Tumor-related splicing variant RAC1b in colorectal cancer: regulation and role in tumorigenesis

Purpose: Alternative splicing of the small GTPase RAC1 generates RAC1b, a hyperactivated variant that is overexpressed in a subtype of colorectal tumors. The objective of our studies is to understand the molecular regulation of this alternative splicing event and how it contributes to tumorigenesis. Experimental description: The regulation of the RAC1b splicing event in human colon cell lines was dissected using a transfected RAC1 minigene and the role of upstream regulating protein kinases through an RNA interference approach. The functional properties of the RAC1b protein were characterized by experimental modulation of Rac1b levels in colon cell lines. Results: The RAC1b protein results from an in-frame inclusion of an additional alternative exon encoding 19 amino acids that change the regulation and signaling properties of the protein. RAC1b is a hyperactive variant that exists predominantly in the GTP-bound active conformation in vivo and promotes cell cycle progression and cell survival through activation of the transcription factor NF-κB. RAC1b overexpression functionally cooperates with the oncogenic mutation in BRAF-V600E to sustain colorectal tumor cell survival. The splicing factor SRSF1 was identified to bind an exonic splice enhancer element in the alternative exon and acts as a prime regulator of Rac1b alternative splicing in colorectal cells. SRSF1 is controlled by upstream protein kinase SRPK1, the inhibition or depletion of which led to reduced SRSF1 phosphorylation and nuclear translocation with a concomitant reduction in RAC1b levels. As further SRSF1-regulating pathways we discovered kinase GSK3 and a cyclooxygenase independent effect of the non-steroidal anti-inflammatory drug ibuprofen. Conclusions: Expression of tumor-related RAC1b in colorectal cancer depends critically on SRSF1 for the observed deregulation of alternative splicing during tumorigenesis and is controlled by upstream protein kinases that can be pharmacologically targeted.

Base molecular da hemocromatose hereditária não-clássica em Portugal

A Hemocromatose Hereditária (HH) é uma doença autossómica recessiva caracterizada pela absorção excessiva de ferro a nível intestinal e sua acumulação em órgãos vitais, podendo originar cardiomiopatia, cirrose e carcinoma hepatocelular. O correspondente diagnóstico molecular é obtido pela associação com genótipos específicos no gene HFE (homozigotia para p.Cys282Tyr ou heterozigotia composta p.Cys282Tyr/p.His63Asp). Contudo, nos países do sul da Europa, cerca de um terço dos doentes com diagnóstico clínico de HH não apresenta os referidos genótipos. Para identificar a base molecular da HH não-clássica em Portugal usaram-se metodologias de pesquisa geral de variantes genéticas (SSCP e dHPLC), Next-Generation Sequencing (NGS) e sequenciação de Sanger, cobrindo seis genes relacionados com o metabolismo do ferro em 303 doentes. Identificaram-se 69 variantes diferentes e de vários tipos, por ex. missense, nonsense, de splicing, que perturbam a transcrição do gene ou a regulação da tradução do mRNA. Seguidamente, realizaram-se estudos in silico e in vitro para esclarecer o significado etiológico de algumas das novas variantes. Concluiu-se que a base molecular desta patologia é bastante heterogénea e que a NGS é uma ferramenta adequada para efetuar a análise simultânea dos vários genes num grande número de amostras. Contudo, o estabelecimento da relevância clínica de algumas variantes requer a realização de estudos funcionais.

Next-generation sequencing of iron-metabolism related genes in Portuguese patients with iron overload: novel pathogenic genetic variants

Objective: In Southern European countries up to one-third of the patients with hereditary hemochromatosis (HH) do not present the common HFE risk genotype. In order to investigate the molecular basis of these cases we have designed a gene panel for rapid and simultaneous analysis of 6 HH-related genes (HFE, TFR2, HJV, HAMP, SLC40A1 and FTL) by next-generation sequencing (NGS). Materials and Methods: Eighty-eight iron overload Portuguese patients, negative for the common HFE mutations, were analysed. A TruSeq Custom Amplicon kit (TSCA, by Illumina) was designed in order to generate 97 amplicons covering exons, intron/exon junctions and UTRs of the mentioned genes with a cumulative target sequence of 12115bp. Amplicons were sequenced in the MiSeq instrument (IIlumina) using 250bp paired-end reads. Sequences were aligned against human genome reference hg19 using alignment and variant caller algorithms in the MiSeq reporter software. Novel variants were validated by Sanger sequencing and their pathogenic significance were assessed by in silico studies. Results: We found a total of 55 different genetic variants. These include novel pathogenic missense and splicing variants (in HFE and TFR2), a very rare variant in IRE of FTL, a variant that originates a novel translation initiation codon in the HAMP gene, among others. Conclusion: The merging of TSCA methodology and NGS technology appears to be an appropriate tool for simultaneous and fast analysis of HH-related genes in a large number of samples. However, establishing the clinical relevance of NGS-detected variants for HH development remains a hard-working task, requiring further functional studies.