Development and validation of a novel panel of 16 STR markers for simultaneous diagnosis of ß-thalassemia, aneuploidy screening, maternal cell contamination detection and fetal sample authenticity in PND and PGD/PGS cases.

Prenatal diagnosis (PND) may be complicated with sample mix-up; maternal cell contamination, non-paternity and allele drop out at different stages of diagnosis. Aneuploidy screening if combined with PND for a given single gene disorder, can help to detect any common aneuploidy as well as aiding sample authenticity and other probable complications which may arise during such procedures. This study was carried out to evaluate the effectiveness of a novel panel of STR markers combined as a multiplex PCR kit (HapScreen™ kit) for the detection of ß-thalassemia, aneuploidy screening, ruling in/out maternal cell contamination (MCC), and sample authenticity. The kit uses 7 STR markers linked to ß-globin gene (HBB) as well as using 9 markers for quantitative analysis of chromosomes 21, 18, 13, X and Y. Selection of the markers was to do linkage analysis with ß-globin gene, segregation analysis and to perform a preliminary aneuploidy screening of fetal samples respectively. These markers (linked to the ß-globin gene) were tested on more than 2185 samples and showed high heterozygosity values (68.4-91.4%). From 2185 fetal cases we found 3 cases of non-paternity, 5 cases of MCC, one case of sample mix-up and one case of trisomy 21 which otherwise may have end up to misdiagnosis. This kit was also successfully used on 231 blastomeres for 29 cases of pre-implantation genetic diagnosis (PGD) and screening (PGS). The markers used for simultaneous analysis of haplotype segregation and aneuploidy screening proved to be very valuable to confirm results obtained from direct mutation detection methods (i.e. ARMS, MLPA and sequencing) and aneuploidy screening.

Imatinib independent aberrant methylation of NOV/CCN3 in chronic myelogenous leukemia patients: a mechanism upstream of BCR-ABL1 function?

BACKGROUND: The NOV gene product, CCN3, has been reported in a diverse range of tumors to serve as a negative growth regulator, while acting as a tumor suppressor in Chronic Myelogenous Leukemia (CML). However, the precise mechanism of its silencing in CML is poorly understood. In the current study, we aimed to query if the gene regulation of CCN3 is mediated by the promoter methylation in the patients with CML. In addition, to clarify whether the epigenetic silencing is affected by BCR-ABL1 inhibition, we assessed the methylation status in the patients at different time intervals following the tyrosine kinase inhibition using imatinib therapy, as the first-line treatment for this type of leukemia. METHODS: To address this issue, we applied bisulfite-sequencing technique as a high-resolution method to study the regulatory segment of the CCN3 gene. The results were analyzed in newly diagnosed CML patients as well as following imatinib therapy. We also evaluated the correlation of CCN3 promoter methylation with BCR-ABL1 levels. RESULTS: Our findings revealed that the methylation occurs frequently in the promoter region of CML patients showing a significant increase of the methylated percentage at the CpG sites compared to normal individuals. Interestingly, this hypermethylation was indicated to be independent of BCR-ABL1 titers in both groups, which might suggest a mechanism beyond the BCR-ABL1 function. CONCLUSION: Despite suggesting that the CCN3 hypermethylation acts as a molecular mechanism independent of BCR-ABL1 function in CML patients, this scenario requires further validation by complementary experiments. In the case of acting upstream of BCR-ABL1 signaling, the methylation marker can provide early detection and a novel platform for targeted epigenetic modifiers for efficient treatment in imatinib resistant patients.

Revisiting a Complex Rearrangement Involving a 619 Base Pairs Deletion, 6 Nucleotide Insertion Followed by a A > G Substitution Causing ß°-Thalassemia.

One of the prevalent inherited blood disorders is thalassemia syndrome that characterized by reduction (ß+) or absence (ß0) of ß globin chain synthesis. The ß globin (HBB) gene map in the short arm of chromosome 11 and most of the mutations in this gene are single nucleotide substitutions, insertions or deletions of nucleotides. Nucleotide sequence analysis of a partially deleted ß-globin gene from an Iranian carrier of ß-thalassemia displayed a complex rearrangement involving a 619 base pairs (bp) deletion. This rearrangement had originally been named as the 619 bp deletion and later on as the 619 bp deletion with a 7 bp insertion. In our study, using by single chain sequencing, we have shown that the actual rearrangement involves a 619 bp deletion, a 6 bp insertion followed by a G > A substitution deleting the exon 3 of the ß-globin gene. This clarification has to be inserted into the relevant databases as some of them still site the original 619 bp deletion with wrong breakpoints.

Identification of six novel mutations in Iranian patients with maple syrup urine disease and their in silico analysis.

Maple syrup urine disease (MSUD) is a rare inborn error of branched-chain amino acid metabolism. The disease prevalence is higher in populations with elevated rate of consanguineous marriages such as Iran. Different types of disease causing mutations have been previously reported in BCKDHA, BCKDHB, DBT and DLD genes known to be responsible for MSUD phenotype. In this study, two sets of multiplex polymorphic STR (Short Tandem Repeat) markers linked to the above genes were used to aid in homozygosity mapping in order to find probable pathogenic change(s) in the studied families. The families who showed homozygote haplotype for the BCKDHA gene were subsequently sequenced. Our findings showed that exons 2, 4 and 6 contain most of the mutations which are novel. The changes include two single nucleotide deletion (i.e. c. 143delT and c.702delT), one gross deletion covering the whole exon four c.(375+1_376-1)_(8849+1_885-1), two splice site changes (c.1167+1G>T, c. 288+1G>A), and one point mutation (c.731G>A). Computational approaches were used to analyze these two novel mutations in terms of their impact on protein structure. Computational structural modeling indicated that these mutations might affect structural stability and multimeric assembly of branched-chain α-keto acid dehydrogenase complex (BCKDC).

Frequencies of Six (Five Novel) STR Markers Linked to TUSC3 (MRT7) or NSUN2 (MRT5) Genes Used for Homozygosity Mapping of Recessive Intellectual Disability.

BACKGROUND: Non-syndromic autosomal recessive intellectual disability (NS-ARID) is an extremely heterogeneous genetic disorder. Therefore, to investigate these genes, more research is required. One approach to investigate the NS-ARID loci is homozygosity mapping which requires appropriate STR markers within or flanking the gene/s of interest. In this research, we aimed to find novel STRs for two common NS-ARID genes (TUSC3 and NSUN2) and, in addition, to identify allele frequencies of those STR markers. METHODS: The study group included 119 unrelated healthy individuals. STR markers were investigated using the UCSC genome browser web site and SERV software. Genotyping was determined by multiplex PCR. Data were evaluated using Gene Mapper software. Allele frequencies and observed heterozygosity rates were calculated using PowerStatV12. Deviation from Hardy-Weinberg equilibrium and expected heterozygosity were assessed using the DNAView software. RESULTS: In total, 56 alleles were detected. According to our research, D8TUSC3SU8.3 and D5NSUN2SU0.5 were the most informative STR markers in MRT7 and MRT5 loci, respectively and showed a high percentage of heterozygosity in Iranian population. The observed range of allele frequencies was from 3.4% to 32.4% and 0.8% to 18.9% for MRT5 and MRT7 loci, respectively. Further, we have evaluated other statistical surveys of these STR markers and discovered that all of the six listed STRs were informative and five meet the Hardy-Weinberg equilibrium for the tester group. CONCLUSIONS: Finding novel STRs, with high allele heterozygosity, is one of the most significant current finding in the present study for the two common NSARID genes. The recognized heterozygosity of these markers make MRT flanking STR markers very efficient to be used in diagnostic medical genetics labs or homozygosity mapping on NS-ARID.

Molecular Characterization of KRAS, BRAF, and EGFR Genes in Cases with Prostatic Adenocarcinoma; Reporting Bioinformatics Description and Recurrent Mutations.

BACKGROUND: Prostate cancer is one of the most common cancers which develops by mutations and/or other genetic alterations in specific genes. Regarding the previous studies in literature predominant mutations take place in KRAS, BRAF, and EGFR genes in special types of cancers. In this research, we attempt to identify the prevalence and significant role of the possible mutations in EGFR exons 18-21, KRAS codon 12, 13, and 61, and BRAF codon 600 mutations in tumoral tissue specimens from patients with prostatic adenocarcinoma. Furthermore, in this research, it has been attempted to investigate the molecular characteristics of these genes in terms of bioinformatic aspects. METHODS: A total of 35 prostatic adenocarcinoma fresh tissue samples, enriched in neoplastic cells, were obtained from the Cancer Institute of Iran. The presence of mutations at codons 12, 13 and 61 of KRAS, codon 600 of BRAF and EGFR exons 18-21 were determined by direct Sanger sequencing. To evaluate the molecular features, structure, and post-translation modification of those genes, a bioinformatics survey was performed using the SWISS-MODEL (http://swissmodel.expasy.org) and NetPhos 2.0 (http://www.cbs.dtu.dk/services/NetPhos/) Server. Also, using bioinformatics software, the phylogeny tree of the mutations was drawn. RESULTS: Mutations of codons 12 and 13 of KRAS were found in 2 of the 35 prostatic adenocarcinomas. Two cases carried homozygous mutations on exon 2 in codon 12 (G12V) and codon 13 (G13D). Also, no mutation was detected at BRAF codon 600 and EGFR exons 18-21 in any of the samples. CONCLUSIONS: Based on the group of patients with prostate adenocarcinoma, our research shows that the mutations in codons 12 and 13 of KRAS are the most common in prostate carcinomas. Noting these results and the molecular pathway of this gene, there is a possible more perceptible role for this gene in the pathogenesis of prostatic carcinoma. However, according to our finding, as in previous studies, the role of BRAF and EGFR gene mutations in prostate adenocarcinoma are less than in the KRAS gene and, therefore, we assume that these common mutations of the KRAS gene can be used as an early determining marker for early diagnosis of prostate adenocarcinoma. In the future, due to the complexity of etiological parameters in prostate cancer development, the case specific tumor molecular identification and treatment for each affected subject are urgently needed.

Next generation sequencing in a family with autosomal recessive Kahrizi syndrome (OMIM 612713) reveals a homozygous frameshift mutation in SRD5A3.

As part of a large-scale, systematic effort to unravel the molecular causes of autosomal recessive mental retardation, we have previously described a novel syndrome consisting of mental retardation, coloboma, cataract and kyphosis (Kahrizi syndrome, OMIM 612713) and mapped the underlying gene to a 10.4-Mb interval near the centromere on chromosome 4. By combining array-based exon enrichment and next generation sequencing, we have now identified a homozygous frameshift mutation (c.203dupC; p.Phe69LeufsX2) in the gene for steroid 5α-reductase type 3 (SRD5A3) as the disease-causing change in this interval. Recent evidence indicates that this enzyme is required for the conversion of polyprenol to dolichol, a step that is essential for N-linked protein glycosylation. Independently, another group has recently observed SRD5A3 mutations in several families with a type 1 congenital disorder of glycosylation (CDG type Ix, OMIM 212067), mental retardation, cerebellar ataxia and eye disorders. Our results show that Kahrizi syndrome and this CDG Ix subtype are allelic disorders, and they illustrate the potential of next-generation sequencing strategies for the elucidation of single gene defects.