference suppression of the gene elicits strikingly similar programmed changes in plant growth pattern in six different plant species, changes subsequently heritable independent of the RNA interference transgene. The altered phenotypes reflect multiple pathways that are known to participate in adaptation, including altered phytohormone effects for dwarfed growth and reduced internode elongation, enhanced branching, reduced stomatal density, altered leaf morphology, delayed flowering, and extended juvenility, with conversion to perennial growth pattern in short days. Some of these effects are partially reversed with the application of gibberellic acid. Genetic hemicomplementation experiments show that this phenotypic plasticity derives from changes in chloroplast state. Our results suggest that suppression of MSH1, which occurs under several forms of abiotic stress, triggers a plastidial response process that involves nongenetic inheritance.
RsaE is a regulatory RNA highly conserved amongst Firmicutes that lowers the amount of mRNAs associated with the TCA cycle and folate metabolism. A search for new RsaE targets in Staphylococcus aureus revealed that in addition to previously described substrates, RsaE down-regulates several genes associated with arginine catabolism. In particular, RsaE targets the arginase rocF mRNA via direct interactions involving G-rich motifs. Two duplicated C-rich motifs of RsaE can independently downregulate rocF expression. The faster growth rate of ΔrsaE compared to its parental strain in media containing amino acids as sole carbon source points to an underlying role for RsaE in amino acid catabolism. Collectively, the data support a model in which RsaE acts as a global regulator of functions associated with metabolic adaptation.
SummaryViroid infection is associated with the production of short interfering RNAs (siRNAs), a hallmark of posttranscriptional gene silencing (PTGS). However, viroid RNAs autonomously replicating in the nucleus have not been shown to trigger the degradation of homologous RNA in the cytoplasm. To investigate the potential of viroids for the induction of gene silencing, non-infectious fragments of potato spindle tuber viroid (PSTVd) cDNA were transcriptionally fused to the 3 H end of the green¯uorescent protein (GFP)-coding region. Introduction of such constructs into tobacco plants resulted in stable transgene expression. Upon PSTVd infection, transgene expression was suppressed and partial de novo methylation of the transgene was observed. PSTVd-speci®c siRNA was detected but none was found corresponding to the gfp gene. Methylation was restricted almost entirely to the PSTVd-speci®c part of the transgene. Neither a gfp transgene construct lacking viroid-speci®c elements was silenced nor was de novo methylation detected, when it was introduced into the genetic background of the PSTVd-infected plant lines containing silenced GFP:PSTVd transgenes. The absence of gfp-speci®c siRNAs and of signi®cant methylation within the gfp-coding region demonstrated that neither silencing nor DNA methylation spread from the initiator region into adjacent 5 H regions.
Macrophage-derived nitric oxide (NO·) is a crucial effector against invading pathogens. Yet, paradoxically, several bacterial species, including some pathogens, are known to endogenously produce NO· via nitric oxide synthase (NOS) activity, despite its apparent cytotoxicity. Here, we reveal a conserved role for bacterial NOS in activating aerobic respiration. We demonstrate that nitrite generated from endogenous NO· decomposition stimulates quinol oxidase activity in Staphylococcus aureus and increases the rate of cellular respiration. This not only supports optimal growth of this organism but also prevents a dysbalance in central metabolism. Further, we also show that activity of the SrrAB two-component system alleviates the physiological defects of the nos mutant. Our findings suggest that NOS and SrrAB constitute two distinct but functionally redundant routes for controlling staphylococcal respiration during aerobic growth.
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