Zhang Yuning, Ho Tiffany D, Buchler Nicolas E, Gordân Raluca
Center for Genomic and Computational Biology, Duke University, Durham, North Carolina 27708, USA.
Program in Computational Biology and Bioinformatics, Duke University, Durham, North Carolina 27708, USA.
Genome Res. 2021 Jul;31(7):1216-1229. doi: 10.1101/gr.275145.120. Epub 2021 May 11.
Most eukaryotic transcription factors (TFs) are part of large protein families, with members of the same family (i.e., paralogous TFs) recognizing similar DNA-binding motifs but performing different regulatory functions. Many TF paralogs are coexpressed in the cell and thus can compete for target sites across the genome. However, this competition is rarely taken into account when studying the in vivo binding patterns of eukaryotic TFs. Here, we show that direct competition for DNA binding between TF paralogs is a major determinant of their genomic binding patterns. Using yeast proteins Cbf1 and Pho4 as our model system, we designed a high-throughput quantitative assay to capture the genomic binding profiles of competing TFs in a cell-free system. Our data show that Cbf1 and Pho4 greatly influence each other's occupancy by competing for their common putative genomic binding sites. The competition is different at different genomic sites, as dictated by the TFs' expression levels and their divergence in DNA-binding specificity and affinity. Analyses of ChIP-seq data show that the biophysical rules that dictate the competitive TF binding patterns in vitro are also followed in vivo, in the complex cellular environment. Furthermore, the Cbf1-Pho4 competition for genomic sites, as characterized in vitro using our new assay, plays a critical role in the specific activation of their target genes in the cell. Overall, our study highlights the importance of direct TF-TF competition for genomic binding and gene regulation by TF paralogs, and proposes an approach for studying this competition in a quantitative and high-throughput manner.
大多数真核转录因子(TFs)是大型蛋白质家族的一部分,同一家族的成员(即旁系同源TFs)识别相似的DNA结合基序,但执行不同的调控功能。许多TF旁系同源物在细胞中共表达,因此可以竞争全基因组的靶位点。然而,在研究真核TFs的体内结合模式时,这种竞争很少被考虑在内。在这里,我们表明TF旁系同源物之间对DNA结合的直接竞争是其基因组结合模式的主要决定因素。以酵母蛋白Cbf1和Pho4作为我们的模型系统,我们设计了一种高通量定量测定法,以在无细胞系统中捕获竞争性TFs的基因组结合谱。我们的数据表明,Cbf1和Pho4通过竞争它们共同的假定基因组结合位点,极大地影响彼此的占据情况。竞争在不同的基因组位点有所不同,这取决于TFs的表达水平以及它们在DNA结合特异性和亲和力上的差异。ChIP-seq数据分析表明,在体外决定竞争性TF结合模式的生物物理规则在体内复杂的细胞环境中也同样适用。此外,使用我们的新测定法在体外表征的Cbf1-Pho4对基因组位点的竞争,在细胞中对其靶基因的特异性激活中起关键作用。总体而言,我们的研究突出了TF旁系同源物之间对基因组结合和基因调控的直接TF-TF竞争的重要性,并提出了一种以定量和高通量方式研究这种竞争的方法。
