Identification et regroupement de QTL influençant la pression artérielle en modules épistatiques et analyse de deux gènes candidats chez la souche Dahl Salt-Sensitive

L’hypertension essentielle étant un facteur majeur de morbidité, la compréhension de son l’étiologie est prépondérante. Ainsi, la découverte de nouvelles composantes ou mécanismes de régulation de la PA par l’identification de QTL et l’étude de leurs interactions s’avère une approche prometteuse. L’utilisation de souches congéniques de rats pour l’étude de l’hypertension est une stratégie payante puisqu’elle permet de masquer les effets de l’environnement, tout en gardant le caractère polygénique de la PA. Longtemps conçu comme un trait issu de l’accumulation des effets minimes des QTL, la PA est régulée par une architecture basée sur l’existence d’interactions épistatiques. L’analyse par paires de QTL individuels a permis d’établir une modularité dans l’organisation des QTL chez le rat Dahl Salt-sensitive en fonction de la présence ou de l’absence d’une interaction épistatique entre eux. Ainsi, deux modules épistatiques ont été établis; EM1 et EM2 où tous les QTL appartenant à EM1 sont épistatiques entre eux et agissent de façon additive avec les membres de EM2. Des hiérarchies dans la régulation peuvent alors être révélées si les QTL d’un même EM ont des effets opposés. L’identification de la nature moléculaire des candidats C18QTL4/Hdhd2 et C18QTL3/Tcof1, membres du EM1, et de l’interaction épistatique entre ces deux QTL, a permis, en plus, d’élucider une régulation séquentielle au sein du module. Hdhd2 pourrait agir en amont de Tcof1 et réguler ce dernier par une modification post-traductionnelle. Cette interaction est la première évidence expérimentale de la prédiction des relations entre QTL, phénomène établi par leur modularisation. Le dévoilement du fonctionnement de l’architecture génétique à la base du contrôle de la PA et la découverte des gènes responsables des QTL permettrait d’élargir les cibles thérapeutiques et donc de développer des traitements antihypertenseurs plus efficaces.Essential hypertension is a major risk factor for cardiovascular diseases. Understanding the etiology of this pathology is of the outmost importance. Thus, unraveling novel genetic components and mechanisms regulating blood pressure (BP) via QTL identification and QTL-QTL interaction analysis is a promising strategy. Congenic strains establishment is a common and fruitful means for achieving such goal. A quantitative trait, such as BP, has long been thought to result from the accumulation of infinitesimal effects exerted by multiple QTL. Nevertheless, BP is controlled by an epistasis-based architecture. Pair-wise comparisons of individual QTL based on the existence or lack-of epistatic interaction between them allowed us to establish a modularized organization of BP QTL in the Dahl Salt-sensitive model. Hence, two epistatic modules, namely EM1 and EM2 were constituted. In this fashion, any member of the EM1 is epistatic to all the other members of the same module and is additive to those of EM2. Regulatory hierarchies among BP with paradoxical effects can be revealed within each EM. The molecular identification of EM1 members, C18QTL4/Hdhd2 and C18QTL3/Tcof1, as well as the revelation of the molecular basis for their epistatic interaction enabled us to suggest a sequential regulation within this EM. Hdhd2 could act upstream of Tcof1 and regulate it by post-transcriptional modification. This interaction is the first experimental evidence derived from the predictive model of QTL modularization. The elucidation of the molecular mechanisms underlying the genetic architecture of BP, as well as the identification of the causal genes for QTL will lay the grounds for expanding therapeutic targets and for developing more efficient antihypertensive treatments

Identification de QTL à pression artérielle dans le chromosome 18 du rat et analyse des gènes candidats Adrb2 et Nedd4l associés à l’hypertension essentielle

L’hypertension constitue un facteur majeur de risque de maladies cardiovasculaires et touche à un pourcentage important de la population humaine. Il s’agit d’une maladie complexe étant donné son caractère multifactoriel. La régulation de la pression artérielle (PA) est sous contrôle de plusieurs gènes, appelés loci pour traits quantitatifs ou QTL, et elle est le résultat de leur interaction. Étant donné que la PA est un trait quantitatif sous contrôle de plusieurs composantes comme les facteurs génétiques et environnementaux, l’étude de l’hypertension est limitée chez les populations humaines. Ainsi la stratégie principale pour l’étude de cette maladie est l’identification de QTL à PA chez des souches congéniques de rat construites à partir des lignées hyper- et normotendues; à savoir les souches Dahl salt-sensitive [1] et Lewis, respectivement. Des études précédentes dans notre laboratoire ont localisé trois QTL à PA au niveau du chromosome 18 chez le rat. Au cours de ce projet, de nouvelles sous-souches ont été construites afin de raffiner la cartographie de ces QTL. Ainsi, les C18QTL1, C18QTL3 et C18QTL4 ont été définis. Des analyses moléculaires ont été effectuées sur deux gènes candidats pour le C18QTL3; à savoir, Adrb2 et Nedd4l associés précédemment à l’hypertension. La comparaison des résultats de séquençage des régions régulatrices et codantes de ces deux gènes, ainsi que leur analyse d’expression par qRT-PCR chez les souches contrastantes DSS et Lewis, n’ont pas montré de différence significative pouvant expliquer la variation du phénotype observé. Des études plus poussées devront être effectuées sur ces deux gènes et, le cas échéant, l’analyse d’autres gènes contenus dans le C18QTL3 devra être entamée afin d’identifier le gène responsable de ce QTL.Hypertension is a major risk factor in cardiovascular disease and affects a large percentage of human population. It is a complex disease because of its multifactorial nature. Blood pressure (BP) regulation is controlled by several genes, known as quantitative trait loci or QTL, and results from their interaction. Given that BP is a quantitative trait influenced by several components such as genetic and environmental factors, the study of hypertension is limited in humans. As a result, the main strategy in the study of this disease is the identification of BP QTL in congenic rat strains established from hyper- and normotensive breeds, namely, Dahl salt-sensitive [1] and Lewis. Previous studies showed the existence of three QTL in rat chromosome 18. For this project, new congenic sub-strains were developed in order to refine these QTL containing regions. Thus, C18QTL1, C18QTL3 and C18QTL4 were defined. Molecular analyses were carried out for two candidate genes contained in C18QTL3; namely Adrb2 and Nedd4l previously associated with hypertension. Comparison of the sequencing results from regulatory and coding regions of the two genes, as well as their expression analyses, showed no significant difference able to account for the variation of the observed phenotype distinguishing DSS from Lewis. Further investigation of these two genes must be conducted and, if needed, analyses of other genes contained in C18QTL3 should be undertaken in order to uncover the locus responsible for the QTL

Fungal alteration of the elemental composition of leaf litter affects shredder feeding activity

1. Leaf litter from riparian vegetation provides the main source of matter and energy for food webs of small forest streams. Shredding macroinvertebrates mostly feed on this litter when it has been colonised and conditioned by microorganisms, especially by aquatic hyphomycetes. Since shredders feed selectively, they must make foraging decisions based on the physical and chemical characteristics of the food resource, which can change depending on the identity of fungal species. 2. Here, we addressed the effect of changes in fungal assemblage structure on the elemental composi- tion of oak (Quercus robur) leaf litter and how variation in litter quality affects the feeding of a stream shredder. Leaf discs were incubated in microcosms for 2 weeks, inoculated with various fungal assemblages comprised of three species each, and offered to a shredder (Schizopelex festiva, Trichoptera: Sericostomatidae) as food. 3. This shredder ate more leaves with a high mycelial biomass, which depended on fungal assemblage composition. Leaf litter conditioned by different fungal assemblages resulted in different litter N and P concentrations. Mycelial biomass was positively related to litter P concentration, with the lowest and highest P concentrations differing by 40% at most, but not to litter N concentration, even though the lowest and highest N concentrations differed by as much as 35%. The caddisfly larvae ate more leaves with a low C/P ratio. 4. These findings suggest a key role of litter P concentration in eliciting fungal conditioning effects on shredder-mediated litter decomposition

Reducing Nurse to Patient Ratio

https://scholarlycommons.baptisthealth.net/cohort-5-ebp-showcase/1020/thumbnail.jp

Complementary actions of dopamine D2 receptor 1 agonist and anti-Vegf therapy on tumoral vessel normalization in a transgenic mouse model

International audienceAngiogenesis contributes in multiple ways to disease progression in tumors and reduces treatment efficiency. Molecular therapies targeting Vegf signaling combined with chemotherapy or other drugs exhibit promising results to improve efficacy of treatment. Dopamine has been recently proposed to be a novel safe anti-angiogenic drug that stabilizes abnormal blood vessels and increases therapeutic efficacy. Here, we aimed to identify a treatment to normalize tumoral vessels and restore normal blood perfusion in tumor tissue with a Vegf receptor inhibitor and/or a ligand of dopamine G protein-coupled receptor D2 (D2R). Dopamine, via its action on D2R, is an endogenous effector of the pituitary gland, and we took advantage of this system to address this question. We have used a previously described Hmga2/T mouse model developing haemorrhagic prolactin-secreting adenomas. In mutant mice, blood vessels are profoundly altered in tumors, and an aberrant arterial vascularization develops leading to the loss of dopamine supply. D2R agonist treatment blocks tumor growth, induces regression of the aberrant blood supply and normalizes blood vessels. A chronic treatment is able to restore the altered balance between pro- and anti-angiogenic factors. Remarkably, an acute treatment induces an upregulation of the stabilizing factor Angiopoietin 1. An anti-Vegf therapy is also effective to restrain tumor growth and improves vascular remodeling. Importantly, only the combination treatment suppresses intratumoral hemorrhage and restores blood vessel perfusion, suggesting that it might represent an attractive therapy targeting tumor vasculature. Similar strategies targeting other ligands of GPCRs involved in angiogenesis may identify novel therapeutic opportunities for cancer

BCL11A Haploinsufficiency Causes an Intellectual Disability Syndrome and Dysregulates Transcription

Intellectual disability (ID) is a common condition with considerable genetic heterogeneity. Next-generation sequencing of large cohorts has identified an increasing number of genes implicated in ID, but their roles in neurodevelopment remain largely unexplored. Here we report an ID syndrome caused by de novo heterozygous missense, nonsense, and frameshift mutations in BCL11A, encoding a transcription factor that is a putative member of the BAF swi/snf chromatin-remodeling complex. Using a comprehensive integrated approach to ID disease modeling, involving human cellular analyses coupled to mouse behavioral, neuroanatomical, and molecular phenotyping, we provide multiple lines of functional evidence for phenotypic effects. The etiological missense variants cluster in the amino-terminal region of human BCL11A, and we demonstrate that they all disrupt its localization, dimerization, and transcriptional regulatory activity, consistent with a loss of function. We show that Bcl11a haploinsufficiency in mice causes impaired cognition, abnormal social behavior, and microcephaly in accordance with the human phenotype. Furthermore, we identify shared aberrant transcriptional profiles in the cortex and hippocampus of these mouse models. Thus, our work implicates BCL11A haploinsufficiency in neurodevelopmental disorders and defines additional targets regulated by this gene, with broad relevance for our understanding of ID and related syndromes.This article is available via Open Access. Click on the Additional Link above to access the full-text via the publisher's site.Wellcome Trust (grant number WT098051)Published (open access

Effects of experimental warming, litter species, and presence of macroinvertebrates on litter decomposition and associated decomposers in a temperate mountain stream

International audienceSmall woodland streams make the majority of water courses in most watersheds. Litter decomposition is a key ecosystem process in these shaded streams, and its response to warming can have profound consequences for food webs and the carbon (C) cycle. However, these responses can be modulated by litter identity and the structure of the detrital food web. Here we report on a manipulative study aiming at evaluating the effects of warming (+2.8 °C), litter identity (chestnut (Castanea sativa) or oak (Quercus robur) litter), and the structure of the detrital food web (presence or absence of macroinvertebrates) on litter decomposition and decomposers in a small, temperate woodland stream. Warming significantly stimulated overall (microbial- + macroinvertebrate-driven) decomposition of oak and microbial-driven decomposition of chestnut. The similar shredder densities at elevated and ambient temperatures suggest that stimulated overall decomposition of oak resulted from increased activity of macroinvertebrate individuals. Stimulated microbial-driven decomposition of chestnut resulted from higher fungal activity with warming. Stimulation of litter decomposition by warming can lead to increases in the amount of C returned to the atmosphere and to a faster disappearance of litter from the benthos, with consequences to the C cycle and aquatic food webs

Alterations in Fibronectin Type III Domain Containing 1 Protein Gene Are Associated with Hypertension

<div><p>Multiple quantitative trait loci (QTLs) for blood pressure (BP) have been detected in rat models of human polygenic hypertension. Great challenges confronting us include molecular identifications of individual QTLs. We first defined the chromosome region harboring <i>C1QTL1</i> to a segment of 1.9 megabases that carries 9 genes. Among them, we identified the gene encoding the fibronectin type III domain containing 1 protein (<i>Fndc1</i>)/activator of G protein signaling 8 (<i>Ags8</i>) to be the strongest candidate for <i>C1QTL1</i>, since numerous non-synonymous mutations are found. Moreover, the 5’ <i>Fndc1</i>/<i>Ags8</i> putative promoter contains numerous mutations that can account for its differential expression in kidneys and the heart, prominent organs in modulating BP, although the Fndc1/Ags8 protein was not detectable in these organs under our experimental conditions. This work has provided the premier evidence that <i>Fndc1</i>/<i>Ags8</i> is a novel and strongest candidate gene for <i>C1QTL1</i> without completely excluding other 8 genes in the <i>C1QTL1</i>-residing interval. If proven true by future <i>in vivo</i> function studies such as single-gene <i>Fndc1</i>/<i>Ags8</i> congenics, transgenesis or targeted-gene modifications, it might represent a part of the BP genetic architecture that operates in the upstream position distant from the end-phase physiology of BP control, since it activates a Gbetagamma component in a signaling pathway. Its functional role could validate the concept that a QTL in itself can influence BP ‘indirectly’ by regulating other genes downstream in a pathway. The elucidation of the mechanisms initiated by <i>Fndc</i>/<i>Ags8</i> variations will reveal novel insights into the BP modulation via a regulatory hierarchy.</p></div