scispace - formally typeset
Search or ask a question
Author

Kwonho Hong

Bio: Kwonho Hong is an academic researcher from Howard Hughes Medical Institute. The author has contributed to research in topics: Medicine & Biology. The author has an hindex of 4, co-authored 5 publications receiving 2787 citations. Previous affiliations of Kwonho Hong include Boston Children's Hospital & University of North Carolina at Chapel Hill.

Papers
More filters
Journal ArticleDOI
26 Aug 2010-Nature
TL;DR: It is demonstrated that all three mouse Tet proteins (Tet1, Tet2 and Tet3) can also catalyse a similar reaction, uncover the enzymatic activity of the Tet proteins, and demonstrate a role for Tet1 in ES cell maintenance and inner cell mass cell specification.
Abstract: DNA methylation is one of the best-characterized epigenetic modifications. Although the enzymes that catalyse DNA methylation have been characterized, enzymes responsible for demethylation have been elusive. A recent study indicates that the human TET1 protein could catalyse the conversion of 5-methylcytosine (5mC) of DNA to 5-hydroxymethylcytosine (5hmC), raising the possibility that DNA demethylation may be a Tet1-mediated process. Here we extend this study by demonstrating that all three mouse Tet proteins (Tet1, Tet2 and Tet3) can also catalyse a similar reaction. Tet1 has an important role in mouse embryonic stem (ES) cell maintenance through maintaining the expression of Nanog in ES cells. Downregulation of Nanog via Tet1 knockdown correlates with methylation of the Nanog promoter, supporting a role for Tet1 in regulating DNA methylation status. Furthermore, knockdown of Tet1 in pre-implantation embryos results in a bias towards trophectoderm differentiation. Thus, our studies not only uncover the enzymatic activity of the Tet proteins, but also demonstrate a role for Tet1 in ES cell maintenance and inner cell mass cell specification.

2,364 citations

Journal ArticleDOI
20 Dec 2012-Nature
TL;DR: It is shown that the 5mC-specific dioxygenase Tet1 has an important role in regulating meiosis in mouse oocytes, and establishes a function for Tet1 in meiosis and meiotic gene activation in female germ cells.
Abstract: A loss-of-function approach in mice is used to show that the methylcytosine dioxygenase Tet1 has a role in regulating meiosis and meiotic gene activation in female germ cells; Tet1 deficiency does not greatly affect genome-wide demethylation but has a more specific effect on the expression of a subset of meiotic genes. DNA methylation on cytosine is an important epigenetic modification, and the mechanisms controlling 5-methylcytosine (5mC) dynamics constitute an active area of research. The Tet family of dioxygenases can catalyse oxidation of 5mC to produce derivatives such as 5-hydroxymethylcytosine (5hmC), but little is known about the biological function of Tet proteins. Here, a loss-of-function approach in mice is used to show that Tet1 has a role in meiosis and meiotic gene activation in female germ cells. Tet1 deficiency does not greatly impact genome-wide demethylation, but has a more specific effect on the expression of a subset of meiotic genes. Meiosis is a germ-cell-specific cell division process through which haploid gametes are produced for sexual reproduction1. Before the initiation of meiosis, mouse primordial germ cells undergo a series of epigenetic reprogramming steps2,3, including the global erasure of DNA methylation at the 5-position of cytosine (5mC) in CpG-rich DNA4,5. Although several epigenetic regulators, such as Dnmt3l and the histone methyltransferases G9a and Prdm9, have been reported to be crucial for meiosis6, little is known about how the expression of meiotic genes is regulated and how their expression contributes to normal meiosis. Using a loss-of-function approach in mice, here we show that the 5mC-specific dioxygenase Tet1 has an important role in regulating meiosis in mouse oocytes. Tet1 deficiency significantly reduces female germ-cell numbers and fertility. Univalent chromosomes and unresolved DNA double-strand breaks are also observed in Tet1-deficient oocytes. Tet1 deficiency does not greatly affect the genome-wide demethylation that takes place in primordial germ cells, but leads to defective DNA demethylation and decreased expression of a subset of meiotic genes. Our study thus establishes a function for Tet1 in meiosis and meiotic gene activation in female germ cells.

274 citations

Journal ArticleDOI
28 Jan 2010-Nature
TL;DR: This study establishes a critical role for the elongator complex in zygotic paternal genome demethylation and indicates that the dem methylation process may be mediated through a reaction that requires an intact radical SAM domain.
Abstract: The life cycle of mammals begins when a sperm enters an egg. Immediately after fertilization, both the maternal and paternal genomes undergo dramatic reprogramming to prepare for the transition from germ cell to somatic cell transcription programs. One of the molecular events that takes place during this transition is the demethylation of the paternal genome. Despite extensive efforts, the factors responsible for paternal DNA demethylation have not been identified. To search for such factors, we developed a live cell imaging system that allows us to monitor the paternal DNA methylation state in zygotes. Through short-interfering-RNA-mediated knockdown in mouse zygotes, we identified Elp3 (also called KAT9), a component of the elongator complex, to be important for paternal DNA demethylation. We demonstrate that knockdown of Elp3 impairs paternal DNA demethylation as indicated by reporter binding, immunostaining and bisulphite sequencing. Similar results were also obtained when other elongator components, Elp1 and Elp4, were knocked down. Importantly, injection of messenger RNA encoding the Elp3 radical SAM domain mutant, but not the HAT domain mutant, into MII oocytes before fertilization also impaired paternal DNA demethylation, indicating that the SAM radical domain is involved in the demethylation process. Our study not only establishes a critical role for the elongator complex in zygotic paternal genome demethylation, but also indicates that the demethylation process may be mediated through a reaction that requires an intact radical SAM domain.

264 citations

Journal ArticleDOI
TL;DR: The dynamics of 5mC and 5hmC during PGC reprograming and germ cell development are revealed and their potential role in epigenetic reprogramming and transcriptional regulation of meiotic and imprinted genes is revealed.
Abstract: Previous studies have revealed that mouse primordial germ cells (PGCs) undergo genome-wide DNA methylation reprogramming to reset the epigenome for totipotency. However, the precise 5-methylcytosine (5mC) dynamics and its relationship with the generation of 5-hydroxymethylcytosine (5hmC) are not clear. Here we analyzed the dynamics of 5mC and 5hmC during PGC reprograming and germ cell development. Unexpectedly, we found a specific period (E8.5-9.5) during which both 5mC and 5hmC levels are low. Subsequently, 5hmC levels increase reaching its peak at E11.5 and gradually decrease until E13.5 likely by replication-dependent dilution. Interestingly, 5hmC is enriched in chromocenters during this period. While this germ cell-specific 5hmC subnuclear localization pattern is maintained in female germ cells even in mature oocytes, such pattern is gradually lost in male germ cells as mitotic proliferation resumes during the neonatal stage. Pericentric 5hmC plays an important role in silencing major satellite repeat, especially in female PGCs. Global transcriptome analysis by RNA-seq revealed that the great majority of differentially expressed genes from E9.5 to 13.5 are upregulated in both male and female PGCs. Although only female PGCs enter meiosis during the prenatal stage, meiosis-related and a subset of imprinted genes are significantly upregulated in both male and female PGCs at E13.5. Thus, our study not only reveals the dynamics of 5mC and 5hmC during PGC reprogramming and germ cell development, but also their potential role in epigenetic reprogramming and transcriptional regulation of meiotic and imprinted genes.

157 citations

Journal ArticleDOI
TL;DR: The female reproductive system and its association with the Hippo signaling pathway is described, as well as novel Hippo pathway genes and potential target genes.
Abstract: The uterus is essential for embryo implantation and fetal development. During the estrous cycle, the uterine endometrium undergoes dramatic remodeling to prepare for pregnancy. Angiogenesis is an essential biological process in endometrial remodeling. Steroid hormones regulate the series of events that occur during such remodeling. Researchers have investigated the potential factors, including angiofactors, involved in endometrial remodeling. The Hippo signaling pathway discovered in the 21st century, plays important roles in various cellular functions, including cell proliferation and cell death. However, its role in the endometrium remains unclear. In this review, we describe the female reproductive system and its association with the Hippo signaling pathway, as well as novel Hippo pathway genes and potential target genes.

6 citations


Cited by
More filters
Journal ArticleDOI
02 Sep 2011-Science
TL;DR: This study raises the possibility that DNA demethylation may occur through Tet-catalyzed oxidation followed by decarboxylation, and identifies two previously unknown cytosine derivatives in genomic DNA as the products of Tet proteins.
Abstract: 5-methylcytosine (5mC) in DNA plays an important role in gene expression, genomic imprinting, and suppression of transposable elements. 5mC can be converted to 5-hydroxymethylcytosine (5hmC) by the Tet (ten eleven translocation) proteins. Here, we show that, in addition to 5hmC, the Tet proteins can generate 5-formylcytosine (5fC) and 5-carboxylcytosine (5caC) from 5mC in an enzymatic activity–dependent manner. Furthermore, we reveal the presence of 5fC and 5caC in genomic DNA of mouse embryonic stem cells and mouse organs. The genomic content of 5hmC, 5fC, and 5caC can be increased or reduced through overexpression or depletion of Tet proteins. Thus, we identify two previously unknown cytosine derivatives in genomic DNA as the products of Tet proteins. Our study raises the possibility that DNA demethylation may occur through Tet-catalyzed oxidation followed by decarboxylation.

2,989 citations

Journal ArticleDOI
TL;DR: Vertebrate CpG islands are generically equipped to influence local chromatin structure and simplify regulation of gene activity.
Abstract: Vertebrate CpG islands (CGIs) are short interspersed DNA sequences that deviate significantly from the average genomic pattern by being GC-rich, CpG-rich, and predominantly nonmethylated. Most, perhaps all, CGIs are sites of transcription initiation, including thousands that are remote from currently annotated promoters. Shared DNA sequence features adapt CGIs for promoter function by destabilizing nucleosomes and attracting proteins that create a transcriptionally permissive chromatin state. Silencing of CGI promoters is achieved through dense CpG methylation or polycomb recruitment, again using their distinctive DNA sequence composition. CGIs are therefore generically equipped to influence local chromatin structure and simplify regulation of gene activity.

2,710 citations

Journal ArticleDOI
TL;DR: Key concepts in the function of DNA methylation in mammals are discussed, stemming from more than two decades of research, including many recent studies that have elucidated when and whereDNA methylation has a regulatory role in the genome.
Abstract: DNA methylation is among the best studied epigenetic modifications and is essential to mammalian development. Although the methylation status of most CpG dinucleotides in the genome is stably propagated through mitosis, improvements to methods for measuring methylation have identified numerous regions in which it is dynamically regulated. In this Review, we discuss key concepts in the function of DNA methylation in mammals, stemming from more than two decades of research, including many recent studies that have elucidated when and where DNA methylation has a regulatory role in the genome. We include insights from early development, embryonic stem cells and adult lineages, particularly haematopoiesis, to highlight the general features of this modification as it participates in both global and localized epigenetic regulation.

2,550 citations

Journal ArticleDOI
TL;DR: A comprehensive understanding of epigenetic mechanisms, their interactions and alterations in health and disease, has become a priority in biomedical research.
Abstract: Epigenetics is one of the most rapidly expanding fields in biology. The recent characterization of a human DNA methylome at single nucleotide resolution, the discovery of the CpG island shores, the finding of new histone variants and modifications, and the unveiling of genome-wide nucleosome positioning maps highlight the accelerating speed of discovery over the past two years. Increasing interest in epigenetics has been accompanied by technological breakthroughs that now make it possible to undertake large-scale epigenomic studies. These allow the mapping of epigenetic marks, such as DNA methylation, histone modifications and nucleosome positioning, which are critical for regulating gene and noncoding RNA expression. In turn, we are learning how aberrant placement of these epigenetic marks and mutations in the epigenetic machinery is involved in disease. Thus, a comprehensive understanding of epigenetic mechanisms, their interactions and alterations in health and disease, has become a priority in biomedical research.

2,458 citations

Journal ArticleDOI
TL;DR: The investigation into DNA methylation continues to show a rich and complex picture about epigenetic gene regulation in the central nervous system and provides possible therapeutic targets for the treatment of neuropsychiatric disorders.

2,399 citations