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Salicylic Acid Signaling in Disease ResistanceKumar, Dhirendra 01 November 2014 (has links)
Salicylic acid (SA) is a key plant hormone that mediates host responses against microbial pathogens. Identification and characterization of SA-interacting/binding proteins is a topic which has always excited scientists studying microbial defense response in plants. It is likely that discovery of a true receptor for SA may greatly advance understanding of this important signaling pathway. SABP2 with its high affinity for SA was previously considered to be a SA receptor. Despite a great deal work we may still not have true a receptor for SA. It is also entirely possible that there may be more than one receptor for SA. This scenario is more likely given the diverse role of SA in various physiological processes in plants including, modulation of opening and closing of stomatal aperture, flowering, seedling germination, thermotolerance, photosynthesis, and drought tolerance. Recent identification of NPR3, NPR4 and NPR1 as potential SA receptors and α-ketoglutarate dehydrogenase (KGDHE2), several glutathione S transferases (GSTF) such as SA binding proteins have generated more interest in this field. Some of these SA binding proteins may have direct/indirect role in plant processes other than pathogen defense signaling. Development and use of new techniques with higher specificity to identify SA-interacting proteins have shown great promise and have resulted in the identification of several new SA interactors. This review focuses on SA interaction/binding proteins identified so far and their likely role in mediating plant defenses.
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Étude des déterminants génétiques et environnementaux des complications du diabète de type 2 / Genetic and environmental factors study of type 2 diabetes complicationsSaulnier, Pierre-Jean 20 December 2012 (has links)
Le diabète de type 2 (DT2) représente un enjeu de santé publique au regard de ses complications, qui sont des maladies complexes, où interagissent des déterminants génétiques et environnementaux.L'objectif de ce travail était d'étudier ces déterminants dans trois populations indépendantes de patients DT2 en couplant études transversales (DIAB2NEPHROGENE) et longitudinales (SURDIAGENE et DIABHYCAR) totalisant 7767 sujets. Via une approche gène-candidat, nous avons focalisé nos recherches sur le système des peptides natriurétiques, le gène NPR3 (codant le récepteur de clairance aux peptides natriurétiques) et les apports sodés puis la voie métabolique des hormones sexuelles, le gène CYP19A1 (codant l’aromatase) et les concentrations de stéroïdes sexuels. Nous avons montré que l'allèle G du rs2270915 du NPR3 est un allèle de risque de pression artérielle (PA) plus élevée et de moindre sensibilité pressive à la réduction sodée qui ne confère pas d'augmentation significative de risque d'évènements cardiovasculaires (ECV) contrairement au rs6889608. Enfin, la survie sans ECV est significativement modulée par les apports en sel avec un risque de morbi-mortalité réduit chez les sujets diabétiques consommant le plus de sel malgré un niveau de PA plus élevé.Nous avons confirmé que le sexe masculin est un facteur de risque pour la néphropathie diabétique (ND) mais également pour la survenue d'ECV. Nous avons montré, chez les hommes, que des concentrations plus élevés d'oestradiol s'associent à une prévalence plus importante de ND mais ne se traduisent pas par une augmentation des événements rénaux oucardiovasculaires. CYP19A1 n'est associé ni avec les niveaux d'oestradiol, ni avec la prévalence ou la sévérité de la ND. Deux SNP s'associent toutefois significativement avec la survenue d'insuffisance rénale chronique terminale.Au total, nous avons identifié dans 2 voies métaboliques distinctes des déterminants génétiques de complications du DT2 ainsi qu'une interaction gène-environnement. / Type 2 diabetes (T2D) is a public health issue because of vascular and renal complications, which are complex diseases with interaction between genetic and environmental determinants.The objective of this work was to study these determinants in three independent populations of T2D patients by coupling cross-sectional (DIAB2NEPHROGENE) and longitudinal studies (SURDIAGENE and DIABHYCAR). Through a candidate-gene approach, we first focused on the natriuretic peptides system, NPR3 gene and sodium intake and then on the metabolic pathway of sex hormones, CYP19A1 gene (coding for aromatase) and sex steroid levels.Our first results showed that NPR3 rs2270915 G Allele was associated with high blood pressure (BP) and a reduced salt-sensitivity of BP. However, this SNP was not associated with any significant risk of cardio-vascular events (CVE) or death, at variance with rs6889608. Ultimately, CVE-free survival was impacted by salt intake with a reduced risk of morbi-mortality in those patients having the greatest intake, though a higher BP.In our second study, we confirmed that male gender was a risk factor for diabetic nephropathy (DN), but also for the occurrence of CVE. In men, we showed higher levels of estradiol (E2) associated with a higher prevalence of ND but without any significant increase in renal or CVE during follow-up. CYP19A1 variants were not associated with either E2 levels or the prevalence of ND. However, 2 SNPs tested, were significantly associated with the occurrence of end stage renal failure. Altogether, we have identified 2 different metabolic ways contributing to the genetic determinants of complications associated with T2D including a gene-environment interaction.
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Hormone Signaling: Current Perspectives on the Roles of Salicylic Acid and Its Derivatives in PlantsKumar, Dhirendra, Haq, Imdadul, Chapagai, Danda, Tripathi, Diwaker, Donald, David, Hossain, Mir, Devaiah, Shivakumar 14 October 2015 (has links)
Salicylic acid (SA) is an important plant hormone with a wide range of effects on plant growth and metabolism. Plants lacking SA exhibit enhanced susceptibility to pathogens. SA plays important signaling roles in resistance against biotrophic and hemi- biotrophic phytopathogens. It is synthesized in plastids along two pathways, one involving phenylalanine ammonia lyase (PAL) and the other isochorismate synthase (ICS). In Arabidopsis , during immune response most SA is synthesized through the ICS-dependent pathway, but clearly an ICS-independent pathway also exists. Several SA effector proteins have been identified and characterized which mediate downstream SA signaling. This includes SABP, a catalase, SABP2, a methyl salicylate esterase, SABP3, a carbonic anhydrase, NPR1 (nonexpressor of pathogenesis-related 1), NPR3 (a NPR1 paralog), and NPR4 (another NPR1 paralog). NPR3 and NPR4 regulate the turnover of NPR1, a process which plays a key role in activating defense gene expression. The role of SA in abiotic stress signaling is gradually becoming clearer. Various components of SA signaling in biotic stress also appear to impact abiotic stress signaling.
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