Compréhension des mécanismes physiologiques et génétiques impliqués dans l'activité réductrice de Lactococcus lactis / Understanding of the physiological and genetic mechanisms involved in the reducing activity of Lactococcus lactis

Roussel, Célia

22 June 2015

Les bactéries lactiques, en particulier Lactococcus lactis sont utilisées en industrie agroalimentaire. Ces bactéries sont connues pour avoir une activité réductrice, désignant leur aptitude à abaisser le potentiel redox (Eh) d’un milieu. Le génome de L. lactis MG1363 code plusieurs protéines possédant un motif CXXC potentiellement liées à une activité redox. Pour comprendre le rôle des protéines de surface riches en cystéines, deux approches ont été utilisées. Par l’approche bioinformatique, notre intérêt s'est porté sur deux protéines de surface de fonctions inconnues et à motif CX2CX10CX2C : Llmg_0524 et Llmg_0526. Leurs gènes forment un opéron induit temporairement en début de croissance. Dans les deux protéines, le motif chélate un ion de zinc par les résidus cystéines, formant un complexe très stable. Nos données suggèrent que cet opéron contribue à l'intégrité de la paroi cellulaire et que le zinc participe à la stabilité des protéines. L'identification des protéines à thiols exofaciaux par une approche biochimique indique la présente d’AhpF à la surface de L. lactis. La délétion du gène ahpF entraîne une forte sensibilité du mutant au cumène hydroperoxyde, mais aucune au peroxyde d'hydrogène. Le cumène hydroperoxyde provoque une modification de la proportion en acide gras chez le mutant ahpF, le mécanisme de cyclopropanation contribue à sa survie en réponse à un stress oxydatif. La compréhension des fonctions impliquées dans l'activité réductrice des lactocoques permettra une meilleure maîtrise du Eh dans la fabrication des produits fermentés et un meilleur contrôle des flores pathogènes et d’altérations. Le projet Food-Redox a été financé par l'ANR. / Lactic acid bacteria, particularly Lactococcus lactis are used in dairy industry. These bacteria are known to have a reducing activity, indicating their ability to lower the redox potential (Eh) of a medium. L. lactis MG1363 genome encodes several proteins with a CXXC motif, potentially linked with a redox activity. To understand the role of proteins rich in cysteine located at the surface of L. lactis, two approaches were used, one bioinformatics and biochemical another. For bioinformatic approach, interest was focused on two proteins of unknown function and CX2CX10CX2C motif: Llmg_0524 and Llmg_0526. Their corresponding genes form an operon temporarily induces in early growth phase. In these two proteins, the pattern chelate a zinc ion via its cysteine residues. The zinc-cysteine complexe is very stable, it suggests a probable role in protein stability. Data suggest that this operon contributes to the cell wall integrity. The identification of exofacial thiol proteins by a biochemical approach indicates that AhpF is present at the surface of L. lactis. The ahpF gene deletion causes a strong sensitivity to the cumene hydroperoxide, but no sensibility for hydrogen peroxide. In the mutant ahpF incubation with cumene hydroperoxide modified fatty acid proportion, cyclopropanation mechanism thus contributes to the survival in response to oxidative stress. Understanding the lactococci functions involved in the reduction activity allows a better control of redox potentiel in the fermented food production and thus a better control of foodbornes microorganisms in these products. Food-Redox project is financially supported by the French National Research Agency.

Lactococcus lactis

Activité réductrice

Protéines de surface

CXXC

Lactococcus lactis

Reducing activity

Surface proteins

CXXC

571.6

579

Biochemical characterisation of KDM2A

Zhou, Jin Chuan

January 2012

Mammalian genomes are characterised by unique regions of non-methylated DNA known as CpG islands (CGIs). These genomic elements are characterised by a high density of CpGs and an elevated GC content compared to the surrounding, bulk of the genome. CGIs are prevalently associated with the 5’ end of genes and represent key nucleation sites where specific transcription factors and chromatin modifiers are recruited to impact on gene function. This thesis is focused at understanding the biochemical properties of the recently discovered H3K36-specific histone demethylase, KDM2A. This enzyme is specifically recruited to CGIs but how it interfaces with local chromatin in vivo remains unknown. Using defined chromatin templates in vitro, this study demonstrates that KDM2A binding to DNA relies on a zinc finger CXXC domain that preferentially recognizes non-methylated CpGs. In particular, nucleosomes represent a major barrier to KDM2A binding and chromatin substrates are interpreted by the CXXC domain through specific interaction with CpGs within linker DNAs. Moreover, the adjacent PHD domain does not contribute to KDM2A binding to chromatin. Together these observations suggest that sequence, methylation status and accessibility of DNA define how CGI chromatin is interpreted by CXXC domain proteins. In particular, the precise targeting of KDM2A to CGIs contributes to the creation of a unique chromatin architecture that highlights gene regulatory regions within large and complex mammalian genomes.

572.86

Structure-function analysis of CXXC finger protein 1

Tate, Courtney Marie

26 January 2010

Indiana University-Purdue University Indianapolis (IUPUI) / This dissertation describes structure-function studies of CXXC finger protein 1 (Cfp1), encoded by the CXXC1 gene, in order to determine the functional significance of Cfp1 protein domains and properties. Cfp1 is an important regulator of chromatin structure and is essential for mammalian development. Murine embryonic stem (ES) cells lacking Cfp1 (CXXC1-/-) are viable but demonstrate a variety of defects, including hypersensitivity to DNA damaging agents, reduced plating efficiency and growth, decreased global and gene-specific cytosine methylation, failure to achieve in vitro differentiation, aberrant histone methylation, and subnuclear mis-localization of Setd1A, the catalytic component of a histone H3K4 methyltransferase complex, and tri-methylated histone H3K4 (H3K4me3) with regions of heterochromatin. Expression of wild-type Cfp1 in CXXC1-/- ES cells rescues the observed defects, thereby providing a convenient method to assess structure-function relationships of Cfp1. Cfp1 cDNA expression constructs were stably transfected into CXXC1-/- ES cells to evaluate the ability of various Cfp1 fragments and mutations to rescue the CXXC1-/- ES cell phenotype. These experiments revealed that expression of either the amino half of Cfp1 (amino acids 1-367) or the carboxyl half of Cfp1 (amino acids 361-656) is sufficient to rescue the hypersensitivity to DNA damaging agents, plating efficiency, cytosine and histone methylation, and differentiation defects. These results reveal that Cfp1 contains redundant functional domains for appropriate regulation of cytosine methylation, histone methylation, and in vitro differentiation. Additional studies revealed that a point mutation (C169A) that abolishes DNA-binding activity of Cfp1 ablates the rescue activity of the 1-367 fragment, and a point mutation (C375A) that abolishes the interaction of Cfp1 with the Setd1A and Setd1B histone H3K4 methyltransferase complexes ablates the rescue activity of the 361-656 Cfp1 fragment. In addition, introduction of both point mutations (C169A and C375A) ablates the rescue activity of the full-length Cfp1 protein. These results indicate that retention of either DNA-binding or Setd1 association of Cfp1 is required to rescue hypersensitivity to DNA damaging agents, plating efficiency, cytosine and histone methylation, and in vitro differentiation. In contrast, confocal immunofluorescence analysis revealed that full-length Cfp1 is required to restrict Setd1A and histone H3K4me3 to euchromatic regions.

protein domains

cytosine methylation

embryonic stem cells

chromatin

Set1

DNA methyltransferase

Dnmt1

histone methyltransferase

base excision repair

DNA repair

Ape1

differentiation

CXXC finger protein 1

histone methylation

DNA-protein interactions

Chromatin

Embryonic stem cells

DNA repair