Implications of CLSPN Variants in Cellular Function and Susceptibility to Cancer.

Claspin is a multifunctional protein that participates in physiological processes essential for cell homeostasis that are often defective in cancer, namely due to genetic changes. It is conceivable that Claspin gene (CLSPN) alterations may contribute to cancer development. Therefore, CLSPN germline alterations were characterized in sporadic and familial breast cancer and glioma samples, as well as in six cancer cell lines. Their association to cancer susceptibility and functional impact were investigated. Eight variants were identified (c.-68C>T, c.17G>A, c.1574A>G, c.2230T>C, c.2028+16G>A, c.3595-3597del, and c.3839C>T). CLSPN c.1574A>G (p.Asn525Ser) was significantly associated with breast cancer and was shown to cause partial exon skipping and decreased Claspin expression and Chk1 activation in a minigene splicing assay and in signalling experiments, respectively. CLSPN c.2028+16G>A was significantly associated with familial breast cancer and glioma, whereas c.2230T>C (p.Ser744Pro), was exclusively detected in breast cancer and glioma patients, but not in healthy controls. The remaining variants lacked a significant association with cancer. Nevertheless, the c.-68C>T promoter variant increased transcriptional activity in a luciferase assay. In conclusion, some of the CLSPN variants identified in the present study appear to modulate Claspin's function by altering CLSPN transcription and RNA processing, as well as Chk1 activation.

Claspin: From replication stress and DNA damage responses to cancer therapy.

Cancer is still one of the major causes of death worldwide. Radiation therapy and chemotherapy remain the main treatment modalities in cancer. These therapies exert their effect mainly through interference with DNA replication and induction of DNA damage. It is believed that one way of improving the efficacy of cancer treatment will be to inhibit the replication stress and DNA damage responses and promote mitotic catastrophe of cancer cells. So far, the majority of the efforts have focused central players of checkpoint responses, such as ATR and CHK1, and DNA damage repair, such as PARPs. Being a key player in the replication stress response, checkpoint activation, and the DNA damage response, Claspin constitutes an attractive therapeutic target in cancer, namely for radio- and chemo-sensitization. In this review, we will go through Claspin functions in the replication stress and DNA damage responses and will discuss how Claspin can be targeted in cancer treatment, as well as the effects of Claspin inhibition.

Claspin functions in cell homeostasis-A link to cancer?

Cancer remains one of the leading causes of mortality worldwide. Most cancers present high degrees of genomic instability. DNA damage and replication checkpoints function as barriers to halt cell cycle progression until damage is resolved, preventing the perpetuation of errors. Activation of these checkpoints is critically dependent on Claspin, an adaptor protein that mediates the phosphorylation of the effector kinase Chk1 by ATR. However, Claspin also performs other roles related to the protection and maintenance of cell and genome integrity. For instance, following DNA damage and checkpoint activation, Claspin bridges checkpoint responses to DNA repair or to apoptosis. During DNA replication, Claspin acts a sensor and couples DNA unwinding to strand polymerization, and may also indirectly regulate replication initiation at firing origins. As Claspin participates in several processes that are vital to maintenance of cell homeostasis, its function is tightly regulated at multiple levels. Nevertheless, little is known about its role in cancer. Accumulating evidence suggests that Claspin inactivation could be an essential event during carcinogenesis, indicating that Claspin may function as a tumour suppressor. In this review, we will examine the functions of Claspin and how its deregulation may contribute to cancer initiation and progression. To conclude, we will discuss means by which Claspin can be targeted for cancer therapy.

[Gastric carcinoma and chronic gastritis: epigenetic regulation of CDH1 (E-Cadherin), CDKN2A (p16INK4A), PTGS2 (COX-2) and EGFR genes through methylation]. / Carcinoma gástrico e gastrite crónica: regulação epigenética por metilação dos genes CDH1 (Caderina-E), CDKN2A (p16INK4A), PTGS2 (COX2) e EGFR.

The genetic and epigenetic alterations are being studied as one of the causes of gastric cancer (GC) progression and development. DNA methylation is an epigenetic alteration which leads to suppressor gene silencing and proto-oncogene activation, playing an important role in carcinogenesis. The histological types of gastric carcinoma have different genetic paths and the knowledge of the molecular bases of tumoral progression leads to diagnostic accuracy and attempted therapy. CDH1 (E-cadherin) and CDKN2A (p16(INK4A)) genes are thought to be tumoral suppressor genes and PTGS2 (COX-2) and genes are involved in tumour regulation and growth. In one hand, gene silencing as an epigenetic phenomenon, and in the other hand, gene expression enhancement due to possible demethylation, simultaneously, can facilitate carcinogénesis and tumoral progression. Our aim was to relate CDH1, p16(INK4A), COX-2 and EGFR genes DNA methylation with the several histological types of gastric carcinoma and chronic gastritis. We studied 55 formalin fixed paraffin embedded gastric biopsies: 35 were GC specimens (12 diffuse type, 15 intestinal type and 8 indeterminate type, according to Laurén's classification) and 20 samples had chronic gastritis (CG). The DNA was treated with sodium bisulfite after extraction and then performed Methylation Specific PCR (MSP). Statistical analysis was based on chi-square test and Exact Fisher's test. CpG island methylation was detected in 94% of the GC samples for CDH1, 91% for COX-2, 80% for p16(INK4A) and no methylation was detected in EGFR gene (0%). In CG, CpG island methylation was found in 100% for CDH1 and COX-2 genes, 90% for p16(INK4A) and 20% for EGFR. These results reveal significant differences in EGFR gene methylation distinguishing GC from CG (p < 0, 01), suggesting that gene demethylation leads to malignant transformation and favours the use of tyrosine-kinase inhibitors in its treatment. Genes COX2 e p16INK4A lower methylation in intestinal and diffuse types of GC, favours their different role in respective histogenesis.

Male specific association between the 5-HTR6 gene 267C/T SNP and suicide in the Portuguese population.

Serotonergic system dysfunction has been implicated in the etiology of suicide. A large number of genetic studies have focused on the potential involvement of genes coding for components of serotonergic system in suicidal behavior. However, other genes belonging to this system remain to be investigated or have been poorly studied, as is the case of the 5-HT6 receptor (5-HTR6) gene. In this study, we investigated the potential association between the 5-HTR6 gene 267C/T SNP and suicide in a Portuguese population. Blood samples were collected from 179 suicide victims and 189 controls. Genotypes for the 5-HTR6 gene 267C/T SNP were obtained with the restriction enzyme Rsa I. A tendency was found for genotype association between this polymorphism and suicide, but the differences were not statistically significant (chi(2)=5.374, df=2, p=0.068). However, a gender-specific association was detected when comparing the genotype distribution between male suicide victims and male controls (chi(2)=6.988, df=2, p=0.030), suggesting that this SNP might have a role in the etiology of suicide in male subjects in the Portuguese population.