Dissecting the Role of the Histone Demethylase KDM1B in Maintenance of Pluripotency and Differentiation of Human Embryonic Stem Cells

Alfarhan, Dalal

04 1900

Lysine-specific Demethylase 1B (KDM1B) is a chromatin regulator which functions as a histone eraser through the removal of the post-translational modifications mono and dimethylation of histone 3 on lysine 4 (H3K4me1/2). This process is enhanced by the formation of a complex with Nuclear Protein Glyoxylate Reductase (NPAC). NPAC resolves the sequestration of the nucleosome histone tail to allow robust demethylation of H3K4me2 by KDM1B, during transcriptional elongation by RNA polymerase 2 (RNAP II). KDM1B is involved in many crucial processes during development. Its physiological functions include the establishment of maternal genomic imprints, reset of the epigenome during somatic cell reprogramming, and regulation of brown adipogenic differentiation. In light of this, the role of KDM1B in human embryonic stem cells (hESCs) is examined through CRISPR/Cas9-editing to further dissect its biological functions during embryogenesis. CRISPR-induced knockouts of KDM1B exhibited similar cell proliferation rate and expression of OCT4 and NANOG pluripotency markers to wildtype cells. Furthermore, KDM1B-/- clones were able to maintain their pluripotency potential by differentiating to all germ layers in teratoma and embryoid body formation assays. In addition, RNA-seq of KDM1B-/- clones showed enrichment of mesoderm lineage-related gene ontology (GO) terms in the downregulated differentially expressed genes. Thus, KDM1B is believed to be dispensable during the pluripotent stage of the cell but proved fundamental during later stages of development.

KDM1B

Histone demethylation

CRISPR knockout

Human embryonic stem cells

Differentiation

Studies of Budding Yeast Transcription Factors Acting Downstream of Nutrient Signaling Pathways

Nordberg, Niklas

January 2012

Being able to respond to extracellular cues such as nutrients and growth factors is of vital importance to all living cells. Pathways have therefore evolved which can sense the extracellular status, transmit a signal through the cell and affect gene expression, which ultimately enables adaptation. Intriguingly, research has revealed that such signaling pathways responding to nutrient status are intrinsically linked to the lifespan of organisms, a phenomenon known as caloric restriction. This thesis utilizes budding yeast, Saccharomyces cerevisiae, as a model system to investigate how transcription factors affect gene expression in response to nutrient signaling pathways. Paper I investigates the role of the three homologous transcription factors Mig1, Mig2 and Mig3 in regulating gene expression in response to glucose. This is done by transcriptional profiling with microarrays of wild type yeast, as well as mutant strains where the MIG1, MIG2 and MIG3 genes have been deleted in all possible combinations. The results reveal that Mig1 and Mig2 act together, with Mig1 having a larger effect in general while Mig2 has a role specialized for high-glucose conditions. Using a strategy similar to that in paper I, paper II examines the roles of the two homologous transcription factors Gis1 and Rph1 in gene regulation. This study shows that Gis1 and Rph1 are both involved in nutrient signaling, acting in parallel with a large degree of redundancy. Furthermore, we find that these two transcription factors change both target genes as well as the effects on transcription when the yeast cell transitions through different growth phases. Rph1 is a functional JmjC histone demethylase, and paper III investigates the connection between this activity and the transcriptional regulation studied in paper II. We find that rendering Rph1 catalytically inactive has little effect on its role in nutrient signaling and gene regulation, but subtly affects certain groups of genes. Paper IV reveals that Rph1 does not affect the chronological lifespan of yeast as does its homolog Gis1. However, deleting or overexpressing RPH1 has effects on the response to rapamycin and caffeine, inhibitors of the evolutionary conserved TORC1 complex affecting lifespan in both yeast and mammals.

Budding yeast

nutrient signaling

glucose repression

aging

caloric restriction

JmjC

histone demethylation

Mig1

Mig2

Mig3

Gis1

Rph1

Caracterização de alterações epigenéticas no gene JARID1C e desequilíbrios genéticos como causas do retardo mental ligado ao x de etiologia idiopática / Characterization of epigenetic alterations in JARID1C gene and genetic imbalance as causes of X-linked mental retardation of idiopathic etiology

Natalia Fintelman Rodrigues

17 February 2011

Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / O retardo mental (RM) é caracterizado por um funcionamento intelectual significantemente abaixo da média (QI<70). A prevalência de RM varia entre estudos epidemiológicos, sendo estimada em 2-3% da população mundial, constituindo assim, um dos mais importantes problemas de saúde pública. Há um consenso geral de que o RM é mais comum no sexo masculino, um achado atribuído às numerosas mutações nos genes encontrados no cromossomo X, levando ao retardo mental ligado ao X (RMLX). Dentre os genes presentes no cromossomo X, o Jumonji AT-rich interactive domain IC (JARID1C) foi recentemente identificado como um potencial candidato etiológico do RM, quando mutado. O JARID1C codifica uma proteína que atua como uma desmetilase da lisina 4 da histona H3 (H3K4), imprescindível para a regulação epigenética. Tão recente como a identificação do gene JARID1C, é a descoberta de que mudanças no número de cópias de sequências de DNA, caracterizadas por microdeleções e microduplicações, poderiam ser consideradas como razões funcionalmente importantes de RMLX. Atualmente, cerca de 5-10% dos casos de RM em homens são reconhecidos por ocorrerem devido a estas variações do número de cópias no cromossomo X. Neste estudo, investigamos mutações no gene JARID1C, através do rastreamento dos éxons 9, 11, 12, 13, 15 e 16, em 121 homens de famílias com RM provavelmente ligado ao X. Paralelamente, realizamos a análise da variação do número de cópias em 16 genes localizados no cromossomo X através da técnica de MLPA no mesmo grupo de pacientes. Esta metodologia consiste em uma amplificação múltipla que detecta variações no número de cópias de até 50 sequências diferentes de DNA genômico, sendo capaz de distinguir sequências que diferem em apenas um nucleotídeo. O DNA genômico foi extraído a partir de sangue periférico e as amostras foram amplificadas pela técnica de PCR, seguida da análise por sequenciamento direto. Foram identificadas três variantes na sequência do gene JARID1C entre os pacientes analisados: a variante intrônica 2243+11 G>T, que esteve presente em 67% dos pacientes, a variante silenciosa c.1794C>G e a mutação inédita nonsense c.2172C>A, ambas presentes em 0,82% dos indivíduos investigados. A análise através do MLPA revelou uma duplicação em um dos pacientes envolvendo as sondas referentes ao gene GDI1 e ao gene HUWE1. Este trabalho expande o estudo de mutações no gene JARID1C para a população brasileira ereforça a importância da triagem de mutações neste gene em homens portadores de RM familiar de origem idiopática, assim como, é primeiro relato científico relativo à investigação de variações no número de cópias de genes localizados no cromossomo X em homens brasileiros com RM, através da técnica de MLPA. / Mental retardation (MR) is defined as a disability characterized by significant below average intellectual functioning (IQ>70). The prevalence of MR varies between epidemiological studies, estimated at 2-3% of the population, thus constituting a major public health problem. There is a general consensus that MR is more common in males, a finding attributed, in part, to mutations in the genes located on the X chromosome, leading to an X-linked mental retardation (XLMR). Among all the genes present on X chromosome, Jumonji AT-rich interactive domain IC (JARID1C) was recently identified as aetiologic potential candidate of MR, when mutated. The JARID1C gene encodes a protein that acts as a histone demethylase specific for histone 3 lysine 4 (H3K4) and it is indispensable for the epigenetic regulation. As recently as the identification of the JARID1C gene, it is the discovery that changes in the number of copies of DNA sequences, characterized by microdeletions and microduplications, could be regarded as functionally important reasons to XLMR. Currently, about 5-10% of men MR cases are known to occur due to these variations in the number of copies of chromosome X. In this study we investigated mutations in the JARID1C gene by screening of exons 9, 11, 12, 13, 15 and 16 in 121 patients from families with X-linked MR. At the same time we analyzed the variation in the number of copies in 16 genes located in X chromosome through the MLPA technique. This metodology consists of a multiplex amplification that detects variations in the number of copies up to 50 different genomic DNA sequences, being able to distinguish sequences that differ by only one nucleotide. Genomic DNA was extracted from peripheral blood and the samples were amplified by PCR followed by direct sequencing analysis. We identified three sequence variants among 121 patients. The intronic variant c.2243 +11 G> T, which was present in 67% of patients analyzed, the silent variant c.1794C> G and the novel nonsense mutation c.2172C> A, which was present in 0,82% of patients analyzed. The MLPA analysis revealed that the patient 58 exhibited a duplication involving probes for the GDI1 gene and the HUWE1 gene, resulting in an increase in the number of copies of this gene. This work expands the study of mutations in the JARID1C gene for the Brazilian population and reinforces the importance of screening for mutations in this gene in men with idiopathic mental retardation, and it is the first scientific report on the investigation of variations in the number of copies in genes located on chromosome X in Brazilian men with MR using the MLPA technique.

RMLX

JARID1C

KDM5C

Desmetilação de histonas

Variação no número de cópias

MLPA

Retardo mental - Aspectos genéticos

Translocação (Genética)

XLMR

JARID1C

KDM5C

Histone demethylation

Copy number variants

MLPA

Mental retardation - Genetic aspects

Translocation (Genetics)

GENETICA HUMANA E MEDICA

Caracterização de alterações epigenéticas no gene JARID1C e desequilíbrios genéticos como causas do retardo mental ligado ao x de etiologia idiopática / Characterization of epigenetic alterations in JARID1C gene and genetic imbalance as causes of X-linked mental retardation of idiopathic etiology

Natalia Fintelman Rodrigues

17 February 2011

Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / O retardo mental (RM) é caracterizado por um funcionamento intelectual significantemente abaixo da média (QI<70). A prevalência de RM varia entre estudos epidemiológicos, sendo estimada em 2-3% da população mundial, constituindo assim, um dos mais importantes problemas de saúde pública. Há um consenso geral de que o RM é mais comum no sexo masculino, um achado atribuído às numerosas mutações nos genes encontrados no cromossomo X, levando ao retardo mental ligado ao X (RMLX). Dentre os genes presentes no cromossomo X, o Jumonji AT-rich interactive domain IC (JARID1C) foi recentemente identificado como um potencial candidato etiológico do RM, quando mutado. O JARID1C codifica uma proteína que atua como uma desmetilase da lisina 4 da histona H3 (H3K4), imprescindível para a regulação epigenética. Tão recente como a identificação do gene JARID1C, é a descoberta de que mudanças no número de cópias de sequências de DNA, caracterizadas por microdeleções e microduplicações, poderiam ser consideradas como razões funcionalmente importantes de RMLX. Atualmente, cerca de 5-10% dos casos de RM em homens são reconhecidos por ocorrerem devido a estas variações do número de cópias no cromossomo X. Neste estudo, investigamos mutações no gene JARID1C, através do rastreamento dos éxons 9, 11, 12, 13, 15 e 16, em 121 homens de famílias com RM provavelmente ligado ao X. Paralelamente, realizamos a análise da variação do número de cópias em 16 genes localizados no cromossomo X através da técnica de MLPA no mesmo grupo de pacientes. Esta metodologia consiste em uma amplificação múltipla que detecta variações no número de cópias de até 50 sequências diferentes de DNA genômico, sendo capaz de distinguir sequências que diferem em apenas um nucleotídeo. O DNA genômico foi extraído a partir de sangue periférico e as amostras foram amplificadas pela técnica de PCR, seguida da análise por sequenciamento direto. Foram identificadas três variantes na sequência do gene JARID1C entre os pacientes analisados: a variante intrônica 2243+11 G>T, que esteve presente em 67% dos pacientes, a variante silenciosa c.1794C>G e a mutação inédita nonsense c.2172C>A, ambas presentes em 0,82% dos indivíduos investigados. A análise através do MLPA revelou uma duplicação em um dos pacientes envolvendo as sondas referentes ao gene GDI1 e ao gene HUWE1. Este trabalho expande o estudo de mutações no gene JARID1C para a população brasileira ereforça a importância da triagem de mutações neste gene em homens portadores de RM familiar de origem idiopática, assim como, é primeiro relato científico relativo à investigação de variações no número de cópias de genes localizados no cromossomo X em homens brasileiros com RM, através da técnica de MLPA. / Mental retardation (MR) is defined as a disability characterized by significant below average intellectual functioning (IQ>70). The prevalence of MR varies between epidemiological studies, estimated at 2-3% of the population, thus constituting a major public health problem. There is a general consensus that MR is more common in males, a finding attributed, in part, to mutations in the genes located on the X chromosome, leading to an X-linked mental retardation (XLMR). Among all the genes present on X chromosome, Jumonji AT-rich interactive domain IC (JARID1C) was recently identified as aetiologic potential candidate of MR, when mutated. The JARID1C gene encodes a protein that acts as a histone demethylase specific for histone 3 lysine 4 (H3K4) and it is indispensable for the epigenetic regulation. As recently as the identification of the JARID1C gene, it is the discovery that changes in the number of copies of DNA sequences, characterized by microdeletions and microduplications, could be regarded as functionally important reasons to XLMR. Currently, about 5-10% of men MR cases are known to occur due to these variations in the number of copies of chromosome X. In this study we investigated mutations in the JARID1C gene by screening of exons 9, 11, 12, 13, 15 and 16 in 121 patients from families with X-linked MR. At the same time we analyzed the variation in the number of copies in 16 genes located in X chromosome through the MLPA technique. This metodology consists of a multiplex amplification that detects variations in the number of copies up to 50 different genomic DNA sequences, being able to distinguish sequences that differ by only one nucleotide. Genomic DNA was extracted from peripheral blood and the samples were amplified by PCR followed by direct sequencing analysis. We identified three sequence variants among 121 patients. The intronic variant c.2243 +11 G> T, which was present in 67% of patients analyzed, the silent variant c.1794C> G and the novel nonsense mutation c.2172C> A, which was present in 0,82% of patients analyzed. The MLPA analysis revealed that the patient 58 exhibited a duplication involving probes for the GDI1 gene and the HUWE1 gene, resulting in an increase in the number of copies of this gene. This work expands the study of mutations in the JARID1C gene for the Brazilian population and reinforces the importance of screening for mutations in this gene in men with idiopathic mental retardation, and it is the first scientific report on the investigation of variations in the number of copies in genes located on chromosome X in Brazilian men with MR using the MLPA technique.

RMLX

JARID1C

KDM5C

Desmetilação de histonas

Variação no número de cópias

MLPA

Retardo mental - Aspectos genéticos

Translocação (Genética)

XLMR

JARID1C

KDM5C

Histone demethylation

Copy number variants

MLPA

Mental retardation - Genetic aspects

Translocation (Genetics)

GENETICA HUMANA E MEDICA