Dissecting cell cycle protein complexes using the pptimized yeast cytosine deaminase protein-fragment complementation assay “You too can play with an edge”

Ear, Po Hien

11 1900

Les protéines sont les produits finaux de la machinerie génétique. Elles jouent des rôles essentiels dans la définition de la structure, de l'intégrité et de la dynamique de la cellule afin de promouvoir les diverses transformations chimiques requises dans le métabolisme et dans la transmission des signaux biochimique. Nous savons que la doctrine centrale de la biologie moléculaire: un gène = un ARN messager = une protéine, est une simplification grossière du système biologique. En effet, plusieurs ARN messagers peuvent provenir d’un seul gène grâce à l’épissage alternatif. De plus, une protéine peut adopter plusieurs fonctions au courant de sa vie selon son état de modification post-traductionelle, sa conformation et son interaction avec d’autres protéines. La formation de complexes protéiques peut, en elle-même, être déterminée par l’état de modifications des protéines influencées par le contexte génétique, les compartiments subcellulaires, les conditions environmentales ou être intrinsèque à la croissance et la division cellulaire. Les complexes protéiques impliqués dans la régulation du cycle cellulaire sont particulièrement difficiles à disséquer car ils ne se forment qu’au cours de phases spécifiques du cycle cellulaire, ils sont fortement régulés par les modifications post-traductionnelles et peuvent se produire dans tous les compartiments subcellulaires. À ce jour, aucune méthode générale n’a été développée pour permettre une dissection fine de ces complexes macromoléculaires. L'objectif de cette thèse est d'établir et de démontrer une nouvelle stratégie pour disséquer les complexes protéines formés lors du cycle cellulaire de la levure Saccharomyces cerevisiae (S. cerevisiae). Dans cette thèse, je décris le développement et l'optimisation d'une stratégie simple de sélection basée sur un essai de complémentation de fragments protéiques en utilisant la cytosine déaminase de la levure comme sonde (PCA OyCD). En outre, je décris une série d'études de validation du PCA OyCD afin de l’utiliser pour disséquer les mécanismes d'activation des facteurs de transcription et des interactions protéine-protéines (IPPs) entre les régulateurs du cycle cellulaire. Une caractéristique clé du PCA OyCD est qu'il peut être utilisé pour détecter à la fois la formation et la dissociation des IPPs et émettre un signal détectable (la croissance des cellules) pour les deux types de sélections. J'ai appliqué le PCA OyCD pour disséquer les interactions entre SBF et MBF, deux facteurs de transcription clés régulant la transition de la phase G1 à la phase S. SBF et MBF sont deux facteurs de transcription hétérodimériques composés de deux sous-unités : une protéine qui peut lier directement l’ADN (Swi4 ou Mbp1, respectivement) et une protéine commune contenant un domain d’activation de la transcription appelée Swi6. J'ai appliqué le PCA OyCD afin de générer un mutant de Swi6 qui restreint ses activités transcriptionnelles à SBF, abolissant l’activité MBF. Nous avons isolé des souches portant des mutations dans le domaine C-terminal de Swi6, préalablement identifié comme responsable dans la formation de l’interaction avec Swi4 et Mbp1, et également important pour les activités de SBF et MBF. Nos résultats appuient un modèle où Swi6 subit un changement conformationnel lors de la liaison à Swi4 ou Mbp1. De plus, ce mutant de Swi6 a été utilisé pour disséquer le mécanisme de régulation de l’entrée de la cellule dans un nouveau cycle de division cellulaire appelé « START ». Nous avons constaté que le répresseur de SBF et MBF nommé Whi5 se lie directement au domaine C-terminal de Swi6. Finalement, j'ai appliqué le PCA OyCD afin de disséquer les complexes protéiques de la kinase cycline-dépendante de la levure nommé Cdk1. Cdk1 est la kinase essentielle qui régule la progression du cycle cellulaire et peut phosphoryler un grand nombre de substrats différents en s'associant à l'une des neuf protéines cycline régulatrice (Cln1-3, Clb1-6). Je décris une stratégie à haut débit, voir à une échelle génomique, visant à identifier les partenaires d'interaction de Cdk1 et d’y associer la cycline appropriée(s) requise(s) à l’observation d’une interaction en utilisant le PCA OyCD et des souches délétées pour chacune des cyclines. Mes résultats nous permettent d’identifier la phase(s) du cycle cellulaire où Cdk1 peut phosphoryler un substrat particulier et la fonction potentielle ou connue de Cdk1 pendant cette phase. Par exemple, nous avons identifié que l’interaction entre Cdk1 et la γ-tubuline (Tub4) est dépendante de Clb3. Ce résultat est conforme au rôle de Tub4 dans la nucléation et la croissance des faisceaux mitotiques émanant des centromères. Cette stratégie peut également être appliquée à l’étude d'autres IPPs qui sont contrôlées par des sous-unités régulatrices. / Proteins are the end-products of gene interpretative machinery. Proteins serve essential roles in defining the structure, integrity and dynamics of the cell and mediate most chemical transformations needed for everything from metabolic catalysis to signal transduction. We know that the central dogma of molecular biology, one gene = one mRNA = one protein is a gross simplification and that a protein may do different things depending on the form in which its mRNA was spliced, how and where it is post-translationally modified, what conformational state it may be in or finally, which other proteins it may interact with. Formation of protein complexes may, themselves, be governed by the states in which proteins are expressed in specific cells, cellular compartments or under specific conditions or dynamic phases such has growth or division. Protein complexes involved in mitotic cell cycle regulation are particularly challenging to dissect since they could only form during specific phases of the cell cycle, are highly regulated by post-translational modifications and can be found in any subcellular compartments. To date, no general methods have been developed to allow fine dissection of these protein complexes. The goal of this thesis was to establish and demonstrate a novel strategy for dissecting protein complexes regulating the budding yeast Saccharomyces cerevisiae (S. cerevisiae) mitotic cell cycle. In this thesis, I describe my development and optimization of a simple survival-selection Protein-fragment Complementation Assay using the prodrug-converting enzyme, yeast cytosine deaminase as reporter (OyCD PCA). I further describe, in a series of proof of principle studies, applications of the OyCD PCA to dissect the mechanism of transcriptional activation by key mitotic transcription factors and to dissect protein-protein interactions (PPIs) among regulators of the mitotic cell cycle. A key feature of the OyCD PCA is that it can be used to detect both formation and disruption of PPIs by virtue of having positive readouts for both assays. I applied the OyCD PCA in a strategy to dissect interactions between the key transcription factors of the G1/S phase: SBF and MBF. These two heterodimeric transcription factors are composed of, respectively, two distinct DNA-binding subunits named Swi4 and Mbp1 and a common transcription activation subunit called Swi6. I took advantage of the dual selection by OyCD PCA to engineer a specific mutant of Swi6 in order to demonstrate the rewiring of a transcriptional network. We isolated Swi6 with mutations found in its C-terminal domain previously identified for binding Swi4 and Mbp1 and important for SBF and MBF activities. Our results support a model where Swi6 undergoes a conformational change upon binding to Swi4 or Mbp1. In addition, this Swi6 mutant was used to dissect the regulatory mechanism that governs the entry of S. cerevisiae to a new round of cell division also known as START. We found that the SBF and MBF repressor Whi5 directly binds to the C-terminal domain of Swi6. Finally, I applied the OyCD PCA to dissect the yeast cyclin dependent kinase Cdk1-protein complexes. Cdk1 is the essential kinase that regulates cell cycle progression and can phosphorylate a large number of different substrates by teaming up with one of nine cyclin regulatory proteins (Cln1-3, Clb1-6). I describe a strategy to identify interaction partners of Cdk1 that can easily be scaled up for a genome-wide screen and associate the complexes with the appropriate cyclin(s) required for mediating the interaction using the OyCD PCA and deletion of the cyclin genes. My results allow us to postulate which phase(s) of the mitotic cell cycle Cdk1 may phosphorylate proteins and what function potential or known substrates of Cdk1 may take on during that phase(s). For example, we identified the interaction between Cdk1 and the γ-tubulin (Tub4) to be dependent upon Clb3, consistent with its role in mediating nucleation and growth of mitotic microtubule bundles on the spindle pole body. This strategy can also be applied to study other PPIs that are contingent upon accessory subunits.

Saccharomyces cerevisiae

sélection positive et négative

cytosine désaminase de levure

5-fluorocytosine

cycle cellulaire

facteurs de transcription

Swi6

activités transcriptionnelles

mécanisme de régulation

phase G1/S du cycle cellulaire

kinase dépendante des cyclines (CDK)

cycline

complexes entre substrats et protéines

interactions protéine-protéines

positive and negative selection

Protein-fragment Complementation Assay

yeast cytosine deaminase

5-fluorocytosine

cell cycle

transcription factors

rewiring transcriptional activities

mechanism of regulation, G1/S phase

cyclin dependent kinase Cdk1

cyclin

protein-protein interactions

substrates and protein complexes

Dissecting cell cycle protein complexes using the pptimized yeast cytosine deaminase protein-fragment complementation assay “You too can play with an edge”

Ear, Po Hien

11 1900

Les protéines sont les produits finaux de la machinerie génétique. Elles jouent des rôles essentiels dans la définition de la structure, de l'intégrité et de la dynamique de la cellule afin de promouvoir les diverses transformations chimiques requises dans le métabolisme et dans la transmission des signaux biochimique. Nous savons que la doctrine centrale de la biologie moléculaire: un gène = un ARN messager = une protéine, est une simplification grossière du système biologique. En effet, plusieurs ARN messagers peuvent provenir d’un seul gène grâce à l’épissage alternatif. De plus, une protéine peut adopter plusieurs fonctions au courant de sa vie selon son état de modification post-traductionelle, sa conformation et son interaction avec d’autres protéines. La formation de complexes protéiques peut, en elle-même, être déterminée par l’état de modifications des protéines influencées par le contexte génétique, les compartiments subcellulaires, les conditions environmentales ou être intrinsèque à la croissance et la division cellulaire. Les complexes protéiques impliqués dans la régulation du cycle cellulaire sont particulièrement difficiles à disséquer car ils ne se forment qu’au cours de phases spécifiques du cycle cellulaire, ils sont fortement régulés par les modifications post-traductionnelles et peuvent se produire dans tous les compartiments subcellulaires. À ce jour, aucune méthode générale n’a été développée pour permettre une dissection fine de ces complexes macromoléculaires. L'objectif de cette thèse est d'établir et de démontrer une nouvelle stratégie pour disséquer les complexes protéines formés lors du cycle cellulaire de la levure Saccharomyces cerevisiae (S. cerevisiae). Dans cette thèse, je décris le développement et l'optimisation d'une stratégie simple de sélection basée sur un essai de complémentation de fragments protéiques en utilisant la cytosine déaminase de la levure comme sonde (PCA OyCD). En outre, je décris une série d'études de validation du PCA OyCD afin de l’utiliser pour disséquer les mécanismes d'activation des facteurs de transcription et des interactions protéine-protéines (IPPs) entre les régulateurs du cycle cellulaire. Une caractéristique clé du PCA OyCD est qu'il peut être utilisé pour détecter à la fois la formation et la dissociation des IPPs et émettre un signal détectable (la croissance des cellules) pour les deux types de sélections. J'ai appliqué le PCA OyCD pour disséquer les interactions entre SBF et MBF, deux facteurs de transcription clés régulant la transition de la phase G1 à la phase S. SBF et MBF sont deux facteurs de transcription hétérodimériques composés de deux sous-unités : une protéine qui peut lier directement l’ADN (Swi4 ou Mbp1, respectivement) et une protéine commune contenant un domain d’activation de la transcription appelée Swi6. J'ai appliqué le PCA OyCD afin de générer un mutant de Swi6 qui restreint ses activités transcriptionnelles à SBF, abolissant l’activité MBF. Nous avons isolé des souches portant des mutations dans le domaine C-terminal de Swi6, préalablement identifié comme responsable dans la formation de l’interaction avec Swi4 et Mbp1, et également important pour les activités de SBF et MBF. Nos résultats appuient un modèle où Swi6 subit un changement conformationnel lors de la liaison à Swi4 ou Mbp1. De plus, ce mutant de Swi6 a été utilisé pour disséquer le mécanisme de régulation de l’entrée de la cellule dans un nouveau cycle de division cellulaire appelé « START ». Nous avons constaté que le répresseur de SBF et MBF nommé Whi5 se lie directement au domaine C-terminal de Swi6. Finalement, j'ai appliqué le PCA OyCD afin de disséquer les complexes protéiques de la kinase cycline-dépendante de la levure nommé Cdk1. Cdk1 est la kinase essentielle qui régule la progression du cycle cellulaire et peut phosphoryler un grand nombre de substrats différents en s'associant à l'une des neuf protéines cycline régulatrice (Cln1-3, Clb1-6). Je décris une stratégie à haut débit, voir à une échelle génomique, visant à identifier les partenaires d'interaction de Cdk1 et d’y associer la cycline appropriée(s) requise(s) à l’observation d’une interaction en utilisant le PCA OyCD et des souches délétées pour chacune des cyclines. Mes résultats nous permettent d’identifier la phase(s) du cycle cellulaire où Cdk1 peut phosphoryler un substrat particulier et la fonction potentielle ou connue de Cdk1 pendant cette phase. Par exemple, nous avons identifié que l’interaction entre Cdk1 et la γ-tubuline (Tub4) est dépendante de Clb3. Ce résultat est conforme au rôle de Tub4 dans la nucléation et la croissance des faisceaux mitotiques émanant des centromères. Cette stratégie peut également être appliquée à l’étude d'autres IPPs qui sont contrôlées par des sous-unités régulatrices. / Proteins are the end-products of gene interpretative machinery. Proteins serve essential roles in defining the structure, integrity and dynamics of the cell and mediate most chemical transformations needed for everything from metabolic catalysis to signal transduction. We know that the central dogma of molecular biology, one gene = one mRNA = one protein is a gross simplification and that a protein may do different things depending on the form in which its mRNA was spliced, how and where it is post-translationally modified, what conformational state it may be in or finally, which other proteins it may interact with. Formation of protein complexes may, themselves, be governed by the states in which proteins are expressed in specific cells, cellular compartments or under specific conditions or dynamic phases such has growth or division. Protein complexes involved in mitotic cell cycle regulation are particularly challenging to dissect since they could only form during specific phases of the cell cycle, are highly regulated by post-translational modifications and can be found in any subcellular compartments. To date, no general methods have been developed to allow fine dissection of these protein complexes. The goal of this thesis was to establish and demonstrate a novel strategy for dissecting protein complexes regulating the budding yeast Saccharomyces cerevisiae (S. cerevisiae) mitotic cell cycle. In this thesis, I describe my development and optimization of a simple survival-selection Protein-fragment Complementation Assay using the prodrug-converting enzyme, yeast cytosine deaminase as reporter (OyCD PCA). I further describe, in a series of proof of principle studies, applications of the OyCD PCA to dissect the mechanism of transcriptional activation by key mitotic transcription factors and to dissect protein-protein interactions (PPIs) among regulators of the mitotic cell cycle. A key feature of the OyCD PCA is that it can be used to detect both formation and disruption of PPIs by virtue of having positive readouts for both assays. I applied the OyCD PCA in a strategy to dissect interactions between the key transcription factors of the G1/S phase: SBF and MBF. These two heterodimeric transcription factors are composed of, respectively, two distinct DNA-binding subunits named Swi4 and Mbp1 and a common transcription activation subunit called Swi6. I took advantage of the dual selection by OyCD PCA to engineer a specific mutant of Swi6 in order to demonstrate the rewiring of a transcriptional network. We isolated Swi6 with mutations found in its C-terminal domain previously identified for binding Swi4 and Mbp1 and important for SBF and MBF activities. Our results support a model where Swi6 undergoes a conformational change upon binding to Swi4 or Mbp1. In addition, this Swi6 mutant was used to dissect the regulatory mechanism that governs the entry of S. cerevisiae to a new round of cell division also known as START. We found that the SBF and MBF repressor Whi5 directly binds to the C-terminal domain of Swi6. Finally, I applied the OyCD PCA to dissect the yeast cyclin dependent kinase Cdk1-protein complexes. Cdk1 is the essential kinase that regulates cell cycle progression and can phosphorylate a large number of different substrates by teaming up with one of nine cyclin regulatory proteins (Cln1-3, Clb1-6). I describe a strategy to identify interaction partners of Cdk1 that can easily be scaled up for a genome-wide screen and associate the complexes with the appropriate cyclin(s) required for mediating the interaction using the OyCD PCA and deletion of the cyclin genes. My results allow us to postulate which phase(s) of the mitotic cell cycle Cdk1 may phosphorylate proteins and what function potential or known substrates of Cdk1 may take on during that phase(s). For example, we identified the interaction between Cdk1 and the γ-tubulin (Tub4) to be dependent upon Clb3, consistent with its role in mediating nucleation and growth of mitotic microtubule bundles on the spindle pole body. This strategy can also be applied to study other PPIs that are contingent upon accessory subunits.

Saccharomyces cerevisiae

sélection positive et négative

cytosine désaminase de levure

5-fluorocytosine

cycle cellulaire

facteurs de transcription

Swi6

activités transcriptionnelles

mécanisme de régulation

phase G1/S du cycle cellulaire

kinase dépendante des cyclines (CDK)

cycline

complexes entre substrats et protéines

interactions protéine-protéines

positive and negative selection

Protein-fragment Complementation Assay

yeast cytosine deaminase

5-fluorocytosine

cell cycle

transcription factors

rewiring transcriptional activities

mechanism of regulation, G1/S phase

cyclin dependent kinase Cdk1

cyclin

protein-protein interactions

substrates and protein complexes

Beyond hairballs: depicting complexity of a kinase-phosphatase network in the budding yeast

Abd-Rabbo, Diala

01 1900

No description available.

Réseau des kinases-phosphatases

Saccharomyces cerevisiae

Complexité des réseaux

Structure hiérarchique des réseaux

Propriétés topologiques

Intégration de données multi-omiques

Kinase-phosphatase network

Network complexity

Network hierarchical structure

Network decomposition algorithms

Topological properties

Integration of multi-omics data

Identificação de fatores epigenéticos associados às complicações crônicas em portadores de diabetes mellitus tipo1 / Identification of epigenetic factors associated with chronic complications in patients with type 1 diabetes mellitus

Bezerra, Daniele Pereira dos Santos

26 April 2018

INTRODUÇÃO: Fatores associados à etiopatogenia das complicações diabéticas, incluindo hiperglicemia e estresse oxidativo, podem causar alterações epigenéticas que modificam a expressão de genes em células-alvo, sem alterar sua sequência de DNA. São considerados mecanismos epigenéticos: (1) as modificações pós-traducionais das histonas; (2) a metilação do DNA e (3) a ação dos micro-RNAs (miRNAs); todos já foram reconhecidos na patogênese da \"memória metabólica\", situação na qual a hiperglicemia continua a exercer efeitos deletérios prolongados mesmo depois de ser normalizada. A sirtuína-1 é uma enzima que causa modificações pós-traducionais das histonas por sua atividade de histona desacetilase, silenciando a transcrição gênica. O silenciamento gênico também pode ocorrer pela ação da DNA metiltransferase 1 (DNMT1), enzima que adiciona um grupamento metil (CH3) na posição 5 de resíduos de citosina localizadas em ilhas CpG presentes nas regiões promotoras dos genes. Os miRNAs constituem uma classe de pequenos RNAs não codificadores com cerca de 19 a 25 nucleotídeos que controlam a expressão gênica por meio da repressão da tradução ou da degradação do RNA mensageiro-alvo. As hipóteses do presente estudo são (1) que exista um perfil sérico de miRNAs associado à presença ou ausência de complicações crônicas e (2) que existam variantes em genes relacionados à desacetilação das histonas e à metilação de citosinas que poderiam predispor ao aparecimento das complicações diabéticas, o que se constituiria na \"genética da epigenética\". OBJETIVOS: (1) caracterizar e comparar o perfil de miRNAs sérico de pacientes com diabetes mellitus tipo 1 (DM1) sem nenhuma complicação microvascular versus aqueles com três complicações microvasculares: retinopatia diabética (RD), doença renal diabética (DRD) e neuropatia diabética, para identificar vias epigeneticamente moduladas nesses dois grupos de pacientes e (2) avaliar a frequência de polimorfismos de um único nucleotídeo nos genes que codificam as enzimas DNMT1 e sirtuína-1 e suas associações com cada uma das complicações microvasculares em pacientes com DM1. MÉTODOS: O perfil sérico de 381 miRNAs foi avaliado com o uso do estojo comercial Taqman® Human MicroRNA Array A em 10 pacientes bem caracterizados clínica e laboratorialmente divididos em dois grupos: Pacientes com DM1 sem complicações [sem DRD (Clearance de creatinina > 90 ml/min/1,73 m2 e excreção urinária de albumina < 20 mg/g de creatinina), sem polineuropatia sensitivo-motora distal (ausência de sintomas sugestivos de neuropatia, sensibilidade térmica e dolorosa e reflexo aquileu normais), sem neuropatia autonômica cardiovascular (NAC) e sem RD] e Pacientes com DM1 com complicações [DRD (Clearance de creatinina < 60 ml/min/1,73 m2 e excreção urinária de albumina > 200 mg/g de creatinina), com polineuropatia sensitiva-motora distal, com NAC instalada e RD moderada ou grave]. Os cinco miRNAs mais diferencialmente expressos foram validados em uma casuística bem caracterizada de 20 pacientes com DM1 sem nenhuma complicação e 27 com todas as complicações microvasculares, com o emprego do estojo comercial TaqMan(TM) Advanced miRNA cDNA Synthesis. A avaliação da frequência de polimorfismos de um único nucleotídeo nos genes que codificam as enzimas DNMT1 (rs8112895, rs7254567, rs11085721, rs17291414, rs10854076) e sirtuína-1 (rs10997870; rs12766485) foi realizada após a genotipagem por reação em cadeia da polimerase em tempo real, em uma casuística composta por 466 pacientes com DM1. RESULTADOS: Do total de 377 miRNAs-alvo avaliados no soro dos pacientes com DM1, um total de 21 miRNAs estava superexpresso no grupo com complicações. Dos 5 miRNAs para os quais foi realizada a validação na casuística de 47 pacientes com DM1, dois foram confirmados como superexpressos na população com complicações (hsa-miR-518d-3p e hsa-miR-618). O polimorfismo rs11085721 no gene que codifica a DNMT1 associou-se à presença de NAC no sexo feminino, sendo o alelo raro C considerado de risco e conferindo um odds ratio (intervalo de confiança de 95%) de 2,44 (1,26-5,28). Nenhum polimorfismo da sirtuína-1 associou-se às complicações microvasculares avaliadas. CONCLUSÃO: o perfil de miRNAs séricos difere entre pacientes com DM1 com e sem complicações. O achado de uma variante em um gene que codifica a enzima de uma via epigenética conferir suscetibilidade a uma complicação crônica sugere que também exista a \"genética da epigenética\" modulando o desenvolvimento das complicações / INTRODUCTION: Factors associated with the etiopathogenesis of diabetic complications, including hyperglycemia and oxidative stress, may cause epigenetic changes that modify the expression of genes in target cells without altering their DNA sequence. The following mechanisms are considered epigenetics: (1) post-translational modifications of histones; (2) methylation of DNA and (3) action of micro-RNAs (miRNAs); all have already been recognized in the pathogenesis of \"metabolic memory\", a situation in which hyperglycemia exerts prolonged deleterious effects even after its normalization. Sirtuin-1 is an enzyme that causes post-translational modifications of histones by their histone deacetylase activity, silencing gene transcription. Gene silencing may also occur through the action of DNA methyltransferase 1 (DNMT1), an enzyme that adds a methyl group (CH3) at position 5 of cytosine residues located in CpG islands from gene-promoter regions. miRNAs are a class of small non-coding RNAs with about 19 to 25 nucleotides that control gene expression by promoting translation repression or degradation of target messenger RNAs. The hypotheses of the present study are (1) there is a serum profile of miRNAs associated with the presence or absence of chronic complications and (2) there are variants in genes related to histone deacetylation and cytosine methylation that could predispose to diabetes complications, which would constitute the \"genetics of epigenetics\". OBJECTIVES: (1) to characterize and compare the serum miRNA profile of patients with type 1 diabetes mellitus (T1D) without any microvascular complications versus those with three microvascular complications: diabetic retinopathy (DR), diabetic kidney disease (DKD) and diabetic neuropathy to identify signaling pathways epigenetically modulated in these two groups of patients and (2) to assess the frequency of single nucleotide polymorphisms in the genes encoding DNMT1 and sirtuin-1 and their associations with each of the microvascular complications in T1D patients. METHODS: The serum profile of 381 miRNAs was evaluated using the Taqman® Human MicroRNA Array A kit in 10 clinical and laboratory well-characterized patients divided into two groups: Patients without microvascular complications: without DKD (creatinine clearance> 90 ml/min/1.73 m2 and urinary albumin excretion < 20 mg / g creatinine), without distal sensory-motor polyneuropathy (absence of symptoms suggestive of neuropathy and normal thermal and pain sensitivity and Achilles reflex), without cardiovascular autonomic neuropathy (CAN) and without DR; and T1D patients with complications: with DKD (creatinine clearance < 60 ml / min / 1.73 m2 and urinary albumin excretion> 200 mg / g creatinine), with distal sensory-motor polyneuropathy, with CAN and with DR moderate or severe. The five most differentially expressed miRNAs were validated in a well-characterized case series of 20 patients with no complications and 27 patients with all microvascular complications using the TaqMan (TM) Advanced miRNA cDNA Synthesis kit. The evaluation of the frequency of single nucleotide polymorphisms in genes encoding the DNMT1 (rs8112895, rs7254567, rs11085721, rs1729414, rs10854076) and sirtuin-1 (rs10997870; rs12766485) was performed by genotyping using real-time polymerase chain reaction in a sample of 466 T1D patients. RESULTS: Of the total of 377 target miRNAs evaluated in the serum of T1D patients, 21 miRNAs were overexpressed in the group with complications. Of the 5 miRNAs for which validation was performed in 47 patients, two were confirmed as overexpressed in the group with complications (hsa-miR-518d-3p and hsa-miR-618). The polymorphism rs11085721 in the gene encoding DNMT1 was associated with the presence of CAN in female patients, with the minor allele C being considered of risk and conferring an odds ratio (95% confidence interval) of 2.44 (1.26 - 5.28). Polymorphisms in the gene encoding Sirtuin-1 did not associate with microvascular complications. CONCLUSION: the serum miRNA profile differs between patients with and without microvascular complications. A variant in a gene encoding a enzyme of an epigenetic pathway conferring susceptibility to a chronic complication suggests that there is also the \"genetics of epigenetics\" modulating the development of complications

Diabetes mellitus tipo 1

Diabetes mellitus type 1

Diabetic nephropathies

Diabetic neuropathies

Diabetic retinopathy

DNA (Citosina-5-) metiltransferase

DNA (cytosine-5-)-methyltransferase

Epigenetic repression

microRNAs

microRNAs

Nefropatias diabéticas

Neuropatias diabéticas

Polimorfismo de nucleotídeo único

Polymorphism single nucleotide

Repressão epigenética

Retinopatia diabética

Sirtuin 1

Sirtuína 1

Identificação de fatores epigenéticos associados às complicações crônicas em portadores de diabetes mellitus tipo1 / Identification of epigenetic factors associated with chronic complications in patients with type 1 diabetes mellitus

Daniele Pereira dos Santos Bezerra

26 April 2018

INTRODUÇÃO: Fatores associados à etiopatogenia das complicações diabéticas, incluindo hiperglicemia e estresse oxidativo, podem causar alterações epigenéticas que modificam a expressão de genes em células-alvo, sem alterar sua sequência de DNA. São considerados mecanismos epigenéticos: (1) as modificações pós-traducionais das histonas; (2) a metilação do DNA e (3) a ação dos micro-RNAs (miRNAs); todos já foram reconhecidos na patogênese da \"memória metabólica\", situação na qual a hiperglicemia continua a exercer efeitos deletérios prolongados mesmo depois de ser normalizada. A sirtuína-1 é uma enzima que causa modificações pós-traducionais das histonas por sua atividade de histona desacetilase, silenciando a transcrição gênica. O silenciamento gênico também pode ocorrer pela ação da DNA metiltransferase 1 (DNMT1), enzima que adiciona um grupamento metil (CH3) na posição 5 de resíduos de citosina localizadas em ilhas CpG presentes nas regiões promotoras dos genes. Os miRNAs constituem uma classe de pequenos RNAs não codificadores com cerca de 19 a 25 nucleotídeos que controlam a expressão gênica por meio da repressão da tradução ou da degradação do RNA mensageiro-alvo. As hipóteses do presente estudo são (1) que exista um perfil sérico de miRNAs associado à presença ou ausência de complicações crônicas e (2) que existam variantes em genes relacionados à desacetilação das histonas e à metilação de citosinas que poderiam predispor ao aparecimento das complicações diabéticas, o que se constituiria na \"genética da epigenética\". OBJETIVOS: (1) caracterizar e comparar o perfil de miRNAs sérico de pacientes com diabetes mellitus tipo 1 (DM1) sem nenhuma complicação microvascular versus aqueles com três complicações microvasculares: retinopatia diabética (RD), doença renal diabética (DRD) e neuropatia diabética, para identificar vias epigeneticamente moduladas nesses dois grupos de pacientes e (2) avaliar a frequência de polimorfismos de um único nucleotídeo nos genes que codificam as enzimas DNMT1 e sirtuína-1 e suas associações com cada uma das complicações microvasculares em pacientes com DM1. MÉTODOS: O perfil sérico de 381 miRNAs foi avaliado com o uso do estojo comercial Taqman® Human MicroRNA Array A em 10 pacientes bem caracterizados clínica e laboratorialmente divididos em dois grupos: Pacientes com DM1 sem complicações [sem DRD (Clearance de creatinina > 90 ml/min/1,73 m2 e excreção urinária de albumina < 20 mg/g de creatinina), sem polineuropatia sensitivo-motora distal (ausência de sintomas sugestivos de neuropatia, sensibilidade térmica e dolorosa e reflexo aquileu normais), sem neuropatia autonômica cardiovascular (NAC) e sem RD] e Pacientes com DM1 com complicações [DRD (Clearance de creatinina < 60 ml/min/1,73 m2 e excreção urinária de albumina > 200 mg/g de creatinina), com polineuropatia sensitiva-motora distal, com NAC instalada e RD moderada ou grave]. Os cinco miRNAs mais diferencialmente expressos foram validados em uma casuística bem caracterizada de 20 pacientes com DM1 sem nenhuma complicação e 27 com todas as complicações microvasculares, com o emprego do estojo comercial TaqMan(TM) Advanced miRNA cDNA Synthesis. A avaliação da frequência de polimorfismos de um único nucleotídeo nos genes que codificam as enzimas DNMT1 (rs8112895, rs7254567, rs11085721, rs17291414, rs10854076) e sirtuína-1 (rs10997870; rs12766485) foi realizada após a genotipagem por reação em cadeia da polimerase em tempo real, em uma casuística composta por 466 pacientes com DM1. RESULTADOS: Do total de 377 miRNAs-alvo avaliados no soro dos pacientes com DM1, um total de 21 miRNAs estava superexpresso no grupo com complicações. Dos 5 miRNAs para os quais foi realizada a validação na casuística de 47 pacientes com DM1, dois foram confirmados como superexpressos na população com complicações (hsa-miR-518d-3p e hsa-miR-618). O polimorfismo rs11085721 no gene que codifica a DNMT1 associou-se à presença de NAC no sexo feminino, sendo o alelo raro C considerado de risco e conferindo um odds ratio (intervalo de confiança de 95%) de 2,44 (1,26-5,28). Nenhum polimorfismo da sirtuína-1 associou-se às complicações microvasculares avaliadas. CONCLUSÃO: o perfil de miRNAs séricos difere entre pacientes com DM1 com e sem complicações. O achado de uma variante em um gene que codifica a enzima de uma via epigenética conferir suscetibilidade a uma complicação crônica sugere que também exista a \"genética da epigenética\" modulando o desenvolvimento das complicações / INTRODUCTION: Factors associated with the etiopathogenesis of diabetic complications, including hyperglycemia and oxidative stress, may cause epigenetic changes that modify the expression of genes in target cells without altering their DNA sequence. The following mechanisms are considered epigenetics: (1) post-translational modifications of histones; (2) methylation of DNA and (3) action of micro-RNAs (miRNAs); all have already been recognized in the pathogenesis of \"metabolic memory\", a situation in which hyperglycemia exerts prolonged deleterious effects even after its normalization. Sirtuin-1 is an enzyme that causes post-translational modifications of histones by their histone deacetylase activity, silencing gene transcription. Gene silencing may also occur through the action of DNA methyltransferase 1 (DNMT1), an enzyme that adds a methyl group (CH3) at position 5 of cytosine residues located in CpG islands from gene-promoter regions. miRNAs are a class of small non-coding RNAs with about 19 to 25 nucleotides that control gene expression by promoting translation repression or degradation of target messenger RNAs. The hypotheses of the present study are (1) there is a serum profile of miRNAs associated with the presence or absence of chronic complications and (2) there are variants in genes related to histone deacetylation and cytosine methylation that could predispose to diabetes complications, which would constitute the \"genetics of epigenetics\". OBJECTIVES: (1) to characterize and compare the serum miRNA profile of patients with type 1 diabetes mellitus (T1D) without any microvascular complications versus those with three microvascular complications: diabetic retinopathy (DR), diabetic kidney disease (DKD) and diabetic neuropathy to identify signaling pathways epigenetically modulated in these two groups of patients and (2) to assess the frequency of single nucleotide polymorphisms in the genes encoding DNMT1 and sirtuin-1 and their associations with each of the microvascular complications in T1D patients. METHODS: The serum profile of 381 miRNAs was evaluated using the Taqman® Human MicroRNA Array A kit in 10 clinical and laboratory well-characterized patients divided into two groups: Patients without microvascular complications: without DKD (creatinine clearance> 90 ml/min/1.73 m2 and urinary albumin excretion < 20 mg / g creatinine), without distal sensory-motor polyneuropathy (absence of symptoms suggestive of neuropathy and normal thermal and pain sensitivity and Achilles reflex), without cardiovascular autonomic neuropathy (CAN) and without DR; and T1D patients with complications: with DKD (creatinine clearance < 60 ml / min / 1.73 m2 and urinary albumin excretion> 200 mg / g creatinine), with distal sensory-motor polyneuropathy, with CAN and with DR moderate or severe. The five most differentially expressed miRNAs were validated in a well-characterized case series of 20 patients with no complications and 27 patients with all microvascular complications using the TaqMan (TM) Advanced miRNA cDNA Synthesis kit. The evaluation of the frequency of single nucleotide polymorphisms in genes encoding the DNMT1 (rs8112895, rs7254567, rs11085721, rs1729414, rs10854076) and sirtuin-1 (rs10997870; rs12766485) was performed by genotyping using real-time polymerase chain reaction in a sample of 466 T1D patients. RESULTS: Of the total of 377 target miRNAs evaluated in the serum of T1D patients, 21 miRNAs were overexpressed in the group with complications. Of the 5 miRNAs for which validation was performed in 47 patients, two were confirmed as overexpressed in the group with complications (hsa-miR-518d-3p and hsa-miR-618). The polymorphism rs11085721 in the gene encoding DNMT1 was associated with the presence of CAN in female patients, with the minor allele C being considered of risk and conferring an odds ratio (95% confidence interval) of 2.44 (1.26 - 5.28). Polymorphisms in the gene encoding Sirtuin-1 did not associate with microvascular complications. CONCLUSION: the serum miRNA profile differs between patients with and without microvascular complications. A variant in a gene encoding a enzyme of an epigenetic pathway conferring susceptibility to a chronic complication suggests that there is also the \"genetics of epigenetics\" modulating the development of complications

Diabetes mellitus tipo 1

DNA (Citosina-5-) metiltransferase

microRNAs

Nefropatias diabéticas

Neuropatias diabéticas

Polimorfismo de nucleotídeo único

Repressão epigenética

Retinopatia diabética

Sirtuína 1

Diabetes mellitus type 1

Diabetic nephropathies

Diabetic neuropathies

Diabetic retinopathy

DNA (cytosine-5-)-methyltransferase

Epigenetic repression

microRNAs

Polymorphism single nucleotide

Sirtuin 1

A Novel Approach to Identify Candidate Imprinted Genes in Humans

Shapiro, Jonathan

21 March 2012

Many imprinted genes are necessary for normal human development. Approximately 70 imprinted genes have been identified in humans. I developed a novel approach to identify candidate imprinted genes in humans using the premise that imprinted genes are often associated with nearby parent-of-origin-specific DNA differentially methylated regions (DMRs). I identified parent-of-origin-specific DMRs using sodium bisulfite-based DNA (CpG) methylation profiling of uniparental tissues, mature cystic ovarian teratoma (MCT) and androgenetic complete hydatidiform mole (AnCHM), and biparental tissues, blood and placenta. In support of this approach, the CpG methylation profiling led to the identification of parent-of-origin-specific differentially methylated CpG sites (DMCpGs) in known parent-of-origin-specific DMRs. I found new DMRs for known imprinted genes NAP1L5 and ZNF597. Most importantly, I discovered many new DMCpGs, which were associated with nearby genes, i.e., candidate imprinted genes. Allelic expression analyses of one candidate imprinted gene, AXL, suggested polymorphic imprinting of AXL in human blood.

Allele

Allele-specific DNA Methylation

Allele-specific Gene Expression

Allele-specific Expression

Allele-specific Methylation

AnCHM

Androgenetic

Androgenetic Mole

Mole

Complete Mole

Hydatidiform Mole

Complete Hydatidiform Mole

Androgenetic Hydatidiform Mole

Androgenetic Complete Hydatidiform Mole

Biparental Tissue

Bisulfite

Bisulphite

Blood

Blood DNA

Computational Biology

DNA Methylation

DNA Methylation Profiling

Epigenetic

Epi-genetic

Epigenomic

Epi-genomic

Expression

Expression Regulation

Gene Expression

Gene Expression Regulation

Genetic

Genetic Imprint

Genetic Imprinting

Genomic

Genomic DNA

Genomic Imprint

Genomic Imprinting

Human

Imprint

Imprinting

Teratoma

Ovarian Teratoma

Cystic Teratoma

Mature Teratoma

Mature Cystic Teratoma

Mature Ovarian Teratoma

Cystic Ovarian Teratoma

Mature Cystic Ovarian Teratoma

MCT

Methylation

Cytosine Methylation

Microarray

Neoplasm

Ovarian Neoplasm

Placenta

Profiling

Promoter

Promoter Region

Sodium Bisulfite

Sodium Bisulphite

Uniparental Tissue

WB

WBC

Imprinted Gene

Polymorphic Imprinting

Parent-of-origin

Parent-of-origin-specific Methylation

Parent-of-origin-specific Expression

0369

0307

A Novel Approach to Identify Candidate Imprinted Genes in Humans

Shapiro, Jonathan

21 March 2012

Many imprinted genes are necessary for normal human development. Approximately 70 imprinted genes have been identified in humans. I developed a novel approach to identify candidate imprinted genes in humans using the premise that imprinted genes are often associated with nearby parent-of-origin-specific DNA differentially methylated regions (DMRs). I identified parent-of-origin-specific DMRs using sodium bisulfite-based DNA (CpG) methylation profiling of uniparental tissues, mature cystic ovarian teratoma (MCT) and androgenetic complete hydatidiform mole (AnCHM), and biparental tissues, blood and placenta. In support of this approach, the CpG methylation profiling led to the identification of parent-of-origin-specific differentially methylated CpG sites (DMCpGs) in known parent-of-origin-specific DMRs. I found new DMRs for known imprinted genes NAP1L5 and ZNF597. Most importantly, I discovered many new DMCpGs, which were associated with nearby genes, i.e., candidate imprinted genes. Allelic expression analyses of one candidate imprinted gene, AXL, suggested polymorphic imprinting of AXL in human blood.

Allele

Allele-specific DNA Methylation

Allele-specific Gene Expression

Allele-specific Expression

Allele-specific Methylation

AnCHM

Androgenetic

Androgenetic Mole

Mole

Complete Mole

Hydatidiform Mole

Complete Hydatidiform Mole

Androgenetic Hydatidiform Mole

Androgenetic Complete Hydatidiform Mole

Biparental Tissue

Bisulfite

Bisulphite

Blood

Blood DNA

Computational Biology

DNA Methylation

DNA Methylation Profiling

Epigenetic

Epi-genetic

Epigenomic

Epi-genomic

Expression

Expression Regulation

Gene Expression

Gene Expression Regulation

Genetic

Genetic Imprint

Genetic Imprinting

Genomic

Genomic DNA

Genomic Imprint

Genomic Imprinting

Human

Imprint

Imprinting

Teratoma

Ovarian Teratoma

Cystic Teratoma

Mature Teratoma

Mature Cystic Teratoma

Mature Ovarian Teratoma

Cystic Ovarian Teratoma

Mature Cystic Ovarian Teratoma

MCT

Methylation

Cytosine Methylation

Microarray

Neoplasm

Ovarian Neoplasm

Placenta

Profiling

Promoter

Promoter Region

Sodium Bisulfite

Sodium Bisulphite

Uniparental Tissue

WB

WBC

Imprinted Gene

Polymorphic Imprinting

Parent-of-origin

Parent-of-origin-specific Methylation

Parent-of-origin-specific Expression

0369

0307