Project description:In plants and fungi, the plasma membrane proton pump (H+-ATPase) establishes an electrochemical gradient across the plasma membrane which serves as the driving force for the secondary transport of ions and nutrients across the cell membrane. This is an essential enzyme that functions in many important processes including stomatal movement, cell elongation, and cellular responses to stimuli from hormones, light, and other environmental conditions. Therefore, understanding how the activity of the H+-ATPase is regulated is important to understand how plants adapt to different growth conditions. The autoinhibitory effect of the C- terminal regulatory domain of H+-ATPase is well established and is thought to be mediated by interactions with the catalytic domains. Here, using the lysine reactive mass spectrometry cleavable crosslinker DSSO, we found that the C-terminal domain of the Arabidopsis H+- ATPase 2 (AHA2) crosslinked extensively with the actuator, nucleotide-binding, and phosphorylation domains, suggesting that the C-terminal domain regulates the catalytic cycle by modulating the relative positions of these domains. Interestingly, several C-terminal crosslinks occurred near a predicted proton binding site (Asp-684 in TM6), suggesting that the C-terminal domain may regulate proton efflux. Additionally, crosslinks between the C-terminal domain and other domains of AHA2 were detected in a monomeric protein resolved on SDS-PAGE, suggesting that intramolecular interactions may also be involved in the regulation of enzyme activity. Finally, we observed mixed-isotope crosslinking between unlabeled (14N-AHA2) and labeled (15N-AHA2) between the C-terminal domain and other domains of AHA2, supporting our model that oligomeric H+-ATPase may autoinhibit the neighboring monomer in a “head to tail” configuration.

Project description:We have created a synthetic crosslinked peptide library to benchmark crosslinking mass spectrometry search engines. The unique benefit of the library is knowing which identified crosslinks are true and which are false. The data collected from mass spectrometry measurements of the peptide library were used to assess the most frequently used search algorithms. The datasets included will provide an important resource for the crosslinking community to evaluate and optimise search engines, results from which have far-reaching implications.

Project description:We compared transcriptomes of wild-type and ∆vanS strains of Clostridioides difficile 630 growing in the presence or absence of peptidoglycan-targeting antibiotics, vancomycin or ramoplanin. VanS is a histidine kinase of a two-component system that regulates expression of the vancomycin-induced vanG operon.

Project description:Clostridium difficile is the leading cause of antibiotic associated diarrhea in adults. During infection, the bacteria must rapidly respond and adapt to the host environment by being able to activate survival strategies. Ser/Thr kinases (STKs) are involved in signal transduction and regulate numerous physiological processes. PrkC of C. difficile is STK with two PASTA domains. We showed that this protein was membrane associated and localized at the septum. We observed that prkC deletion affects the cell morphology with an increased mean size, heterogeneity in length and the presence of abnormal septa. A ∆prkC mutant was able to sporulate and germinate but had a reduced motility and formed more biofilms than the wild-type strain. Moreover, a ∆prkC mutant showed an increased sensitivity to antimicrobial compounds targeting the envelope such as deoxycholate, a secondary bile salt, cephalosporins acting on peptidoglycan synthesis, cationic antimicrobial peptides and lysozyme. This increased susceptibility was not associated to differences in the structure of peptidoglycan or of polysaccharide II (PSII). A proteomic study showed that the majority of C. difficile proteins associated to the cell wall are less abundant in the ∆prkC mutant compared to the WT strain. Finally, the ∆prkC mutant presented a delay in gut establishment in a hamster model of infection while its virulence was not significantly affected.

Project description:Gram negative bacteria are surrounded by the cell envelope, a structure comprised of an outer membrane (OM) and an inner membrane (IM). These two membranes delimit the periplasmic space, a compartment containing the peptidoglycan (PG), a giant polymer surrounding the cell and functioning as an extracytoplasmic skeleton. In the model organism Escherichia coli, covalently anchoring the OM to the peptidoglycan is crucial for envelope integrity. When attachment is prevented, the OM forms blebs and detaches from the cell body. Intriguingly, the only bacterial protein known to covalently attach the OM to the PG (the Braun lipoprotein or Lpp) is present in a small number of γ-proteobacteria, raising the question of OM-PG attachment in other species. Here, we show that in -proteobacteria Brucella abortus and Agrobacterium tumefaciens, the OM is attached to the peptidoglycan via the formation of covalent crosslinks between the N-terminus of integral OM proteins (OMPs; including porins) and peptide stems of peptidoglycan.

Project description:Clostridium difficile is an important nosocomial pathogen and the leading cause of hospital-acquired diarrhea. Antibiotic use is the primary risk factor for the development of C. difficile-associated disease because it disrupts normal protective gut flora and enables C. difficile to colonize the colon. C. difficile damages host tissue by secreting toxins and disseminates by forming spores. The toxin-encoding genes, tcdA and tcdB are part of a pathogenicity locus, which also encodes the gene tcdR that codes for the toxin genes positive regulator. TcdR is an alternate sigma factor that initiates transcription of tcdA and tcdB at their promoters. Alternative sigma factors are known to regulate virulence and virulence associated genes in many pathogenic bacteria. We created a tcdR mutant in the epidemic-type C. difficile R20291 strain in an attempt to identify the global role of tcdR. A site-directed mutation in tcdR affected both toxin production and sporulation in C. difficile R20291. Spores derived from the tcdR mutant were found to be mildly temperature sensitive. Moreover, nearly two fold more taurocholate was needed to germinate spores from the tcdR mutant than the spores prepared from the wild-type parent strain. Comparison of the tcdR mutant transcriptome with the parent strain revealed many differentially expressed late sporulation genes in the tcdR mutant. These data suggests that gene regulatory networks of toxin production and sporulation in Clostridium difficile are linked with each other.

Project description:Lysyl oxidase is an extracellular enzyme essential for crosslinking elastin and collagen. Mice that do not express Lox have 60% and 40% reductions in elastin-specific and collagen-specific crosslinks, respectively. Mutations in LOX are associated with thoracic aortic aneurysm and dissection (TAAD). Lysyl oxidase knockout mice dye perinatally with ruptured diaphragm, tortuous arteries, and TAAD This is the first study to analyze the mechanical and genetic changes induced by the absence of lysyl oxidase in the thoracic aorta, and may provide new therapeutic targets relevant for the pathogenesis of thoracic aortic aneurysms and dissections

Project description:The flagellar motor is a powerful macromolecular machine used to propel bacteria through various environments. Flagellar motility of the alpha-proteobacterium Sinorhizobium meliloti is nearly abolished in the absence of the transcriptional regulator LdtR, which is involved in peptidoglycan remodeling. We report that LdtR does not regulate motility gene transcription. Remarkably, the motility defects of the DldtR mutant can be restored by secondary mutations in the motility gene motA or a previously uncharacterized gene in the flagellar regulon, which we named motS. MotS is not essential for S. meliloti motility and may serve an accessory role in flagellar motor function. Structural modeling predicts that MotS is comprised of an N-terminal transmembrane segment, a long-disordered region, and a conserved β-sandwich domain. The C-terminus of MotS is localized in the periplasm. Genetics-based substitution of MotA with a MotAG12S variant protein also restored the ΔldtR motility defect. The MotAG12S variant causes a local polarity shift at the periphery of the MotAB stator units. We propose that MotS may be required for optimal alignment of stators in wild-type flagellar motors but becomes detrimental in cells with altered peptidoglycan. Similarly, the polarity shift in the stator units composed of MotB/MotAG12S might stabilize its interaction with altered peptidoglycan.

Project description:Reactive aldehydes are abundant cytotoxic metabolites, which challenge homoeostasis by crosslinking cellular macromolecules. Aldehyde-induced DNA-DNA crosslinks cause cancer and bone marrow failure in Fanconi anemia, while covalent DNA-protein crosslinks require proteolytic repair to prevent liver tumours and premature ageing. Whether RNA damage contributes to the toxicity of aldehydes and whether cells possess mechanisms to resolve RNA-protein crosslinks (RPCs) in particular is unknown. Studying the specific consequences of aldehyde-induced RNA damage is challenging due to confounding induction of DNA damage. Here, we establish photoactivatable ribonucleosides as a tractable model system to study aldehyde-mimicking RNA damage in the absence of DNA damage. We find that RNA crosslinking damage causes translational stress by stalling elongating ribosomes, which causes cell death upon ZAKα-dependent activation of the ribotoxic stress response (RSR) and GCN2-dependent activation of the integrated stress response (ISR). Moreover, we discover the principles of a translation-coupled cellular quality control mechanism that targets RPCs. Collisions between translating ribosomes and crosslinked mRNA-binding proteins trigger their ubiquitylation and subsequent proteasomal degradation. Our findings reveal RNA damage and RPC formation as a central aspect of aldehyde-induced toxicity and establish a framework to study the cellular responses to these threats in mechanistic detail.

Project description:Reactive aldehydes are abundant cytotoxic metabolites, which challenge homoeostasis by crosslinking cellular macromolecules. Aldehyde-induced DNA-DNA crosslinks cause cancer and bone marrow failure in Fanconi anemia, while covalent DNA-protein crosslinks require proteolytic repair to prevent liver tumours and premature ageing. Whether RNA damage contributes to the toxicity of aldehydes and whether cells possess mechanisms to resolve RNA-protein crosslinks (RPCs) in particular is unknown. Studying the specific consequences of aldehyde-induced RNA damage is challenging due to confounding induction of DNA damage. Here, we establish photoactivatable ribonucleosides as a tractable model system to study aldehyde-mimicking RNA damage in the absence of DNA damage. We find that RNA crosslinking damage causes translational stress by stalling elongating ribosomes, which causes cell death upon ZAKα-dependent activation of the ribotoxic stress response (RSR) and GCN2-dependent activation of the integrated stress response (ISR). Moreover, we discover the principles of a translation-coupled cellular quality control mechanism that targets RPCs. Collisions between translating ribosomes and crosslinked mRNA-binding proteins trigger their ubiquitylation and subsequent proteasomal degradation. Our findings reveal RNA damage and RPC formation as a central aspect of aldehyde-induced toxicity and establish a framework to study the cellular responses to these threats in mechanistic detail.