10 research outputs found
Tyrosine phosphatases as a superfamily of tumor suppressors in colorectal cancer
Phosphorylation and dephosphorylation processes catalyzed by numerous kinases and phosphorylases are essential for cell homeostasis and may lead to disturbances in a variety of vital cellular pathways, such as cell proliferation and differentiation, and thus to complex diseases including cancer. As over 80 % of all oncogenes encode protein tyrosine kinases (PTKs), protein tyrosine phosphatases (PTPs), which can reverse the effects of tyrosine kinases, are very important tumor suppressors. Alterations in tyrosine kinase and phosphatase genes including point mutations, changes in epigenetic regulation, as well as chromosomal aberrations involving regions critical to these genes, are frequently observed in a variety of cancers. Colorectal cancer (CRC) is one of the most common cancers in humans. CRCs occur in a familial (about 15 % of all cases), hereditary (about 5%) and sporadic (almost 75-80 %) form. As genetic-environmental interrelations play an important role in the susceptibility to sporadic forms of CRCs, many studies are focused on genetic alterations in such tumors. Mutational analysis of the tyrosine phosphatome in CRCs has identified somatic mutations in PTPRG, PTPRT, PTPN3, PTPN13 and PTPN14. The majority of these mutations result in a loss of protein function. Also, alterations in the expression of these genes, such as decreased expression of PTPRR, PTPRO, PTPRG and PTPRD, mediated by epigenetic mechanisms have been observed in a variety of tumors. Since cancer is a social and global problem, there will be a growing number of studies on alterations in the candidate cancer genes, including protein kinases and phosphatases, to determine the origin, biology and potential pathways for targeted anticancer therapy
Current Achievements and Applications of Transcriptomics in Personalized Cancer Medicine
Over the last decades, transcriptome profiling emerged as one of the most powerful approaches in oncology, providing prognostic and predictive utility for cancer management. The development of novel technologies, such as revolutionary next-generation sequencing, enables the identification of cancer biomarkers, gene signatures, and their aberrant expression affecting oncogenesis, as well as the discovery of molecular targets for anticancer therapies. Transcriptomics contribute to a change in the holistic understanding of cancer, from histopathological and organic to molecular classifications, opening a more personalized perspective for tumor diagnostics and therapy. The further advancement on transcriptome profiling may allow standardization and cost reduction of its analysis, which will be the next step for transcriptomics to become a canon of contemporary cancer medicine
Current Achievements and Applications of Transcriptomics in Personalized Cancer Medicine
Over the last decades, transcriptome profiling emerged as one of the most powerful approaches in oncology, providing prognostic and predictive utility for cancer management. The development of novel technologies, such as revolutionary next-generation sequencing, enables the identification of cancer biomarkers, gene signatures, and their aberrant expression affecting oncogenesis, as well as the discovery of molecular targets for anticancer therapies. Transcriptomics contribute to a change in the holistic understanding of cancer, from histopathological and organic to molecular classifications, opening a more personalized perspective for tumor diagnostics and therapy. The further advancement on transcriptome profiling may allow standardization and cost reduction of its analysis, which will be the next step for transcriptomics to become a canon of contemporary cancer medicine
Table1_Detection of BRCA1/2 pathogenic variants in patients with breast and/or ovarian cancer and their families. Analysis of 3,458 cases from Lower Silesia (Poland) according to the diagnostic algorithm of the National Cancer Control Programme.DOCX
Breast and ovarian cancers are among the most common malignancies in the female population, with approximately 5â10% of cases being hereditary. BRCA1 and BRCA2 with other homologous recombination genes are the most tested genes in hereditary breast and ovarian cancer (HBOC) patients. As next-generation sequencing (NGS) has become a standard and popular technique, such as for HBOC, it has greatly simplified and accelerated molecular diagnosis of cancer. The study group included 3,458 HBOC patients or their relatives from Lower Silesia (Poland) (a voivodeship located in south-west Poland inhabited by 2.9 million people). All patients were tested according to the recommendations from the National Cancer Control Programme of the Ministry of Health for the years 2018â21. We tested 3,400 patients for recurrent pathogenic variants for the Polish population: five BRCA1 founder variants (c.5266dup, c.181T>G, c.4035del, c.3700_3704del, and c.68_69del), two PALB2 variants (c.509_510del, c.172_175del) and three CHEK2 variants [c.1100del, c.444+1G>A, g.27417113-27422508del (del5395)]. Next 260 patients from the study group were chosen for the BRCA1/2 NGS panel, and additionally selected marker pathogenic variants were tested using Sanger sequencing and MLPA methods in 45 and 13 individuals, respectively. The analysis of BRCA1/2 in the 3,458 patients with HBOC or their relatives revealed 144 carriers of 37 different pathogenic variants (22 in BRCA1 and 15 in BRCA2). Among all detected variants, 71.53% constituted founder pathogenic BRCA1 variants. Our study has revealed that for the Lower Silesian population, the first-line BRCA1/2 molecular test may be limited to only three variants in BRCA1âc.5266dup, c.181T>G, and c.4035delâbut the aim should be to provide a full screening test of HBOC critical genes. The key and still growing role of molecular diagnostics of neoplasms, which includes HBOC, is undeniable. Therefore, it is necessary to provide complete and optimal therapeutic and prophylactic algorithms in line with current medical knowledge.</p
Destabilization of mutated human PUS3 protein causes intellectual disability
Pseudouridine (Κ) is an RNA base modification ubiquitously found in many types of RNAs. In humans, the isomerization of uridine is catalyzed by different stand-alone pseudouridine synthases (PUS). Genomic mutations in the human pseudouridine synthase 3 gene (PUS3) have been identified in patients with neurodevelopmental disorders. However, the underlying molecular mechanisms that cause the disease phenotypes remain elusive. Here, we utilize exome sequencing to identify genomic variants that lead to a homozygous amino acid substitution (p.[(Tyr71Cys)];[(Tyr71Cys)]) in human PUS3 of two affected individuals and a compound heterozygous substitution (p.[(Tyr71Cys)];[(Ile299Thr)]) in a third patient. We obtain wild-type and mutated full-length human recombinant PUS3 proteins and characterize the enzymatic activity in vitro. Unexpectedly, we find that the p.Tyr71Cys substitution neither affect tRNA binding nor pseudouridylation activity in vitro, but strongly impair the thermostability profile of PUS3, while the p.Ile299Thr mutation causes protein aggregation. Concomitantly, we observe that the PUS3 protein levels as well as the level of PUS3-dependent Κ levels are strongly reduced in fibroblasts derived from all three patients. In summary, our results directly illustrate the link between the identified PUS3 variants and reduced Κ levels in the patient cells, providing a molecular explanation for the observed clinical phenotypes
Polymorphisms in methyl-group metabolism genes and risk of sporadic colorectal cancer with relation to the CpG island methylator phenotype .
The CpG island methylator phenotype (CIMP), together with extensive promoter methylation, is regarded as one of the mechanisms involved in colorectal carcinogenesis (CRC). The mechanisms underlying the presence of CIMP in sporadic colorectal cancer are poorly understood. Genes involved in methyl-group metabolism are likely to affect DNA methylation and thereby influence an individual's susceptibility to CIMP. To test this hypothesis, we examined the potential association between the polymorphisms of MTHFR 677C>T, TS 5âUTR 2R/3RG>C, TS 3âUTR 1494del6, MTHFD1 401G>A, DNMT3B -149C>T and DNMT3B -283T>C and the presence of CIMP in a group of 186 sporadic CRC cases and 100 controls. The CIMP status of the tumors was determined by a panel of five markers (CACNA1G, IGF2, NEUROG1, RUNX3 and SOCS1), which was also followed by analysing hMLH1 methylation and BRAF V600E mutation. Individuals with TS 3R/3R had an increased risk of CIMP- colorectal cancer (OR = 2.38, 95% CI = 1.0-5.7; P = 0.042, Fisher's exact test) when compared with 2R/2R homozygotes. Individuals with DNMT3B -283 CC reduced risk of CIMP+ colorectal cancer (OR = 0.220, 95% CI = 0.0226-1.07; P = 0.046, Fisher's exact test) when compared to -283 TT carriers. This study provides some support to the hypothesis that methyl-group metabolism plays a role in the etiology of both CIMP+ and CIMP - colorectal cancers
Protein tyrosine phosphatase receptor-like genes are frequently hypermethylated in sporadic colorectal cancer
Introduction: The activity of phosphatases could be influenced by genetic, as well as epigenetic alterations. In our study we have investigated the methylation status of four PTPRs: PTPRM, PTPRT, PTPRR and PTPRZ1, which were pre-selected using microarray techniques as being alternatively methylated in sporadic colorectal cancer.
Materials and methods: The analyses were carried out on 131 surgical specimens obtained from sporadic colorectal cancer patients. The methylation status of the four genes was examined using MSP.
Results: The analysis of promoter methylation using an Illumina 27K microarray revealed four protein tyrosine phosphatases PTPRM, PTPRT, PTPRR and PTPRZ1 as being hypermethylated with beta-value â„ 0.2 and pâ€0.05. Subsequent analysis using MSP confirmed these observations - the frequency of promoter methylation was significantly higher in tumor cells compared to matched normal tissue for each of the analyzed genes. There was no association observed between the methylation status of PTPRs and either CIMP, K-ras (codon 12) and BRAF (exon 15, V600E) mutations or tumor localization (proximal/distal).
The results of our study show a statistically significant difference between promoter methylation in cancerous and healthy tissue. This result supports the hypothesis that the PTPR family plays an important role in the etiology of colorectal cancer
The C/A polymorphism in intron 11 of the XPC gene plays a crucial role in the modulation of an individualâs susceptibility to sporadic colorectal cancer
Background: Epidemiological data show that colorectal cancer (CRC) is the second
most frequent malignancy worldwide. The involvement of âminor impact genesâ such as
XME and DNA-repair genes in the etiology of sporadic cancer has been postulated by other authors.
Aim: we focused on analyzing polymorphisms in DNA-repair genes in CRC. We
considered the following genes involved in DNA-repair pathways: base excision repair
(OGG1 Ser326Cys, XRCC1 Trp194Arg and Arg399Gln); nucleotide excision repair [XPA (- 4)G/A, XPC C/A (i11) and A33512C (Lys939Gln), XPD Asp312Asn and A18911C
(Lys751Gln), XPF Arg415Gln, XPG Asp1104His, ERCC1 C118T]; homologous
recombination repair [ NBS1 Glu185Gln, Rad51 135G/C, XRCC3 C18067 (Thr241Met)].
Material and methods: The study group consisted of 133 patients diagnosed with
sporadic CRC, while the control group was composed of 100 age-matched non-cancer
volunteers. Genotyping was performed by PCR and PCR-RFLP. Fisherâs exact test with a
Bonferroni correction for multiple testing was used.
Results: We found that: i) XPC C/A (i11) heterozygous variant is associated with
increased risk of CRC [OR is 2.07 (95% CI 1.1391,3.7782) p=0.038], ii) XPD A18911C
(Lys751Gln) is associated with decreased risk of CRC [OR=0.4497, (95% CI 0.2215,0,9131) p=0.031] for an individual with at least one A allele at this locus.
Conclusions: 1. the XPC C/A (i11) genotype is associated with an increased risk of sporadic colorectal cancer.
2. the NER pathway has been highlighted in our study, as a most important in modulation of individual susceptibility to sCRC