Transcriptional Regulation By Nuclear Receptor Homodimers Binding To The Direct Repeat Motif DR1 : Investigations In An in vitro Transcription System Derived From Rat Liver Nuclear Extracts

Harish, S

02 1900

Nuclear receptors (NRs) are important transcription factors involved in the regulation of a variety of physiological processes such as embryonic development, cell differentiation and homeostasis (for review, see Mangelsdorf et al., 1995 TenBaum and Baniahrned, 1997). In contrast to membrane bound receptors, they bind small lipophilic ligands and function in the nucleus as ligand-modulated transcription factors. The ligands for nuclear receptors include steroids (glucocorticoids, progestins, mineralocorticoids, androgens and estrogens), vitamin D3, retinoids, thyroid hormone, prostaglandins, farnesoids etc. Several other nuclear receptors are classified as orphan receptors for which no ligand has yet been identified. More than 300 nuclear receptors have now been identified and together these proteins comprise the single largest family of metazoan transcription factors, the nuclear receptor superfamily. Recently, a unified nomenclature has been evolved (nuclear receptor nomenclature committee, 1999), a summary of which is presented in Table 1.

Biochemistry

Nuclear Receptors (NRs)

Retinoid X Receptor (RXR)

Electro Mobility Shift Assays (EMSA)

Chromatin Assembly

Plasmids Constructs

Nuclear receptors in the Pacific oyster, Crassostrea gigas, as screening tool for determining response to environmental contaminants

Vogeler, Susanne

January 2016

Marine environments are under constant pressure from anthropogenic pollution. Chemical pollutants are introduced into the aquatic environment through waste disposal, sewage, land runoff and environmental exploitation (harbours, fisheries, tourism) leading to disastrous effects on the marine wildlife. Developmental malformations, reproduction failure including sex changes and high death rates are commonly observed in aquatic animal populations around the world. Unfortunately, the underlying molecular mechanisms of these pollution effects, in particular for marine invertebrate species, are often unknown. One proposed mechanism through which environmental pollution affects wildlife, is the disruption of nuclear receptors (NRs), ligand-binding transcription factors in animals. Environmental pollutants can directly interact with nuclear receptors, inducing incorrect signals for gene expression and subsequently disrupt developmental and physiological processes. Elucidation of the exact mechanism in invertebrates, however, is sparse due to limited understanding of invertebrate endocrinology and molecular regulatory mechanisms. Here, I have investigated the presence, expression and function of NRs in the Pacific oyster, Crassostrea gigas, and explored their interrelation with known environmental pollutants. Using a suite of molecular techniques and bioinformatics tools I demonstrate that the Pacific oyster possesses a large variety of NR homologs (43 NRs), which display individual expression profiles during embryo/larval development and supposedly fulfil distinct functions in developmental and physiological processes. Functional studies on a small subset of oyster NRs provided evidence for their ability to regulate gene expression, including interactions with DNA, other NRs or small molecules (ligand-binding). Oyster receptors also show a high likeliness to be disrupted by environmental pollutants. Computational docking showed that the retinoid X receptor ortholog, CgRXR, is able to bind and be activated by 9-cis retinoic acid and by the well-known environmental contaminant tributyltin. A potential interaction between tributyltin and the peroxisome proliferator-activated receptor ortholog CgPPAR has also been found. In addition, exposure of oyster embryos to retinoic acids and tributyltin resulted in shell deformations and developmental failure. In contrast, computer modelling of another putative target for pollutants, the retinoic acid receptor ortholog CgRAR, did not indicate interactions with common retinoic acids, supporting a recently developed theory of loss of retinoid binding in molluscan RARs. Sequence analyses revealed six residues in the receptor sequence, which prevent the successful interaction with retinoid ligands. In conclusion, this investigative work aids the understanding of fundamental processes in invertebrates, such as gene expression and endocrinology, as well as further understanding and prediction of effects of environmental pollutants on marine invertebrates.

363.739

Rôle des récepteurs X aux rétinoïdes dans le contrôle des processus émotionnels chez la souris / The role of retinoid X receptors in the control of emotional processes in mice

Krzyzosiak, Agnieszka

20 January 2012

Rxry est l’un des récepteurs nucléaires impliqués dans la signalisation à l’acide rétinoïque. L’ablation de Rxry chez les souris provoque le développement de comportements de type dépressifs - désespoir et d’anhédonie. De tels déficits pouvaient être normalisés par des anti-dépresseurs tels que la fluoxetine, suggérant donc l’importance de telles données pour la recherche sur la dépression.Nous avons trouvé que le NAcSh est une structure impliquée dans le contrôle par Rxry des comportements motivés étant donné que la ré-expression de Rxry dans cette structure par le virus normalise les déficits comportementaux chez les souris Rxry-/-. Nous avons démontré que le récepteur Drd2 qui est sous-exprimé dans le NAcSh des souris Rxry-/- est nécessaire dans le contrôle des comportements affectifs étant donné que le blocage des activités du Drd2 par infusion de raclopride dans le NAcSh empêche le rétablissement du phénotype Rxry-/- par le virus AAV2-RxryCette observation est étayée par le rétablissement fonctionnel des déficits comportementaux par injection de virus ou traitement à la fluoxetine qui augmentent l’expression du Drd2 dans le NAcSh chez les souris Rxry-/-. Ces données sont la première démonstration que les récepteurs aux rétinoides sont impliqués dans le contrôle des comportements affectifs chez la souris.Nous avons observé que l’ablation de Rxry provoquent une hyperactivité du NAcSh. Nous avons observé des phénomènes similaires dans un modèle de stresse par défaite sociale. L’existence de telle corrélation dans deux modèles animaux distincts de comportements dépressifs suggère que l’hyperactivité du NacSh pourrait être un phénomène commun sous-tendant la dépression. / Rxry is one of nuclear receptors involved in retinoic acid signalling. Ablation of this receptor in mice leads to development of depressive-like behaviours - despair and anhedonia. Importantly, such deficits could be normalized by antidepressant, fluoxetine chronic treatment, suggesting thus the relevance of such data for research into depression. We identified that NAcSh is a key structure implicated in Rxry control of motivated behaviours as virus mediated re-expression of Rxry in this brain region normalized behavioural deficits of Rxry-/- mice. We demonstrated that dopaminergic D2 receptor – Drd2, which is underexpressed in the NAcSh of Rxry-/- mice is necessary for Rxry control of affective behaviours since blocking of Drd2 activities by infusion of raclopride into the NAcSh prevented AAV2-Rxry mediated rescue of Rxry-/- phenotype. This observation was further supported by functional rescue of behavioral deficits by virus mediated or chronic fluoxetine treatment increase of Drd2 expression in the NAcSh of Rxry-/- mice. Such data provide the first evidence that retinoid receptors are implicated in the control of affective behaviours in mice.We also identified that molecular changes caused by Rxry ablation lead to hyperactivity of the NAcSh. Importantly, we observed similar phenomenon in etiologically different model of depression – social defeat stress model. Existence of such correlation in two distinct animal models of depressive behaviours, suggests that NAcSh hyperactivity might be a common phenomenon underlying depression.

Récepteurs X aux rétinoïdes

Recepteurs dopaminergique D2

Depression

Noyau accumbens

Processus émotionnels

Retinoid X receptors

Dopaminergic D2 receptors

Depression

Nucleus accumbens

Emotional precesses

572.6

572.8

Structural and biochemical insights into catalytic mechanisms of carotenoid cleavage oxygenases

Sui, Xuewu

08 February 2017

No description available.

Biochemistry

Biology

Biophysics

Biomedical Research

Pharmacology

Carotenoids

apocarotenoid

retinoid

carotenoid cleavage oxygenases

non-heme oxygenase

oxygen utilization

oxygen activation

mutagenesis

protein structure and function

iron coordination

visual function

carotenoid metabolism

APOCAROTENOIDS MODULATE RETINOID RECEPTORS

Eroglu, Abdulkerim

12 June 2012

No description available.

Biochemistry

Beta-apocarotenoids

Retinoic acid

Vitamin A

Beta-apo-13-carotenone

Retinoic Acid Receptors (RARs)

Retinoid X Receptor alpha (RXR&945

)

Retinoid Signaling

Beta-apo-14&8217

-carotenal

Beta-apo-14&8217

-carotenoic acid

Apo-lycopenoids

Apo-13-lyc

Estudos por modelagem e dinâmica molecular integradas a técnicas físicas para biomoléculas em solução - interação de receptores nucleares a elementos responsivos no DNA e dinâmica inter-domínios da celobiohidrolase I / Integrated experimental biophysics and molecular dynamics simulations of biomolecules in solution - the interaction of nuclear receptors with DNA response elements and the inter-domain dynamics of Cellobiohydrolase I

Lima, Leonardo Henrique França de

26 September 2011

Movimentos coletivos prestam um papel fundamental na dinâmica e energética de biomoléculas em solução. Estes movimentos permitem o acoplamento de regiões significativamente distantes, apresentando considerável influência, por exemplo, no alosterismo para a formação de complexos macromoleculares e no funcionamento integrado de proteínas multidomínios como \"máquinas moleculares\". Neste trabalho de doutoramento, serão apresentados os resultados referentes à aplicação conjunta de técnicas experimentais biofísicas, de modelagem estrutural e de dinâmica molecular no estudo de dois sistemas para os quais estes movimentos coletivos demonstram considerável importância funcional. Para a interação do receptor nuclear do ácido 9-cis-retinóico com seu elemento responsivo específico no DNA (HRE), a comparação de estudos de dinâmica molecular com ensaios de afinidade por anisotropia de fluorescência sugere que a resistência inicial para a associação do monômero, seguida da acentuada colaboratividade na associação do dímero é regida por um impedimento da associação do domínio de ligação ao DNA (DBD) para o primeiro à sequência responsiva devido, em última análise, a uma não complementaridade dos modos coletivos mútuos. Este impedimento para a associação monomérica inicial é mais acentuado para o monômero 5\' (para o qual a menor especificidade de ligação à seqüência específica já é bem documentada), devido aos efeitos conjuntos de um \"defeito\" natural no empacotamento de bases da seqüência responsiva, que se manifesta mais significativamente na interface entre o meio-sítio 5\' e a seqüência espaçadora, e dos modos vibracionais entre os dois sítios decorrentes de seu faseamento relativo na topologia do DNA na seqüência responsiva, caracterizando um mecanismo \"chave e fechadura\" para a interação obrigatoriamente simultânea dos dois monômeros ao DNA. No segundo caso, um estudo integrado utilizando a técnica experimental de espalhamento de raios X a baixos ângulos e uma abordagem de modelagem estrutural baseada em dinâmica molecular foi realizado para a celobiohidrolase I de Trichoderma harziannum. Este estudo permitiu tanto a elaboração de um modelo estrutural de maior resolução para esta enzima de alto potencial biotecnológico como a constatação dos possíveis mecanismos moleculares a partir dos quais as glicosilações no peptídeo conector impõem restrições à orientação e modos vibracionais entre seus dois domínios de forma condizente com sua ação concertada na interação e no deslize da enzima sobre a superfície celulósica, ambos de fundamental importância para a processividade da enzima na hidrólise do substrato microcristalino. / Collective motions play a fundamental role in solution biomolecule dynamics and energetics. These movements can couple very distant regions in the protein structures affection, for instance, allosteric mechanisms, the establishment of macromolecular complexes, and on the integrated function of multidomain proteins as molecullar machines. In this thesis, we present results concerning to the joint use of experimental biophysical techniques, structural modeling and molecular dynamics simulations on the study of two systems for which these collective motions have substantial importance. First, we study the interaction of the nuclear retinoid X receptor with its specific DNA hormone response element (HRE) using a combination of molecular dynamics simulations and affinity assays performed by using fluorescence anisotropy. We find out that collective motions mediate the low binding affinity of monomers and the high cooperative binding of HRE dimers. The lower binding affinity of the monomer is more prominent for 5´ monomers. This occur due to an natural ineffective stacking of the last base pair step at the 5´-half-site and to the phasing of the two binding half-sites in the DNA topology, that impose a collective motions that tends to occlude the 5´ binding site. This behavior, in turn, is concurrent with the well known 3´ polarity and the decreased binding specificity to the 5´ half site for the hRXRα monomer. This same pattern impose a lock-and-key mechanisms dependent on the binding of the full dimer. Second, an integrated Small angle X ray scattering and molecular dynamics based structural modeling was used to comprehend the interdomain motions of cellobiohydrolase I of Trichoderma harziannum. We manage to build a refined model for this enzime, with important biotechnological potential. We also provide insights into molecular mechanisms of linker and glycosylation imposed restraints on the orientation and vibrational modes of the full-length enzyme, supporting a mechanism of sliding of on the cellulose surface. This mechanism is fundamental for the high processivity on the hydrolysis of microcrystalline cellulose.

Trichoderma harziannum

Trichoderma harziannum

Anisotropia de fluorescência

Cellobiohydrolase I

Celobiohidrolase I

Dinâmica molecular

Fluorescence anisotropy

Molecular dynamics

Nuclear receptors

Receptor do ácido 9-cis-retinóico

Receptores Nucleares

Retinoid X receptor

Small angle X-ray scattering

Estudos por modelagem e dinâmica molecular integradas a técnicas físicas para biomoléculas em solução - interação de receptores nucleares a elementos responsivos no DNA e dinâmica inter-domínios da celobiohidrolase I / Integrated experimental biophysics and molecular dynamics simulations of biomolecules in solution - the interaction of nuclear receptors with DNA response elements and the inter-domain dynamics of Cellobiohydrolase I

Leonardo Henrique França de Lima

26 September 2011

Movimentos coletivos prestam um papel fundamental na dinâmica e energética de biomoléculas em solução. Estes movimentos permitem o acoplamento de regiões significativamente distantes, apresentando considerável influência, por exemplo, no alosterismo para a formação de complexos macromoleculares e no funcionamento integrado de proteínas multidomínios como \"máquinas moleculares\". Neste trabalho de doutoramento, serão apresentados os resultados referentes à aplicação conjunta de técnicas experimentais biofísicas, de modelagem estrutural e de dinâmica molecular no estudo de dois sistemas para os quais estes movimentos coletivos demonstram considerável importância funcional. Para a interação do receptor nuclear do ácido 9-cis-retinóico com seu elemento responsivo específico no DNA (HRE), a comparação de estudos de dinâmica molecular com ensaios de afinidade por anisotropia de fluorescência sugere que a resistência inicial para a associação do monômero, seguida da acentuada colaboratividade na associação do dímero é regida por um impedimento da associação do domínio de ligação ao DNA (DBD) para o primeiro à sequência responsiva devido, em última análise, a uma não complementaridade dos modos coletivos mútuos. Este impedimento para a associação monomérica inicial é mais acentuado para o monômero 5\' (para o qual a menor especificidade de ligação à seqüência específica já é bem documentada), devido aos efeitos conjuntos de um \"defeito\" natural no empacotamento de bases da seqüência responsiva, que se manifesta mais significativamente na interface entre o meio-sítio 5\' e a seqüência espaçadora, e dos modos vibracionais entre os dois sítios decorrentes de seu faseamento relativo na topologia do DNA na seqüência responsiva, caracterizando um mecanismo \"chave e fechadura\" para a interação obrigatoriamente simultânea dos dois monômeros ao DNA. No segundo caso, um estudo integrado utilizando a técnica experimental de espalhamento de raios X a baixos ângulos e uma abordagem de modelagem estrutural baseada em dinâmica molecular foi realizado para a celobiohidrolase I de Trichoderma harziannum. Este estudo permitiu tanto a elaboração de um modelo estrutural de maior resolução para esta enzima de alto potencial biotecnológico como a constatação dos possíveis mecanismos moleculares a partir dos quais as glicosilações no peptídeo conector impõem restrições à orientação e modos vibracionais entre seus dois domínios de forma condizente com sua ação concertada na interação e no deslize da enzima sobre a superfície celulósica, ambos de fundamental importância para a processividade da enzima na hidrólise do substrato microcristalino. / Collective motions play a fundamental role in solution biomolecule dynamics and energetics. These movements can couple very distant regions in the protein structures affection, for instance, allosteric mechanisms, the establishment of macromolecular complexes, and on the integrated function of multidomain proteins as molecullar machines. In this thesis, we present results concerning to the joint use of experimental biophysical techniques, structural modeling and molecular dynamics simulations on the study of two systems for which these collective motions have substantial importance. First, we study the interaction of the nuclear retinoid X receptor with its specific DNA hormone response element (HRE) using a combination of molecular dynamics simulations and affinity assays performed by using fluorescence anisotropy. We find out that collective motions mediate the low binding affinity of monomers and the high cooperative binding of HRE dimers. The lower binding affinity of the monomer is more prominent for 5´ monomers. This occur due to an natural ineffective stacking of the last base pair step at the 5´-half-site and to the phasing of the two binding half-sites in the DNA topology, that impose a collective motions that tends to occlude the 5´ binding site. This behavior, in turn, is concurrent with the well known 3´ polarity and the decreased binding specificity to the 5´ half site for the hRXRα monomer. This same pattern impose a lock-and-key mechanisms dependent on the binding of the full dimer. Second, an integrated Small angle X ray scattering and molecular dynamics based structural modeling was used to comprehend the interdomain motions of cellobiohydrolase I of Trichoderma harziannum. We manage to build a refined model for this enzime, with important biotechnological potential. We also provide insights into molecular mechanisms of linker and glycosylation imposed restraints on the orientation and vibrational modes of the full-length enzyme, supporting a mechanism of sliding of on the cellulose surface. This mechanism is fundamental for the high processivity on the hydrolysis of microcrystalline cellulose.

Trichoderma harziannum

Anisotropia de fluorescência

Celobiohidrolase I

Dinâmica molecular

Receptor do ácido 9-cis-retinóico

Receptores Nucleares

Trichoderma harziannum

Cellobiohydrolase I

Fluorescence anisotropy

Molecular dynamics

Nuclear receptors

Retinoid X receptor

Small angle X-ray scattering

Regulace genové exprese jadernými receptory ve specifickém metabolickém kontextu - evoluční perspektiva / Gene expression regulation by nuclear receptors in a specific metabolic context - evolutionary perspective

Kaššák, Filip

January 2021

In animals, some of the most critical regulators of gene expression are nuclear hormone receptors (NRs) and their coregulators, specifically the Mediator complex. Of particular interest are the NRs implicated in metabolic and developmental regulation and in carcinogenesis: thyroid hormone receptors (TRs) and retinoid X receptors (RXRs). In this work, I venture to elucidate some aspects of gene expression regulation by these NRs: the degree of evolutionary conservation of signalling based on NRs and their coregulators; the mechanisms of negative regulation by NRs; and possible implications of these findings for clinical medicine. State-of-the-art bioinformatical, genome editing and microscopic techniques are applied at three levels of animal evolution to study NRs and Mediator. Reverse genomics in human patients suffering from the syndrome of resistance to thyroid hormones β are used to infer the structure and function of TRβ subdomains. Alignments, binding studies and in vivo experiments in Trichoplax adhaerens allow identification of a close orthologue of human RXR at the basis of metazoan evolution. Employing database queries, genome editing and microscopy, we describe a correct orthologue of the Mediator subunit 28 in Caenorhabditis elegans, indicating a complete homology of the Mediator complex...