Domínguez-Rovira Xavier, Arnau-Collell Coral, Gonfaus-Ortiz Gemma, Llargués-Sistac Gemma, Muñoz Jenifer, Llopis Ainara, Soares de Lima Yasmin, Herrera-Pariente Cristina, Moreira Leticia, Ocaña Teresa, Díaz-Gay Marcos, Cuatrecasas Miriam, Carballal Sabela, López-Novo Anael, Fernàndez Guerau, Castells Antoni, Bujanda Luis, Capellà Gabriel, Cubiella Joaquín, Rodríguez-Alcalde Daniel, Valle Laura, Balaguer Francesc, Ruiz-Ponte Clara, Bonjoch Laia, Castellví-Bel Sergi
Gastroenterology, August Pi i Sunyer Biomedical Research Institute (IDIBAPS), CIBEREHD, Hospital Clínic Barcelona, Barcelona, Spain.
Faculty of Medicine and Health Sciences, University of Barcelona (UB), Barcelona, Spain.
Int J Cancer. 2025 Sep 15;157(6):1154-1167. doi: 10.1002/ijc.35492. Epub 2025 May 30.
Serrated polyposis syndrome (SPS) is characterized by multiple and/or large serrated polyps and increased colorectal cancer (CRC) risk. Germline predisposition to SPS is mostly undetermined. We aimed to identify a new inherited SPS predisposition component by functionally evaluating a candidate gene replicated in two independent SPS cohorts. Exome sequencing was performed in a discovery cohort of 39 patients from 16 SPS families, and validation of relevant results was performed by multi-gene panel sequencing in 211 independent SPS patients. Considering the discovery and validation cohorts, three predicted pathogenic missense variants were identified in HIC1 (Hypermethylated in cancer 1): c.110C>T (p.Ala37Val), c.1295A>G (p.Gln432Arg), and c.1411G>A (p.Gly471Arg). HIC1 is a tumor suppressor gene which encodes a transcriptional repressor involved in the DNA damage response, and it is commonly silenced in several cancers and serrated polyps. Two cellular models for HIC1, a CRISPR/Cas9 knockout model and an overexpression model, were produced. In these in vitro models, we assessed DNA damage levels and the SIRT1 regulatory pathway in the presence and absence of the identified variants. Compared to HIC1 wild-type, models harboring the HIC1 variants identified in SPS patients showed higher p-H2AX levels (marker of DNA damage) and impaired HIC1 binding to the SIRT1 promoter. Our results indicate that HIC1 genetic variants located in the zinc finger region affected its transcriptional repressor role. We can conclude that HIC1 may be involved in germline predisposition to SPS through an alteration of its repressor capacity and a faulty DNA damage response, as a molecular mechanism.
锯齿状息肉综合征(SPS)的特征是多发性和/或大的锯齿状息肉以及结直肠癌(CRC)风险增加。SPS的种系易感性大多尚未确定。我们旨在通过对在两个独立的SPS队列中复制的候选基因进行功能评估,来鉴定一种新的遗传性SPS易感性成分。对来自16个SPS家族的39名患者的发现队列进行了外显子组测序,并通过对211名独立SPS患者进行多基因panel测序对相关结果进行了验证。综合发现队列和验证队列,在HIC1(癌症中高甲基化1)中鉴定出三个预测的致病性错义变体:c.110C>T(p.Ala37Val)、c.1295A>G(p.Gln432Arg)和c.1411G>A(p.Gly471Arg)。HIC1是一种肿瘤抑制基因,编码一种参与DNA损伤反应的转录抑制因子,在几种癌症和锯齿状息肉中通常处于沉默状态。构建了HIC1的两种细胞模型,即CRISPR/Cas9敲除模型和过表达模型。在这些体外模型中,我们评估了在存在和不存在已鉴定变体的情况下的DNA损伤水平和SIRT1调节途径。与HIC1野生型相比,携带在SPS患者中鉴定出的HIC1变体的模型显示出更高的p-H2AX水平(DNA损伤标志物),并且HIC1与SIRT1启动子的结合受损。我们的结果表明,位于锌指区域的HIC1基因变体影响了其转录抑制作用。我们可以得出结论,HIC1可能通过改变其抑制能力和错误的DNA损伤反应参与SPS的种系易感性,作为一种分子机制。
