La jonction d'extrémités non-homologues : une nouvelle fonction pour le complexe de ligature

Chez les vertébrés, la voie majoritaire de réparation des cassures double brin de l'ADN est la jonction d'extrémité non homologue (NHEJ). Afin d'initier la réparation, la protéine hétérodimérique Ku se lie aux extrémités de l'ADN et recrute la sous unité catalytique de la protéine kinase dépendante de l'ADN (DNA-PKcs) pour former la DNA-PK. La formation d'une synapse par deux DNA-PK (une sur chaque extrémité de l'ADN) entraîne l'autophosphorylation de la kinase. Le complexe XRCC4/Ligase4 catalyse l'étape finale de ligature avec l'aide de Cernunnos/XLF. Au cours de ma thèse, nous avons prouvé qu'il existe un défaut de maintien de la synapse ainsi que de l'autophosphorylation de la DNA-PKcs dans les extraits cellulaire dépourvu de Ligase4. De plus, dans une expérience de reconstitution mettant en jeu des protéines purifiées, la Ligase 4 stimule l'autophosphorylation de la DNA-PKcs. Un défaut d'autophosphorylation de la kinase dans les cellules déficientes pour la Ligase4 a également était prouvé. Enfin, notre travail montre une contribution de Cernunnos-XLF dans ce rôle précoce du complexe de ligature au cours de la NHEJ. Toutes ces données nous permettent d'émettre l'hypothèse de la formation d'un complexe supramoléculaire précoce, comprenant la DNA-PK et le complexe XRCC4/Ligase4/XLF, sur les extrémités de l'ADN au cours de la réaction de NHEJ.Nonhomologous end joining is the primary DNA double-strand break repair pathway in multicellular eukaryotes. To initiate repair, Ku binds DNA ends and recruits the DNA dependent protein kinase catalytic subunit (DNA-PKcs) forming the holoenzyme. Early end synapsis is associated with kinase autophosphorylation. The XRCC4/Ligase IV complex executes the final ligation promoted by Cernunnos-XLF. During my thesis, using a cell-free system that recapitulates end synapsis and DNAPKcs autophosphorylation, we found a defect in both activities in human cell extracts lacking Ligase IV. Ligase IV also stimulated the DNA-PKcs autophosphorylation in a reconstitution assay with purified components. We additionally uncovered a kinase autophosphorylation defect in Ligase IV-defective cells that was corrected by ectopic expression of catalytically dead Ligase IV. Finally, our data support a contribution of Cernunnos-XLF to this unexpected early role of the ligation complex in end joining. We propose that productive end joining occurs by early formation of a supramolecular entity containing both DNA-PK and XRCC4/Ligase IV/Cernunnos-XLF complexes on DNA ends

Reprint of “The clinical impact of deficiency in DNA non-homologousend-joining”

DNA non-homologous end-joining (NHEJ) is the major DNA double strand break (DSB) repair pathway inmammalian cells. Defects in NHEJ proteins confer marked radiosensitivity in cell lines and mice models,since radiation potently induces DSBs. The process of V(D)J recombination functions during the devel-opment of the immune response, and involves the introduction and rejoining of programmed DSBs togenerate an array of diverse T and B cells. NHEJ rejoins these programmed DSBs. Consequently, NHEJdeficiency confers (severe) combined immunodeficiency – (S)CID – due to a failure to carry out V(D)Jrecombination efficiently. NHEJ also functions in class switch recombination, another step enhancing Tand B cell diversity. Prompted by these findings, a search for radiosensitivity amongst (S)CID patientsrevealed a radiosensitive sub-class, defined as RS-SCID. Mutations in NHEJ genes, defining human syn-dromes deficient in DNA ligase IV (LIG4 Syndrome), XLF-Cernunnos, Artemis or DNA-PKcs, have beenidentified in such patients. Mutations in XRCC4 or Ku70,80 in patients have not been identified. RS-SCIDpatients frequently display additional characteristics including microcephaly, dysmorphic facial featuresand growth delay. Here, we overview the clinical spectrum of RS-SCID patients and discuss our currentunderstanding of the underlying biology

Genome-Scale Identification of Resistance Functions in Pseudomonas aeruginosa Using Tn-seq

We describe a deep-sequencing procedure for tracking large numbers of transposon mutants of Pseudomonas aeruginosa. The procedure employs a new Tn-seq methodology based on the generation and amplification of single-strand circles carrying transposon junction sequences (the Tn-seq circle method), a method which can be used with virtually any transposon. The procedure reliably identified more than 100,000 transposon insertions in a single experiment, providing near-saturation coverage of the genome. To test the effectiveness of the procedure for mutant identification, we screened for mutations reducing intrinsic resistance to the aminoglycoside antibiotic tobramycin. Intrinsic tobramycin resistance had been previously analyzed at genome scale using mutant-by-mutant screening and thus provided a benchmark for evaluating the new method. The new Tn-seq procedure identified 117 tobramycin resistance genes, the majority of which were then verified with individual mutants. The group of genes with the strongest mutant phenotypes included nearly all (13 of 14) of those with strong mutant phenotypes identified in the previous screening, as well as a nearly equal number of new genes. The results thus show the effectiveness of the Tn-seq method in defining the genetic basis of a complex resistance trait of P. aeruginosa and indicate that it can be used to analyze a variety of growth-related processes

Large-Scale Mapping and Validation of Escherichia coli Transcriptional Regulation from a Compendium of Expression Profiles

Machine learning approaches offer the potential to systematically identify transcriptional regulatory interactions from a compendium of microarray expression profiles. However, experimental validation of the performance of these methods at the genome scale has remained elusive. Here we assess the global performance of four existing classes of inference algorithms using 445 Escherichia coli Affymetrix arrays and 3,216 known E. coli regulatory interactions from RegulonDB. We also developed and applied the context likelihood of relatedness (CLR) algorithm, a novel extension of the relevance networks class of algorithms. CLR demonstrates an average precision gain of 36% relative to the next-best performing algorithm. At a 60% true positive rate, CLR identifies 1,079 regulatory interactions, of which 338 were in the previously known network and 741 were novel predictions. We tested the predicted interactions for three transcription factors with chromatin immunoprecipitation, confirming 21 novel interactions and verifying our RegulonDB-based performance estimates. CLR also identified a regulatory link providing central metabolic control of iron transport, which we confirmed with real-time quantitative PCR. The compendium of expression data compiled in this study, coupled with RegulonDB, provides a valuable model system for further improvement of network inference algorithms using experimental data

The Impact of Different Antibiotic Regimens on the Emergence of Antimicrobial-Resistant Bacteria

Backgroud: The emergence and ongoing spread of antimicrobial-resistant bacteria is a major public health threat. Infections caused by antimicrobial-resistant bacteria are associated with substantially higher rates of morbidity and mortality compared to infections caused by antimicrobial-susceptible bacteria. The emergence and spread of these bacteria is complex and requires incorporating numerous interrelated factors which clinical studies cannot adequately address. Methods/Principal Findings: A model is created which incorporates several key factors contributing to the emergence and spread of resistant bacteria including the effects of the immune system, acquisition of resistance genes and antimicrobial exposure. The model identifies key strategies which would limit the emergence of antimicrobial-resistant bacterial strains. Specifically, the simulations show that early initiation of antimicrobial therapy and combination therapy with two antibiotics prevents the emergence of resistant bacteria, whereas shorter courses of therapy and sequential administration of antibiotics promote the emergence of resistant strains. Conclusions/Significance: The principal findings suggest that (i) shorter lengths of antibiotic therapy and early interruption of antibiotic therapy provide an advantage for the resistant strains, (ii) combination therapy with two antibiotics prevents the emergence of resistance strains in contrast to sequential antibiotic therapy, and (iii) early initiation of antibiotics is among the most important factors preventing the emergence of resistant strains. These findings provide new insights into strategies aimed at optimizing the administration of antimicrobials for the treatment of infections and the prevention of the emergence of antimicrobial resistance

Importance of a C-Terminal Conserved Region of Chk1 for Checkpoint Function

BACKGROUND: The protein kinase Chk1 is an essential component of the DNA damage checkpoint pathway. Chk1 is phosphorylated and activated in the fission yeast Schizosaccharomyces pombe when cells are exposed to agents that damage DNA. Phosphorylation, kinase activation, and nuclear accumulation are events critical to the ability of Chk1 to induce a transient delay in cell cycle progression. The catalytic domain of Chk1 is well-conserved amongst all species, while there are only a few regions of homology within the C-terminus. A potential pseudosubstrate domain exists in the C-terminus of S. pombe Chk1, raising the possibility that the C-terminus acts to inhibit the catalytic domain through interaction of this domain with the substrate binding site. METHODOLOGY/PRINCIPAL FINDINGS: To evaluate this hypothesis, we characterized mutations in the pseudosubstrate region. Mutation of a conserved aspartic acid at position 469 to alanine or glycine compromises Chk1 function when the mutants are integrated as single copies, demonstrating that this domain of Chk1 is critical for function. Our data does not support, however, the hypothesis that the domain acts to inhibit Chk1 function as other mutations in the amino acids predicted to comprise the pseudosubstrate do not result in constitutive activation of the protein. When expressed in multi-copy, Chk1D469A remains non-functional. In contrast, multi-copy Chk1D469G confers cell survival and imposes a checkpoint delay in response to some, though not all forms of DNA damage. CONCLUSIONS/SIGNIFICANCE: Thus, we conclude that this C-terminal region of Chk1 is important for checkpoint function and predict that a limiting factor capable of associating with Chk1D469G, but not Chk1D469A, interacts with Chk1 to elicit checkpoint activation in response to a subset of DNA lesions

Phosphorylation-Independent Regulation of Atf1-Promoted Meiotic Recombination by Stress-Activated, p38 Kinase Spc1 of Fission Yeast

BACKGROUND:Stress-activated protein kinases regulate multiple cellular responses to a wide variety of intracellular and extracellular conditions. The conserved, multifunctional, ATF/CREB protein Atf1 (Mts1, Gad7) of fission yeast binds to CRE-like (M26) DNA sites. Atf1 is phosphorylated by the conserved, p38-family kinase Spc1 (Sty1, Phh1) and is required for many Spc1-dependent stress responses, efficient sexual differentiation, and activation of Rec12 (Spo11)-dependent meiotic recombination hotspots like ade6-M26. METHODOLOGY/PRINCIPAL FINDINGS:We sought to define mechanisms by which Spc1 regulates Atf1 function at the ade6-M26 hotspot. The Spc1 kinase was essential for hotspot activity, but dispensable for basal recombination. Unexpectedly, a protein lacking all eleven MAPK phospho-acceptor sites and detectable phosphorylation (Atf1-11M) was fully proficient for hotspot recombination. Furthermore, tethering of Atf1 to ade6 in the chromosome by a heterologous DNA binding domain bypassed the requirement for Spc1 in promoting recombination. CONCLUSIONS/SIGNIFICANCE:The Spc1 protein kinase regulates the pathway of Atf1-promoted recombination at or before the point where Atf1 binds to chromosomes, and this pathway regulation is independent of the phosphorylation status of Atf1. Since basal recombination is Spc1-independent, the principal function of the Spc1 kinase in meiotic recombination is to correctly position Atf1-promoted recombination at hotspots along chromosomes. We also propose new hypotheses on regulatory mechanisms for shared (e.g., DNA binding) and distinct (e.g., osmoregulatory vs. recombinogenic) activities of multifunctional, stress-activated protein Atf1