["I love my heart": a regional program to reduce cardiovascular risk and health inequalities]. / "Je t'aime mon coeur", un programme régional de réduction des risques cardio-vasculaires ... et des inégalités de santé.

"Je t'aime mon coeur" ("I love you, my heart") is a regional program aimed at reducing cardiovascular risk based on a strategy consistent with the Ottawa Charter. One of the objectives of the program is to reduce health inequalities between the general population and disadvantaged groups with limited access to preventive services. Among disadvantaged groups, access to the program appears to be related to the activities designed specifically for them and, in particular, to the support provided by professionals dedicated to the task. The study also shows that the program has had a positive impact on key determinants of health, including individual factors (knowledge, perceived self-efficacy, self-esteem, etc.) and environmental factors. In addition, the study provides evidence of social mobilization and indicates that the targeted populations have responded positively to the program. There is also evidence of better coordination between professionals from different fields. However, the level of public participation in governance remains low, particularly in the steering committee and the technical committee. Additional resources are needed to promote the emergence of a public group or population actively involved in implementing the program. The participation of the general public in the team behind the project should enable people to become actors in their own right on a par with other stakeholders.

Insights into the function of RifI2: structural and biochemical investigation of a new shikimate dehydrogenase family protein.

The shikimate dehydrogenase (SDH) family consists of enzymes with diverse roles in secondary metabolism. The two most widespread members of the family, AroE and YdiB, function in amino acid biosynthesis and quinate catabolism, respectively. Here, we have determined the crystal structure of an SDH homolog belonging to the RifI class, a group of enzymes with proposed roles in antibiotic biosynthesis. The structure of RifI2 from Pseudomonas putida exhibits a number of distinctive features, including a substantial C-terminal truncation and an atypical mode of oligomerization. The active site of the enzyme contains substrate- and cofactor-binding motifs that are significantly different from those of any previously characterized member of the SDH family. These features are reflected in the novel kinetic properties of the enzyme. RifI2 exhibits much lower activity using shikimate as a substrate than AroE, and a strong preference for NAD(+) instead of NADP(+) as a cofactor. Moreover, the enzyme has only trace activity using quinate, unlike YdiB. Cocrystallization of RifI2 with NAD(+) provided the opportunity to determine the mode of cofactor selectivity employed by the enzyme. We complemented this analysis by probing the role of a strictly conserved residue in the cofactor-binding domain, Asn193, by site directed mutagenesis. This study presents the first crystal structure and formal kinetic characterization of a new NAD(+)-dependent member of the SDH family.

Structural and biochemical investigation of two Arabidopsis shikimate kinases: the heat-inducible isoform is thermostable.

The expression of plant shikimate kinase (SK; EC 2.7.1.71), an intermediate step in the shikimate pathway to aromatic amino acid biosynthesis, is induced under specific conditions of environmental stress and developmental requirements in an isoform-specific manner. Despite their important physiological role, experimental structures of plant SKs have not been determined and the biochemical nature of plant SK regulation is unknown. The Arabidopsis thaliana genome encodes two SKs, AtSK1 and AtSK2. We demonstrate that AtSK2 is highly unstable and becomes inactivated at 37 °C whereas the heat-induced isoform, AtSK1, is thermostable and fully active under identical conditions at this temperature. We determined the crystal structure of AtSK2, the first SK structure from the plant kingdom, and conducted biophysical characterizations of both AtSK1 and AtSK2 towards understanding this mechanism of thermal regulation. The crystal structure of AtSK2 is generally conserved with bacterial SKs with the addition of a putative regulatory phosphorylation motif forming part of the adenosine triphosphate binding site. The heat-induced isoform, AtSK1, forms a homodimer in solution, the formation of which facilitates its relative thermostability compared to AtSK2. In silico analyses identified AtSK1 site variants that may contribute to AtSK1 stability. Our findings suggest that AtSK1 performs a unique function under heat stress conditions where AtSK2 could become inactivated. We discuss these findings in the context of regulating metabolic flux to competing downstream pathways through SK-mediated control of steady state concentrations of shikimate.

Genes co-expressed with CPSAR1 identified using ATTED-II.

Identification of interacting proteins will help to investigate further the relationship between CPSAR1 and the vesicle transport system or the ribosomes. Thus, we adopted a bioinformatic approach, using the publicly available Arabidopsis thaliana trans-factor and cis-element prediction database, ATTED-II (http://atted.jp/), to identify putative protein interactors. The proteins directly linked to CPSAR1 were almost exclusively nucleus encoded and several were involved in protein synthesis of which three were thylakoid localized. The list of putative interacting proteins does not exclude any of the previous proposed actions of CPSAR1 but encourage more detailed examination of the role of CPSAR1.

Exploiting antigenic diversity for vaccine design: the chlamydia ArtJ paradigm.

We present an interdisciplinary approach that, by incorporating a range of experimental and computational techniques, allows the identification and characterization of functional/immunogenic domains. This approach has been applied to ArtJ, an arginine-binding protein whose orthologs in Chlamydiae trachomatis (CT ArtJ) and pneumoniae (CPn ArtJ) are shown to have different immunogenic properties despite a high sequence similarity (60% identity). We have solved the crystallographic structures of CT ArtJ and CPn ArtJ, which are found to display a type II transporter fold organized in two α-ß domains with the arginine-binding region at their interface. Although ArtJ is considered to belong to the periplasm, we found that both domains contain regions exposed on the bacterial surface. Moreover, we show that recombinant ArtJ binds to epithelial cells in vitro, suggesting a role for ArtJ in host-cell adhesion during Chlamydia infection. Experimental epitope mapping and computational analysis of physicochemical determinants of antibody recognition revealed that immunogenic epitopes reside mainly in the terminal (D1) domain of both CPn and CT ArtJ, whereas the surface properties of the respective binding-prone regions appear sufficiently different to assume divergent immunogenic behavior. Neutralization assays revealed that sera raised against CPn ArtJ D1 partially reduce both CPn and CT infectivity in vitro, suggesting that functional antibodies directed against this domain may potentially impair chlamydial infectivity. These findings suggest that the approach presented here, combining functional and structure-based analyses of evolutionary-related antigens can be a valuable tool for the identification of cross-species immunogenic epitopes for vaccine development.

The chloroplast protein CPSAR1, dually localized in the stroma and the inner envelope membrane, is involved in thylakoid biogenesis.

Thylakoid biogenesis is a crucial step for plant development involving the combined action of many cellular actors. CPSAR1 is shown here to be required for the normal organization of mature thylakoid stacks, and ultimately for embryo development. CPSAR1 is a chloroplast protein that has a dual localization in the stroma and the inner envelope membrane, according to microscopy studies and subfractionation analysis. CPSAR1 is close to the Obg nucleotide binding protein subfamily and displays GTPase activity, as demonstrated by in vitro assays. Disruption of the CPSAR1 gene via T-DNA insertion results in the arrest of embryo development. In addition, transmission electron microscopy analysis indicates that mutant embryos are unable to develop thylakoid membranes, and remain white. Unstacked membrane structures resembling single lamellae accumulate in the stroma, and do not assemble into mature thylakoid stacks. CPSAR1 RNA interference induces partially developed thylakoids leading to pale-green embryos. Altogether, the presented data demonstrate that CPSAR1 is a protein essential for the formation of normal thylakoid membranes, and suggest a possible involvement in the initiation of vesicles from the inner envelope membrane for the transfer of lipids to the thylakoids.

In vivo studies on the roles of Tic55-related proteins in chloroplast protein import in Arabidopsis thaliana.

The Tic55 (Translocon at the inner envelope membrane of chloroplasts, 55 kDa) protein was identified in pea as a putative regulator, possibly linking chloroplast protein import to the redox state of the photosynthetic machinery. Two Tic55 homologs have been proposed to exist in Arabidopsis: atTic55-II and AtPTC52 (Protochlorophyllide-dependent Translocon Component, 52 kDa; has also been called atTic55-IV). Our phylogenetic analysis shows that atTic55-II is an ortholog of psTic55 from pea (Pisum sativum), and that AtPTC52 is a more distant homolog of the two. AtPTC52 was included in this study to rule out possible functional links between the proteins in Arabidopsis. No detectable mutant phenotypes were found in two independent T-DNA knockout mutant plant lines for each Arabidopsis protein, when compared with wild-type: visible appearance, chlorophyll content, photosynthetic performance, and chloroplast protein import, for example, were all normal. Both wild-type and tic55-II mutant chloroplasts exhibited deficient protein import when treated with diethylpyrocarbonate, indicating that Tic55 is not the sole target of this reagent in relation to protein import. Furthermore, ptc52 mutant chloroplasts were not defective with respect to pPORA import, which was previously reported to involve PTC52 in barley. Thus, we conclude that atTic55-II and AtPTC52 are not strictly required for functional protein import in Arabidopsis.

The VLCFA elongase gene family in Arabidopsis thaliana: phylogenetic analysis, 3D modelling and expression profiling.

As precursors of wax compounds, very long chain fatty acids participate in the limitation of non-stomatal water loss and the prevention of pathogen attacks. They also serve as energy storage in seeds and as membrane building blocks. Their biosynthesis is catalyzed by the acyl-CoA elongase, a membrane-bound enzymatic complex containing four distinct enzymes (KCS, KCR, HCD and ECR). Twenty-one 3-ketoacyl-CoA synthase (KCS) genes have been identified in Arabidopsis thaliana genome. In this paper we present an overview of the acyl-CoA elongase genes in Arabidopsis focusing on the entire KCS family. We show that the KCS family is made up of 8 distinct subclasses, according to their phylogeny, duplication history, genomic organization, protein topology and 3D modelling. The analysis of the subcellular localization in tobacco cells of the different subunits of the acyl-CoA elongase shows that all these proteins are localized in the endoplasmic reticulum demonstrating that VLCFA production occurs in this compartment. The expression patterns in Arabidopsis of the acyl-CoA elongase genes suggest several levels of regulations at the tissular or organ level but also under stress conditions suggesting a complex organization of this multigenic family.

Profiling candidate genes involved in wax biosynthesis in Arabidopsis thaliana by microarray analysis.

Plant epidermal wax forms a hydrophobic layer covering aerial plant organs which constitutes a barrier against uncontrolled water loss and biotic stresses. Wax biosynthesis requires the coordinated activity of a large number of enzymes for the formation of saturated very-long-chain fatty acids and their further transformation in several aliphatic compounds. We found in the available database 282 candidate genes that may play a role in wax synthesis, regulation and transport. To identify the most interesting candidates, we measured the level of expression of 204 genes in the aerial parts of 15-day-old Arabidopsis seedlings by performing microarray experiments. We showed that only 25% of the putative candidates were expressed to significant levels in our samples, thus significantly reducing the number of genes which will be worth studying using reverse genetics to demonstrate their involvement in wax accumulation. We identified a beta-keto acyl-CoA synthase gene, At5g43760, which is co-regulated with the wax gene CER6 in a number of conditions and organs. By contrast, we showed that neither the fatty acyl-CoA reductase genes nor the wax synthase genes were expressed in 15-day-old leaves and stems, raising questions about the identity of the enzymes involved in the acyl-reduction pathway that accounts for 20% of the total wax amount.