• BMB Reports
• /
• 제53권12호
• /
• pp.634-639
• /
• 2020

In prostate cancer, the androgen receptor (AR) transcription factor is a major regulator of cell proliferation and metastasis. To identify new AR regulators, we focused on Mixed lineage leukemia 5 (MLL5), a histone-regulating enzyme, because significantly higher MLL5 expression was detected in prostate cancer tissues than in matching normal tissues. When we expressed shRNAs targeting MLL5 gene in prostate cancer cell line, the growth rate and AR activity were reduced compared to those in control cells, and migration ability of the knockdown cells was reduced significantly. To determine the molecular mechanisms of MLL5 on AR activity, we proved that AR physically interacted with MLL5 and other co-factors, including SET-1 and HCF-1, using an immunoprecipitation method. The chromatin immunoprecipitation analysis showed reduced binding of MLL5, co-factors, and AR enzymes to AR target gene promoters in MLL5 shRNA-expressing cells. Histone H3K4 methylation on the AR target gene promoters was reduced, and H3K9 methylation at the same site was increased in MLL5 knockdown cells. Finally, xenograft tumor formation revealed that reduction of MLL5 in prostate cancer cells retarded tumor growth. Our results thus demonstrate the important role of MLL5 as a new epigenetic regulator of AR in prostate cancer.

• 생명과학회지
• /
• 제33권1호
• /
• pp.102-113
• /
• 2023

본 총설에서는 지난 수년 동안 자궁내막 염증 관련 새롭게 밝혀진 에스트로겐과 프로게스테론 수용체의 기능 중 지엽적 에스트로겐의 합성, 특이적 에스트로겐 수용체의 조절, 프로게스테론 저항성 그리고 스테로이드 호르몬의 작용에 의한 자궁내막 조직세포의 염증반응, 분화 및 생존에 대한 세포 및 분자적 조절기전들을 고찰한다. 자궁내막 조직 기질세포의 비정상적인 후성유전체적 변화는 자궁내막증의 발병과 진행에 중요한 요인으로 작용한다. 특히, 에스트로겐 수용체 유전자들의 차별적 메틸화는 기질세포내 ERα로부터 ERβ로의 발현 우세도 전환을 유도하여, ERβ-매개 염증반응, 프로게스테론 저항성 및 레티노이드 합성장애 등의 비정상적인 에스트로겐 반응을 초래한다. 이 기질세포는 또한 PGE2 및 SF-1 매개에 의한 스테로이드 합성효소의 발현유도를 통하여 지엽적 에스트로겐의 생성을 촉진하며, 증가된 에스트라디올은 다시 ERβ에 피드백으로 작용하여 COX-2 촉진을 통한 염증반응의 악순환을 야기한다. 높은 ERβ의 발현은 중간엽 줄기세포의 염색질 구조변화릉 야기하여 프로게스테론 저항성을 획득하고, 이는 반복적 생리에 따른 지속적 노출로 자궁내막 조직의 염증을 형성하며, 이후에는 ERβ-매개 에스트로겐과 TNF-α 및 TGF-β1을 포함한 염증 유발 인자들이 작용하여 염증 조직세포의 부착, 혈관생성 및 생존과 기질세포의 분화조절장애를 유도한다. 따라서, 생리주기의 역동적인 호르몬 변화와 이에 따르는 자궁내막 조직의 핵수용체 신호전달 조절기전에 대한 구체적인 이해는 정상적인 생식기능을 유지하면서 자궁내막증과 같은 비정상적 염증질환을 치료하기 위한 새로운 안목을 제공할 수 있을 것으로 기대된다.

• 생명과학회지
• /
• 제30권8호
• /
• pp.713-721
• /
• 2020

Adipogenesis의 연구는 인간의 지방생물학의 기초적인 분자기전을 이해하고, 비만, 당뇨 및 대사성 증후군의 발병기전을 밝히는데 필요하다. Adipogenesis의 많은 연구가 adipocytes 특이적인 핵심 전사인자인 PPARγ와 C/EBPα를 중심으로 하는 유전자 발현조절 및 세포 내 신호전달에 초점이 맞추어 활발하게 연구가 진행되었다. 그러나, 에피지놈 변형효소나 히스톤 돌연변이에 의한 에피지놈 관점에서 adipogenesis 연구는 미흡한 실정이다. 포유동물에서 히스톤 methylation은 유전자 발현에 대한 주요 후성유전적(epigenome) 변형 중 하나이며, 특히 히스톤 H3 lysine methylation은 다양한 조직 및 기관 발생과정과 세포 분화에 매우 중요한 히스톤 변형이다. 세포 특이적 enhancer는 adipogenesis에서 active enhancer 표지자인 H3K27ac와 함께 H3K4me1로 변형된다. MLL4는 Pparg 및 Cebpa 유전자 ehancers에서 중요한 adipogenic H3K4 mono-methyltransferase이다. 따라서 MLL4는 adipogenesis에 중요한 에피지놈 변형효소라고 할 수 있다. 유전자 발현 억제를 유발하는 대표적인 히스톤 변형인 H3K27me3은 Polycomb repressive complex 2의 효소활성 subunit인 Ezh2에 의해 매개된다. Wnt 유전자에서 Ezh2에 의한 H3K27me3 히스톤 methylation 변형은 adipogenesis를 증가시키는데, 이는 WNT 신호 전달이 adipogenesis의 억제 조절자로 알려져 있기 때문이다. 본 논문은 유전자 발현을 근본적으로 조절하는 히스톤 H3 methylation에 의한 후성 유전학적인 조절이 어떻게 adipogenesis를 조절하는지에 대해 요약한다.

• 한국식품위생안전성학회지
• /
• 제35권6호
• /
• pp.535-543
• /
• 2020

유전적 조절, 유전자 발현 그리고 환경적 단서, 화학적 신호에 대응하는 표현형 변이에서 세포 RNA는 ubiquitous 역할 이외에도 세포 외 RNA(exRNA)라 하는 새로운 형태의 RNA는 추후 연구의 방향을 제시한다. exRNA는 membrane vesicles 또는 세포 외 소포체(EV)로 알려진 membrane blebs를 통해 세포 외부로 운반된다. EV의 형성은 원핵생물, 진핵생물, 고세균을 포함한 모든 미생물군에 우세하게 보존되어있다. 본 리뷰는 세균 유래 exRNA에 관해 세가지 주제에 초점을 두었다. exRNA의 발견과 박테리아 유전자 배열에 대한 외부 RNA의 영향, b. exRNA의 분비기작을 통한 방출, c. 다른 그람음성 및 그람양성균에 의해 분비되는 exRNA로 고안될 수 있는 응용 가능분야이다. 본 리뷰에서 장내 미생물군의 probiotics 및 후성유전학적 규제에서 본 exRNA와 exRNA마커와 같은 EV파생 응용프로그램에 대한 의견을 제공할 것이다.

• 한국발생생물학회:학술대회논문집
• /
• 한국발생생물학회 2003년도 제3회 국제심포지움 및 학술대회
• /
• pp.84-84
• /
• 2003

DNA methylation is involved in epigenetic processes such as X-chromosome inactivation, imprinting and silencing of transposons. DNA methylation is a highly plastic and critical component of mammalian development The DNA methyltransferases (Dnmts) are responsible for the generation of genomic methylation patterns, which lead to transcriptional silencing. The maintenance DNA methyltransferase enzyme, Dnmt 1, and the de novo methyltransferase, Dnmt3a and Dnmt3b, are indispensable for development because mice homozygous for the targeted disruption of any of these genes are not viable. The occurrence of DNA methylation is not random, and it can result in gene silencing The mechanisms underlying these processes are poorly understood. It is well established that DNA methylation and histone deacetylation operate along a common mechanistic pathway to repress transcription through the action of methyl-binding domain proteins (MBDs), which are components of, or recruit, histone deacetylase (HDAC) complexes to methylated DNA. As a basis for future studies on the role of the DNA-methyl-transferase in porcine development, we have isolated and characterized a partial cDNA coding for the porcine Dnmt1. Total RNA of testis, lung and ovary was isolated with TRlzol according to the manufacture's specifications. 5 ug of total RNA was reverse transcribed with Super Script II in the presence of porcine Dnmt 1 specific primers. Standard PCRs were performed in a total volume of 50 ul with cDNA as template. Two DNA fragmenets in different position were produced about 700bp, 1500bp and were cloned into pCR II-TOPO according to the manufacture's specification. Assembly of all sequences resulted in a cDNA from 158bp of 5'to 4861bp of 3'compare with the known human maintenance methyltransferase. Now, we are cloning the unknown Dnmt 1 region by 5'-RACE method and expression of Dnmt 1 in tissues from adult porcine animals.

• 한국발생생물학회:학술대회논문집
• /
• 한국발생생물학회 2003년도 제3회 국제심포지움 및 학술대회
• /
• pp.81-81
• /
• 2003

DNA methylation is a covalent modification of DNA that can modulate gene expression and is now recognized as a major component of the epigenome. During evolution, the dinucleotide CpG has been progressively eliminated from the genome of higher eukaryotes and is present at only 5% to 10% of its predicted frequency. Approxymately 80% of the remaining CpG sites contain methylated cytosines in most vertebrates and they are distributed in a pattern that is unique in each tissue and is inversely correlated with gene expression. The pattern of methylation is faithfully maintained during cell division by the enzyme Dnmt1, the maintenance DNA methyltransferase, which catalyzes the transfer of a methyl group from S-adenosyl-methionine to the 5'-position of the cytosine ring. We have been identified bovine Dnmt1 cDNA full-length recently (AY173048) Little is known on the functions of Dnmt1 in bovine preimplantation embryos. Thus, we analyzed the specific pattern of Dnmt1 in in vitro derived/nuclear transfer bovine and in vivo derived mouse embryos to monitor the epigenetic reprogramming process. We investigated these process by using indirect immunofluresence with an antibody to Dnmt1. According to other studies, Dnmt1 accumulates in nuclei of early growing oocytes but is sequestered in the cytoplasm of mature oocytes. In 2-cell and 4-cell embryos, Dnmt1 is cytoplasmic, but at the 8-cell stage, it is present only in the nucleus. By the blastocyst stage, Dnmt1o is again found only in the cytoplasm. Thus, nuclear localization of Dnmt1o in preimplantation embryos is limited to the 8-cell stages After implantation, Dnmt1 is localized in the nucleus in mouse. However, we have found different patterns of Dnmt1 nuclear localization. Though we used the common antibody, immune-localization data revealed that Dnmt1 antibody have been detected at the nucleus in 1-cell to blastocyst embryos. Therefore, maybe we think that the functions of Dnmt1 between bovine and mice are different. In order to Identify the mechanisms that regulate DNA methylation in bovine preimplantation embryo, we have plans on using bovine oocyte and somatic specific Dnmt1 antibodies.

• Animal Bioscience
• /
• 제35권10호
• /
• pp.1461-1478
• /
• 2022

The maintenance of poultry gut health is complex depending on the intricate balance among diet, the commensal microbiota, and the mucosa, including the gut epithelium and the superimposing mucus layer. Changes in microflora composition and abundance can confer beneficial or detrimental effects on fowl. Antibiotics have devastating impacts on altering the landscape of gut microbiota, which further leads to antibiotic resistance or spread the pathogenic populations. By eliciting the landscape of gut microbiota, strategies should be made to break down the regulatory signals of pathogenic bacteria. The optional strategy of conferring dietary fibers (DFs) can be used to counterbalance the gut microbiota. DFs are the non-starch carbohydrates indigestible by host endogenous enzymes but can be fermented by symbiotic microbiota to produce short-chain fatty acids (SCFAs). This is one of the primary modes through which the gut microbiota interacts and communicate with the host. The majority of SCFAs are produced in the large intestine (particularly in the caecum), where they are taken up by the enterocytes or transported through portal vein circulation into the bloodstream. Recent shreds of evidence have elucidated that SCFAs affect the gut and modulate the tissues and organs either by activating G-protein-coupled receptors or affecting epigenetic modifications in the genome through inducing histone acetylase activities and inhibiting histone deacetylases. Thus, in this way, SCFAs vastly influence poultry health by promoting energy regulation, mucosal integrity, immune homeostasis, and immune maturation. In this review article, we will focus on DFs, which directly interact with gut microbes and lead to the production of SCFAs. Further, we will discuss the current molecular mechanisms of how SCFAs are generated, transported, and modulated the pro-and anti-inflammatory immune responses against pathogens and host physiology and gut health.