Chen Yunqin, Li Yixue, Wei Jia, Li Yuan-Yuan
Shanghai Center for Bioinformation Technology, Shanghai, P R China.
BMC Genomics. 2014 Jun 24;15(1):519. doi: 10.1186/1471-2164-15-519.
In eukaryotic genomes, about 10% of genes are arranged in a head-to-head (H2H) orientation, and the distance between the transcription start sites of each gene pair is closer than 1 kb. Two genes in an H2H pair are prone to co-express and co-function. There have been many studies on bidirectional promoters. However, the mechanism by which H2H genes are regulated at the transcriptional level still needs further clarification, especially with regard to the co-regulation of H2H pairs. In this study, we first used the Hi-C data of chromatin linkages to identify spatially interacting H2H pairs, and then integrated ChIP-seq data to compare H2H gene pairs with and without evidence of spatial interactions in terms of their binding transcription factors (TFs). Using ChIP-seq and DNase-seq data, histones and DNase associated with H2H pairs were identified. Furthermore, we looked into the connections between H2H genes in a human co-expression network.
We found that i) Similar to the behaviour of two genes within an H2H pair (intra-H2H pair), a gene pair involving two distinct H2H pairs (inter-H2H pair) which interact with each other spatially, share common transcription factors (TFs); ii) TFs of intra- and inter-H2H pairs are distributed differently. Factors such as HEY1, GABP, Sin3Ak-20, POL2, E2F6, and c-MYC are essential for the bidirectional transcription of intra-H2H pairs; while factors like CTCF, BDP1, GATA2, RAD21, and POL3 play important roles in coherently regulating inter-H2H pairs; iii) H2H gene blocks are enriched with hypersensitive DNase and modified histones, which participate in active transcriptions; and iv) H2H genes tend to be highly connected compared with non-H2H genes in the human co-expression network.
Our findings shed new light on the mechanism of the transcriptional regulation of H2H genes through their linear and spatial interactions. For intra-H2H gene pairs, transcription factors regulate their transcriptions through bidirectional promoters, whereas for inter-H2H gene pairs, transcription factors are likely to regulate their activities depending on the spatial interaction of H2H gene pairs. In this way, two distinctive groups of transcription factors mediate intra- and inter-H2H gene transcriptions respectively, resulting in a highly compact gene regulatory network.
在真核生物基因组中,约10%的基因以头对头(H2H)方向排列,且每对基因转录起始位点之间的距离小于1 kb。H2H基因对中的两个基因易于共表达和共同发挥功能。关于双向启动子已有许多研究。然而,H2H基因在转录水平上的调控机制仍需进一步阐明,尤其是关于H2H基因对的协同调控。在本研究中,我们首先利用染色质连接的Hi-C数据来识别空间相互作用的H2H基因对,然后整合ChIP-seq数据,以比较有和没有空间相互作用证据的H2H基因对在结合转录因子(TFs)方面的情况。利用ChIP-seq和DNase-seq数据,识别了与H2H基因对相关的组蛋白和DNase。此外,我们研究了人类共表达网络中H2H基因之间的联系。
我们发现:i)与H2H基因对(H2H对内)中的两个基因的行为类似,涉及两个相互空间作用的不同H2H基因对(H2H对间)的基因对共享共同的转录因子(TFs);ii)H2H对内和H2H对间的TFs分布不同。诸如HEY1、GABP、Sin3Ak-20、POL2、E2F6和c-MYC等因子对H2H对内的双向转录至关重要;而诸如CTCF、BDP1、GATA2、RAD21和POL3等因子在协同调控H2H对间发挥重要作用;iii)H2H基因块富含超敏DNase和修饰的组蛋白,它们参与活跃转录;iv)在人类共表达网络中,与非H2H基因相比,H2H基因倾向于高度连接。
我们的研究结果通过H2H基因的线性和空间相互作用,为H2H基因转录调控机制提供了新的见解。对于H2H内基因对,转录因子通过双向启动子调节其转录,而对于H2H对间基因对,转录因子可能根据H2H基因对的空间相互作用来调节其活性。通过这种方式,两组不同的转录因子分别介导H2H内和H2H对间基因的转录,形成一个高度紧凑的基因调控网络。
