Project description:Pseudomonas syringae pv. phaseolicola (Pph) is a significant bacterial pathogen of agricultural crops, and phage Φ6 and other members of the dsRNA virus family Cystoviridae undergo lytic (virulent) infection of Pph, using the type IV pilus as the initial site of cellular attachment. Despite the popularity of Pph/phage Φ6 as a model system in evolutionary biology, Pph resistance to phage Φ6 remains poorly characterized. To investigate differences between phage Φ6 resistant Pseudomonas syringae pathovar phaseolicola strains, we performed expression analysis of super and non piliated strains of Pseudomonas syringae to determine the genetic cause of resistance to viral infection.

Project description:In Arabidopsis mature seeds, the onset of the embryo-to-seedling transition is nonautonomously controlled, being blocked by endospermic abscisic acid (ABA) release under unfavorable conditions. Mature embryos lack an impermeable cuticle, unlike seedlings, consistent with their endospermic ABA uptake capability. Seedling cuticle formation occurs after germination rather than during embryogenesis. Mature endosperm removal prevents seedling cuticle formation and seed reconstitution by endosperm grafting onto embryos shows that the endosperm promotes seedling cuticle development. Grafting different endosperm and embryo mutant combinations, together with biochemical, microscopy and mass spectrometry approaches, reveals that endospermic release of Tyrosyl Sulfate Transferase (TPST)-sulfated CIF2 and PSY1 peptides promotes seedling cuticle development. Endosperm-deprived embryos produced nonviable seedlings bearing numerous developmental defects, in a manner unrelated to embryo nourishment, all restored by exogenously provided endosperm. Hence, seedling establishment is nonautonomous, requiring the mature endosperm.

Project description:The interactors of the protein Arp-T1 were studied in human cells ( keratinocytes)

Project description:Social insects frequently engage in oral fluid exchange – trophallaxis – between adults, and between adults and larvae. Although trophallaxis is normally considered a simple food-sharing mechanism, we hypothesized that endogenous components of this fluid might underlie a novel means of chemical communication that directly influences colony organization. Through protein and small-molecule mass spectrometry and RNA sequencing in the ant Camponotus floridanus, we found that trophallactic fluid contains a set of specific proteins, hydrocarbons, microRNAs, and Juvenile Hormone, an important insect growth regulator. Comparison of trophallactic fluid proteins across social insect species (ants Camponotus fellah and Solenopsis invictis, honeybees Apis mellifera) revealed that many are regulators of growth and development. These results raise the possibility that, in addition to its role in food transfer, trophallaxis is a mode of communication that enables communal control of colony phenotypes.

Project description:The endoplasmic reticulum (ER) is a multifaceted organelle that plays an essential role in cellular processes such as protein folding, modification, and trafficking. It also acts as a proteostasis sensor and contributes to adaptation responses to maintain cellular homeostasis. The transcription factor NRF1 resides in the ER and is constantly transported from the ER to the cytosol for proteasomal degradation. However, when the proteasome function is defective, NRF1 escapes degradation and undergoes proteolytic cleavage by the protease DDI2, generating a transcriptionally active form that restores proteostasis, including proteasome function. Despite the importance of NRF1 in these processes, the mechanisms that regulate its proteolytic activation and transcriptional potential remain poorly understood. In this study, we utilized a functional molecular approach to elucidate the critical steps involved in NRF1 cleavage. Our results demonstrate that the ER is a crucial regulator of NRF1 function, orchestrating its ubiquitination by the ER-localized E3 ubiquitin ligase HRD1, a component of the ER-associated degradation (ERAD) pathway. Furthermore, we show that HRD1-mediated NRF1 ubiquitination is necessary for DDI2-mediated processing in cells. Notably, we found that the fusion of a ubiquitin moiety to NRF1 was sufficient to promote its proteolytic maturation by DDI2, thus bypassing the requirement for its trafficking to the ER. Our findings highlight the intricate mechanism by which NRF1 is activated by DDI2 and coordinates the transcriptional activity of an adaptation response in cells and suggest potential avenues for therapeutic interventions in conditions associated with proteasome impairment.

Project description:Molecular mechanisms underlying quantitative variations of pathogenicity remain elusive. Here, we identified the Xanthomonas campestris XopJ6 effector that triggers disease resistance in cauliflower and Arabidopsis thaliana. XopJ6 is a close homolog of the Ralstonia solanacearum PopP2 YopJ family acetyltransferase. XopJ6 is recognized by the RRS1-R/RPS4 NLR pair that integrates a WRKY decoy domain mimicking effector true targets. We identified a XopJ6 natural variant carrying a single residue substitution in XopJ6 WRKY-binding site that disrupts interaction with WRKY proteins. This mutation allows XopJ6 to evade immune perception while retaining XopJ6 virulence functions. Interestingly, xopJ6 resides in a Tn3-family transposon likely contributing to xopJ6 copy number variation (CNV). Using genetic complementation assays, we demonstrate that xopJ6 CNV allows fine-tuning of pathogen virulence on Arabidopsis through gene dosage-mediated modulation of xopJ6 expression. Together, our findings highlight how sequence and structural genetic variations restricted at a particular effector gene contribute to bacterial host adaptation.

Project description:Phages are viruses that specifically infect and kill bacteria. Bacterial fermentation and biotechnology industries see them as enemies, however, they are also investigated for the treatment or prevention of infections caused by multidrug resistant bacteria. Whether foes or allies, their importance is undeniable. Despite decades of research some aspects of phage biology are still poorly understood. In this study, we used label-free quantitative proteomics to reveal the proteotypes of Lactococcus lactis MG1363 during infection by the virulent phage p2, a model for studying the biology of phages infecting Gram-positive bacteria. Our approach resulted in the high-confidence detection and quantification of 59% of the theoretical bacterial proteome, including 226 bacterial proteins detected only during phage infection and 6 proteins unique to uninfected bacteria. We also identified many bacterial proteins of differing abundance during the infection. Using this high-throughput proteomic datasets, we selected specific bacterial genes for inactivation using CRISPR-Cas9 to investigate their involvement in phage replication. One knockout mutant lacking gene llmg_0219 showed resistance to phage p2 due to a deficiency in phage adsorption. Furthermore, we detected and quantified 78% of the theoretical phage proteome and identified many proteins of phage p2 that had not been previously detected. Among others, we uncovered a conserved small phage protein (ORFN1) coded by an unannotated gene. We also applied a targeted approach to achieve greater sensitivity and identify undetected phage proteins that were expected to be present. This allowed us to follow the fate of ORF46, a small phage protein of low abundance. In summary, this work offers a unique view of the virulent phages’ takeover of bacterial cells and provides novel information on phage-host interactions.

Project description:The human genome contains 11 APOBEC (Apolipoprotein B mRNA Editing Catalytic Polypeptide-like) cytidine deaminases classified into four families. These proteins function mainly in innate antiviral immunity and can also restrict endogenous retrotransposable element multiplication. The present study focuses on APOBEC3C (A3C), a member of the APOBEC3 sub-family. Some APOBEC3 proteins use their enzymatic activity on genomic DNA, inducing mutations and DNA damage, while other members facilitate DNA repair. Our results show that A3C is highly expressed in cells treated with DNA damaging agents. Its expression is regulated by p53. In addition, we provide the A3C interactome in both normal conditions and in cells exposed to the genotoxin etoposide. Most A3C interacting partners are proteins involved in RNA metabolism and some in DNA repair. Our data also indicate that A3C overexpression is detrimental to mammalian cells and we show that this protein is located around the nucleolus and at laser-damaged DNA sites.

Project description:Phage therapy is a promising adjunct therapeutic approach against bacterial multidrug-resistant infections, including Pseudomonas aeruginosa-derived infections. Nevertheless, the current knowledge about the phage-bacteria interaction within a human environment is limited. In this work, we performed a transcriptome analysis of phage-infected P. aeruginosa adhered to a human epithelium (Nuli-1 ATCC® CRL-4011™). To this end, we performed RNA-sequencing from a complex mixture comprising phage–bacteria–human cells at early, middle, and late infection and compared it to uninfected adhered bacteria. Overall, we demonstrated that phage genome transcription is unaltered by bacterial growth and phage employs a core strategy of predation through upregulation of prophage-associated genes, a shutdown of bacterial surface receptors, and motility inhibition. In addition, specific responses were captured under lung-simulating conditions, with the expression of genes related to spermidine syntheses, sulfate acquisition, spermidine syntheses, biofilm formation (both alginate and polysaccharide syntheses), lipopolysaccharide (LPS) modification, pyochelin expression, and downregulation of virulence regulators. These responses should be carefully studied in detail to better discern phage-induced changes from bacterial responses against phage. Our results establish the relevance of using complex settings that mimics in vivo conditions to study phage-bacteria interplay, being obvious the phage versatility on bacterial cell invasion.

Project description:Socially exchanged fluids, such as seminal fluid and milk, are a direct means through which an organism can influence conspecifics. When orally feeding larval offspring via trophallaxis, workers of the carpenter ant Camponotus floridanus were recently shown to transfer Juvenile Hormone III (JH), a key developmental regulator, as well as paralogs of JH esterase (JHE), an enzyme that catalyzes degradation of JH. Here we combine proteomic, phylogenetic and selection analyses to investigate the evolution of this esterase subfamily. We show that members of the Camponotus JHE-like protein family have undergone multiple duplications, experienced positive selection, and changed tissue localization to become abundantly and selectively present in trophallactic fluid. The Camponotus trophallactic esterases have maintained their catalytic triads but contain a number of positively-selected amino acid changes distributed throughout the protein, which possibly reflect an adaptation to the highly acidic trophallactic fluid of formicine ants. To determine whether these esterases might regulate larval development, we fed workers with a JHE-specific pharmacological inhibitor to introduce it into the trophallactic network. This inhibitor increased the likelihood of pupation of the larvae reared by these workers, similar and complementary to supplementation with JH. Together, these findings suggest that JHE-like proteins have evolved new roles in the Camponotus genus in inter-individual regulation of larval development.