[Objective] This study aimed to conduct bioinformatics analysis of histone H3-1ys-4 (H3K4) methyltransferase MLL3 in animals, thus exploring its relatively conservative evolution to reveal the role of histon H3K4 tr...[Objective] This study aimed to conduct bioinformatics analysis of histone H3-1ys-4 (H3K4) methyltransferase MLL3 in animals, thus exploring its relatively conservative evolution to reveal the role of histon H3K4 trimethyltransferase MLL3 in human cancers. [Method] By using bioinformatics method, gene structure, amino acid sequences, phylogenetic tree, chromosomal localization and synteny of mouse MLL3 were analyzed. [Result] Primary structure of the encoded mouse MLL3 protein con- tained seven zinc finger domains, an HMG-box (High mobility group-box protein), a FYRN (F/Y-rich N-terminus) domain, a FYRC (F/Yrich C-terminus) domain, a SET domain and a postSET domain. Results of sequence comparison and homology showed that 19 animal species in this study all had these structures basically, which indicated that these structures were relatively conserved in the evolution; specifically, the SET domain was highly conserved and was necessary to maintain the activity of histone methyltransferases. Results of phylogenetic analysis showed that the loca- tions of the 19 animal species in evolutionary tree were consistent with the taxo- nomic status. Results of synteny analysis showed that there were the same gene in the upstream and downstream of the mouse and human MLL3 gene which were located on different chromosomes, indicating that the mouse and human MLL3 gene had collinearity. [Conclusion] This study had revealed the primary structure of MLL3 nucleotide sequence and amino acid sequence, which had not only laid the foundation for the future research of high-level structure and function of MLL3 protein but also provided the basis for the follow-up study of primer design, promoter analysis, gene cloning and regulation patterns of localization and expression of mouse MLL3 gene.展开更多
The MLL/SET family of histone H3 lysine 4 methyltransferases form enzyme complexes with core subunits ASH2L, WDR5, RbBP5, and DPY-30 (often abbreviated WRAD), and are responsible for global histone H3 iysine 4 methy...The MLL/SET family of histone H3 lysine 4 methyltransferases form enzyme complexes with core subunits ASH2L, WDR5, RbBP5, and DPY-30 (often abbreviated WRAD), and are responsible for global histone H3 iysine 4 methylation, a hallmark of actively transcribed chromatin in mammalian cells. Accordingly, the function of these proteins is required for a wide variety of processes including stem cell differentiation, cell growth and division, body segmentation, and hematopoiesis. While most work on MLL-WRAD has focused on the function this core complex in histone methylation, recent studies indicate that MLL-WRAD proteins interact with a variety of other proteins and IncRNAs and can localize to cellular organelles beyond the nucleus. In this review, we focus on the recently described activities and interacting partners of MLL-WRAD both inside and outside the nucleus.展开更多
基金Supported by National Natural Science Foundation of China (No.31071310)Provincial Scientific Research Institution Commissioned Special Project of Fuyang Normal University (No.2011PTFY03ZD)+1 种基金Natural Science Research Project for Universities from the Education Department of Anhui Province (KJ2011B121)Natural Science Foundation of Fuyang Normal University (No.2010FSKJ13)~~
文摘[Objective] This study aimed to conduct bioinformatics analysis of histone H3-1ys-4 (H3K4) methyltransferase MLL3 in animals, thus exploring its relatively conservative evolution to reveal the role of histon H3K4 trimethyltransferase MLL3 in human cancers. [Method] By using bioinformatics method, gene structure, amino acid sequences, phylogenetic tree, chromosomal localization and synteny of mouse MLL3 were analyzed. [Result] Primary structure of the encoded mouse MLL3 protein con- tained seven zinc finger domains, an HMG-box (High mobility group-box protein), a FYRN (F/Y-rich N-terminus) domain, a FYRC (F/Yrich C-terminus) domain, a SET domain and a postSET domain. Results of sequence comparison and homology showed that 19 animal species in this study all had these structures basically, which indicated that these structures were relatively conserved in the evolution; specifically, the SET domain was highly conserved and was necessary to maintain the activity of histone methyltransferases. Results of phylogenetic analysis showed that the loca- tions of the 19 animal species in evolutionary tree were consistent with the taxo- nomic status. Results of synteny analysis showed that there were the same gene in the upstream and downstream of the mouse and human MLL3 gene which were located on different chromosomes, indicating that the mouse and human MLL3 gene had collinearity. [Conclusion] This study had revealed the primary structure of MLL3 nucleotide sequence and amino acid sequence, which had not only laid the foundation for the future research of high-level structure and function of MLL3 protein but also provided the basis for the follow-up study of primer design, promoter analysis, gene cloning and regulation patterns of localization and expression of mouse MLL3 gene.
文摘The MLL/SET family of histone H3 lysine 4 methyltransferases form enzyme complexes with core subunits ASH2L, WDR5, RbBP5, and DPY-30 (often abbreviated WRAD), and are responsible for global histone H3 iysine 4 methylation, a hallmark of actively transcribed chromatin in mammalian cells. Accordingly, the function of these proteins is required for a wide variety of processes including stem cell differentiation, cell growth and division, body segmentation, and hematopoiesis. While most work on MLL-WRAD has focused on the function this core complex in histone methylation, recent studies indicate that MLL-WRAD proteins interact with a variety of other proteins and IncRNAs and can localize to cellular organelles beyond the nucleus. In this review, we focus on the recently described activities and interacting partners of MLL-WRAD both inside and outside the nucleus.