Lin Jason, Hiraoka Kiriko, Watanabe Takayoshi, Kuo Tony, Shinozaki Yoshinao, Takatori Atsushi, Koshikawa Nobuko, Chandran Anandhakumar, Otsuki Joe, Sugiyama Hiroshi, Horton Paul, Nagase Hiroki
Laboratory of Cancer Genetics, Chiba Cancer Center Research Institute, Chuo-ku, Chiba, Japan.
Artificial Intelligence Research Center, National Institute of Advanced Industrial Science and Technology, Koto-ku, Tokyo, Japan.
PLoS One. 2016 Oct 31;11(10):e0165581. doi: 10.1371/journal.pone.0165581. eCollection 2016.
Pyrrole-imidazole polyamides are versatile DNA minor groove binders and attractive therapeutic options against oncological targets, especially upon functionalization with an alkylating agent such as seco-CBI. These molecules also provide an alternative for oncogenes deemed "undruggable" at the protein level, where the absence of solvent-accessible pockets or structural crevices prevent the formation of protein-inhibitor ligands; nevertheless, the genome-wide effect of pyrrole-imidazole polyamide binding remain largely unclear to-date. Here we propose a next-generation sequencing-based workflow combined with whole genome expression arrays to address such issue using a candidate anti-cancer alkylating agent, KR12, against codon 12 mutant KRAS. Biotinylating KR12 enables the means to identify its genome-wide effects in living cells and possible biological implications via a coupled workflow of enrichment-based sequencing and expression microarrays. The subsequent computational pathway and expression analyses allow the identification of its genomic binding sites, as well as a route to explore a polyamide's possible genome-wide effects. Among the 3,343 KR12 binding sites identified in the human LS180 colorectal cancer genome, the reduction of KR12-bound gene expressions was also observed. Additionally, the coupled microarray-sequencing analysis also revealed some insights about the effect of local chromatin structure on pyrrole-imidazole polyamide, which had not been fully understood to-date. A comparative analysis with KR12 in a different human colorectal cancer genome SW480 also showed agreeable agreements of KR12 binding affecting gene expressions. Combination of these analyses thus suggested the possibility of applying this approach to other pyrrole-imidazole polyamides to reveal further biological details about the effect of polyamide binding in a genome.
吡咯 - 咪唑聚酰胺是多功能的DNA小沟结合剂,是针对肿瘤靶点的有吸引力的治疗选择,特别是在用烷基化剂(如seco - CBI)进行功能化后。这些分子也为在蛋白质水平被认为“不可成药”的癌基因提供了一种替代方案,因为在这些癌基因中,缺乏溶剂可及的口袋或结构裂缝会阻止蛋白质 - 抑制剂配体的形成;然而,迄今为止,吡咯 - 咪唑聚酰胺结合的全基因组效应仍 largely不清楚。在这里,我们提出了一种基于下一代测序的工作流程,并结合全基因组表达阵列,使用候选抗癌烷基化剂KR12针对密码子12突变的KRAS来解决此类问题。对KR12进行生物素化能够通过基于富集的测序和表达微阵列的耦合工作流程,识别其在活细胞中的全基因组效应以及可能的生物学意义。随后的计算途径和表达分析能够识别其基因组结合位点,以及探索聚酰胺可能的全基因组效应的途径。在人类LS180结肠直肠癌基因组中鉴定出的3343个KR12结合位点中,还观察到了KR12结合基因表达的降低。此外,耦合的微阵列 - 测序分析还揭示了一些关于局部染色质结构对吡咯 - 咪唑聚酰胺影响的见解,这些见解迄今为止尚未被完全理解。在另一个人类结肠直肠癌基因组SW480中对KR12进行的比较分析也显示,KR12结合影响基因表达的结果一致。因此,这些分析的结合表明,有可能将这种方法应用于其他吡咯 - 咪唑聚酰胺,以揭示关于聚酰胺结合在基因组中的影响的更多生物学细节。
