J. Sevcik

The CHEK2 gene I157T mutation and other alterations in its proximity increase the risk of sporadic colorectal cancer in the Czech population.

Checkpoint kinase 2 (CHEK2) gene codes for an important mediator of DNA damage response pathway. Its mutations increase risk of several types of cancer. We analysed selected CHEK2 mutations in 631 Czech colorectal cancer (CRC) patients. The increased risk of CRC was associated with mutations in CHEK2 gene region involving fork head-associated domain [39/631 (6.2%) cases versus 19/683 (2.8%) controls; odds ratio (OR)=2.3; 95% confidence interval (CI)=1.3-4.0; p=0.003], and with the most frequent I157T mutation [30/631 (4.8%) cases versus 17/683 (2.5%) controls; OR=2.0; 95% CI=1.1-3.6; p=0.03]. Prevalence of 1100delC mutation in CRC patients (4/631) did not differ from that in the control population (2/730; p=0.4). The deletion of 5395 bp was not found in any of the successfully analysed CRC cases. We observed no association of analysed mutations with CRC family history. We conclude that the I157T and other alterations in its proximity predispose to sporadic but not to familial CRC in the Czech population.

Expression of human BRCA1Δ17-19 alternative splicing variant with a truncated BRCT domain in MCF-7 cells results in impaired assembly of DNA repair complexes and aberrant DNA damage response

Alternative pre-mRNA splicing is a fundamental post-transcriptional regulatory mechanism. Cancer-specific misregulation of the splicing process may lead to formation of irregular alternative splicing variants (ASVs) with a potentially negative impact on cellular homeostasis. Alternative splicing of BRCA1 pre-mRNA can give rise to BRCA1 protein isoforms that possess dramatically altered biological activities compared with full-length wild-type BRCA1. During the screening of high-risk breast cancer (BC) families we ascertained numerous BRCA1 ASVs, however, their clinical significance for BC development is largely unknown. In this study, we examined the influence of the BRCA1Δ17-19 ASV, which lacks a portion of the BRCT domain, on DNA repair capacity using human MCF-7 BC cell clones with stably modified BRCA1 expression. Our results show that overexpression of BRCA1Δ17-19 impairs homologous recombination repair (sensitizes cells to mitomycin C), delays repair of ionizing radiation-induced DNA damage and dynamics of the ionizing radiation-induced foci (IRIF) formation, and undermines also the non-homologous end joining repair (NHEJ) activity. Mechanistically, BRCA1Δ17-19 cannot interact with the partner proteins Abraxas and CtIP, thus preventing interactions known to be critical for processing of DNA lesions. We propose that the observed inability of BRCA1Δ17-19 to functionally replace wtBRCA1 in repair of DNA double-strand breaks (DDSB) reflects impaired capacity to form the BRCA1-A and -C repair complexes. Our findings indicate that expression of BRCA1Δ17-19 may negatively influence genome stability by reducing the DDSB repair velocity, thereby contributing to enhanced probability of cancer development in the affected families.

Human Keratinocyte Growth and Differentiation on Acellular Porcine Dermal Matrix in relation to Wound Healing Potential

A number of implantable biomaterials derived from animal tissues are now used in modern surgery. Xe-Derma is a dry, sterile, acellular porcine dermis. It has a remarkable healing effect on burns and other wounds. Our hypothesis was that the natural biological structure of Xe-Derma plays an important role in keratinocyte proliferation and formation of epidermal architecture in vitro as well as in vivo. The bioactivity of Xe-Derma was studied by a cell culture assay. We analyzed growth and differentiation of human keratinocytes cultured in vitro on Xe-Derma, and we compared the results with formation of neoepidermis in the deep dermal wounds treated with Xe-Derma. Keratinocytes cultured on Xe-Derma submerged in the culture medium achieved confluence in 7–10 days. After lifting the cultures to the air-liquid interface, the keratinocytes were stratified and differentiated within one week, forming an epidermis with basal, spinous, granular, and stratum corneum layers. Immunohistochemical detection of high-molecular weight cytokeratins (HMW CKs), CD29, p63, and involucrin confirmed the similarity of organization and differentiation of the cultured epidermal cells to the normal epidermis. The results suggest that the firm natural structure of Xe-Derma stimulates proliferation and differentiation of human primary keratinocytes and by this way improves wound healing.

The BRCA1 alternative splicing variant Δ14-15 with an in-frame deletion of part of the regulatory serine-containing domain (SCD) impairs the DNA repair capacity in MCF-7 cells

The BRCA1 gene codes for a protein involved in the DNA double strand break (DDSB) repair. Alongside the dominant full-length splicing form of BRCA1, numerous endogenously expressed alternative splicing variants of unknown significance have been described in various tissues. Some of them retain the original BRCA1 reading frame but lack several critical BRCA1 structural domains, suggesting an altered function of the resulting protein in the BRCA1-regulated processes. To characterize the effect of the BRCA1Δ14-15 splicing variant (with an in-frame deletion affecting the regulatory serine-containing domain) on the DDSB repair, we constructed the MCF-7 clones stably expressing the analyzed variant with/without a shRNA-mediated downregulation of the endogenous full-length wild-type BRCA1 expression. Our results show that the expression of the BRCA1Δ14-15 variant delays the γ-radiation-induced DDSB repair, alters the kinetics of irradiation-induced foci formation/decomposition and reduces the non-homologous end-joining capacity in MCF-7 cells. Therefore, the BRCA1Δ14-15 is not able to functionally replace the full-length wt BRCA1 in the DDSB repair. Our findings indicate that the endogenously expressed BRCA1 alternative splicing variants may negatively influence genome stability and support the growing evidence of the pathological potential of the sequence variants generated by an altered or misregulated alternative splicing in the process of mammary malignant transformation.

Expression and function of dipeptidyl peptidase IV and related enzymes in cancer.

Numerous biologically active peptides, systemic as well as local hormones, contain an evolutionary conserved proline residue as a proteolytic-processing regulatory element (Vanhoof et al 1995). Limited proteolysis of multiple neuropeptides, chemokines, incretins etc. by dipeptidyl peptidase-IV (DPP-IV) enzymatic activity (De Meester et al 2000) leads to both quantitative and in some cases due to the diversification of their receptor preference, also qualitative changes of their signaling potential (Busek et al 2004). Such hydrolytic activity was originally recognized as “canonical” DPP-IV/CD26 (EC 3.4.14.5). Work over the past years has demonstrated that DPP-IV has a multitude of physiological roles (Lambeir et al 2003). Although the greatest part of systemic DPP-IV activity probably resides in DPP-IV/CD26, further studies demonstrated that a significant amount of DPP-IV activity can be attributed to a growing panel of other proteins, including Fibroblast-activation protein α/Seprase (FAP), Quiescent cell proline dipeptidase (QPP/DPP-II/DPP-7), DPP8, DPP9 and Attractin. Moreover, several additional molecules devoid of the characteristic enzymatic activity, but possessing high degree of structural similarity to DPP-IV, for example DPP6 and 10, were included among DASH molecules too (Sedo and Malik, 2001). So far, DPP-IV, FAP and DPP-II/QPP have been shown to participate on the regulation of multiple important cellular programs, including cell growth, transformation, apoptosis, invasion and tumor metastasis. In contrast to proteases involved in cancer development and progression as the executors of tissue degradation, most DASH operate as regulatory molecules, modifying biologically active peptides. The DASH, their substrates and corresponding receptors of these substrates are jointly expressed in many tissues and their deregulation has been observed in the microenvironment of numerous malignancies (Table 1). An antioncogenic effect of DPP-IV was demonstrated by experimentally induced expression in cell lines derived frommelanoma (Wesley et al 1999), ovarian carcinoma (Kajiyama et al 2002, 2003), non-small cell lung carcinoma (NSCLC; Wesley et al 2004) and lately prostatic

Dipeptidyl Peptidase-IV Activity and/or Structure Homologs (DASH): Contributing Factors in the Pathogenesis of Rheumatic Diseases?

Deregulation of DPP-IV-like activity was observed in synovial fluid and blood plasma of patients with RA and PsA. The cellular source of soluble DPP-IV-like enzymatic activity remains unclear.

Abstract 1859: Bioinformatic and experimental evaluation of regulatory variants in breast cancer susceptibility genes

Many germline DNA sequence variants in gene regulatory elements are associated with an increased risk of cancer. These include large genomic deletions of the promoter of the BRCA1 gene, through to single nucleotide variants in the promoter, UTRs and long-range enhancers of multiple other cancer related genes. Next generation sequence analysis of early onset and familial breast cancer cases is currently identifying an escalating number of variants in non-coding regions of the genome, however for most of these the significance in unknown. This project aims to determine the functional and clinical significance of breast cancer associated variants in regulatory regions of BRCA1 and BRCA2, as part of an international collaborative project arising from the Evidence-based Network for the Interpretation of Germline Mutant Alleles (ENIGMA) consortium. To date over two hundred variants mapping to promoter, UTR and deep intronic regions have been identified in early onset or familial breast cancer patients that have no identifiable coding or splicing changes in BRCA1 or BRCA2. Through a pipeline of bioinformatics analyses using ENCODE datasets, these variants have been prioritized for experimental evaluation. This has lead to the identification of several variants that significantly alter the regulation of BRCA1 or BRCA2 expression, through mechanisms including altered binding of transcription factors and microRNAs. These studies will lay the groundwork for comprehensive statistical analyses, in which bioinformatics and experimental data is combined with clinical and genetic data to establish multifactorial risk prediction models that can ultimately be used in a clinical setting. Citation Format: Jan Sevcik, Leslie Burke, Gaetana Gambino, Brooke L. Brewster, Emma Tudini, Philip J. Whiley, Siranoush Manoukian, ENIGMA Consortium, Thomas van Overeem Hansen, Marta Santamarina Pena, Ana Vega, Maria A. Caligo, Paolo Radice, Paolo Peterlongo, Etienne Rouleau, Amanda B. Spurdle, Melissa A. Brown. Bioinformatic and experimental evaluation of regulatory variants in breast cancer susceptibility genes. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 1859.