Distinct Long- and Short-Term Adaptive Mechanisms in Pseudomonas aeruginosa.

Heterogeneous environments such as the chronically infected cystic fibrosis lung drive the diversification of Pseudomonas aeruginosa populations into, e.g., mucoid, alginate-overproducing isolates or small-colony variants (SCVs). In this study, we performed extensive genome and transcriptome profiling on a clinical SCV isolate that exhibited high cyclic diguanylate (c-di-GMP) levels and a mucoid phenotype. We observed a delayed, stepwise decrease of the high levels of c-di-GMP as well as alginate gene expression upon passaging the SCV under noninducing, rich medium growth conditions over 7 days. Upon prolonged passaging, this lagging reduction of the high c-di-GMP levels under noninducing planktonic conditions (reminiscent of a hysteretic response) was followed by a phenotypic switch to a large-colony morphology, which could be linked to mutations in the Gac/Rsm signaling pathway. Complementation of the Gac/Rsm signaling-negative large-colony variants with a functional GacSA system restored the SCV colony morphotype but was not able to restore the high c-di-GMP levels of the SCV. Our data thus suggest that expression of the SCV colony morphotype and modulation of c-di-GMP levels are genetically separable and follow different evolutionary paths. The delayed switching of c-di-GMP levels in response to fluctuating environmental conditions might provide a unique opportunity to include a time dimension to close the gap between short-term phenotypic and long-term genetic adaptation to biofilm-associated growth conditions. IMPORTANCE Extreme environments, such as those encountered during an infection process in the human host, make effective bacterial adaptation inevitable. While bacteria adapt individually by activating stress responses, long-term adaptation of bacterial communities to challenging conditions can be achieved via genetic fixation of favorable traits. In this study, we describe a two-pronged bacterial stress resistance strategy in the opportunistic pathogen Pseudomonas aeruginosa. We show that the production of adjusted elevated c-di-GMP levels, which drive protected biofilm-associated phenotypes in vivo, resembles a stable hysteretic response which prevents unwanted frequent switching. Cellular hysteresis might provide a link between individual adaptability and evolutionary adaptation to ensure the evolutionary persistence of host-adapted stress response strategies.

Glucosyltransferase-dependent and -independent effects of TcdB on the proteome of HEp-2 cells.

Toxin B (TcdB) of the nosocomial pathogen C. difficile has been reported to exhibit a glucosyltransferase-dependent and -independent effect on treated HEp-2 cells at toxin concentration above 0.3 nM. In order to investigate and further characterize both effects epithelial cells were treated with wild type TcdB and glucosyltransferase-deficient TcdBNXN and their proteomes were analyzed by LC-MS. Triplex SILAC labeling was used for quantification. Identification of 5212 and quantification of 4712 protein groups was achieved. Out of these 257 were affected by TcdB treatment, 92 by TcdBNXN treatment and 49 by both. TcdB mainly led to changes in proteins that are related to "GTPase mediated signaling" and the "cytoskeleton" while "chromatin" and "cell cycle" related proteins were altered by both, TcdB and TcdBNXN . The obtained dataset of HEp-2 cell proteome helps us to better understand glucosyltransferase-dependent and -independent mechanisms of TcdB and TcdBNXN , particularly those involved in pyknotic cell death. All proteomics data have been deposited in the ProteomeXchange with the dataset identifier PXD006658 (https://proteomecentral.proteomexchange.org/dataset/PXD006658).

Toxin A of the nosocomial pathogen Clostridium difficile induces primary effects in the proteome of HEp-2 cells.

PURPOSE: This study was carried out to investigate the impact of high concentrations of Clostridium difficile toxin A (TcdA) on the proteome of human cells. It should also be examined whether a catalytically deficient mutant (TcdANXN ) has an effect on target cells. EXPERIMENTAL DESIGN: Proteome changes were investigated after treatment of HEp-2 cells with 20 nM TcdA for 8 h using a triplex SILAC labeling method and shotgun proteomics. Proteins from differently labeled and treated cells were combined for analysis using an HPLC coupled to an Orbitrap mass spectrometer. RESULTS: Nearly 4000 proteins were identified in each replicate and 3500 could be quantified by SILAC triplicate analysis. 51 proteins exhibited an altered abundance with 29 up-regulated and 22 down-regulated proteins. In contrast, TcdANXN had no provable impact on the protein profile of HEp-2 cells. Data analysis of regulated proteins revealed that mainly plasma membrane, cell death, cell proliferation and actin cytoskeleton proteins were affected by TcdA treatment. CONCLUSIONS AND CLINICAL RELEVANCE: This proteome analysis showed novel insights of TcdA impact onepithelial cells. Comparison with long-term treatment studies reveals distinctions in affected cellular processes that will improve the understanding of TcdA functions and might help to find new tools for diagnosis and treatment of CDI.