A novel mutation of the SLC25A13 gene in a Chinese patient with citrin deficiency detected by target next-generation sequencing

Type II citrullinaemia, also known as citrin deficiency, is an autosomal recessive metabolic disorder, which is caused by pathogenic mutations in the SLC25A13 gene on chromosome 7q21.3. One of the clinical manifestations of type II citrullinaemia is neonatal intrahepatic cholestatic hepatitis caused by citrin deficiency (NICCD, OMIM# 605814). In this study, a 5-month-old female Chinese neonate diagnosed with type II citrullinaemia was examined. The diagnosis was based on biochemical and clinical findings, including organic acid profiling using a gas chromatography mass spectrometry (GC/MS), and the patient's parents were unaffected. Approximately 14 kb of the exon sequences of the SLC25A13 and two relative genes (ASS1 and FAH) from the proband and 100 case-unrelated controls were captured by array-based capture method followed by high-throughput next-generation sequencing. Two single-nucleotide mutations were detected in the proband, including the previous reported c.1177+1G>A mutation and a novel c.754G>A mutation in the SLC25A13 gene. Sanger sequence results showed that the patient was a compound heterozygote for the two mutations. The novel mutation (c.754G>A), which is predicted to affect the normal structure and function of citrin, is a candidate pathogenic mutation. Target sequence capture combined with high-throughput next-generation sequencing technologies is proven to be an effective method for molecular genetic testing of type II citrullinaemia.     

Deletion mutations in Duchenne muscular dystrophy (DMD) in Western Saudi children

Duchenne and Becker muscular dystrophy (DMD and BMD) are caused, in the majority of cases, by deletions in the dystrophin gene (DMD). The disease is an X-linked neuromuscular diseases typically caused by disrupting (DMD) or non-disrupting (BMD) the reading frame in the dystrophin (DMD) gene. In the present study, amplifications of the genomic DNAs of unrelated 15 Saudi DMD males were carried out using multiplex polymerase chain reaction (PCR) for nine-hotspot regions of exons 4, 8, 12, 17, 19, 44, 45, 48 and 51. We detected six Saudi patients having deletions in a frequency of 40%. The frequency of deletions in exon 51 (20%) was the most common deletion frequently associated with our Saudi sample males. Exons 19, 45, and 48 were present in a frequency of 6.7% each. All deletions were recognized as an individual exonic deletions, while no gross deletion where detected. Finally, the molecular deletions in the Saudi males was expected to be characterized by a moderate frequency among different populations due to the geographical KSA region, which it is in the crossroad of intense migrations and admixture of people coming from continental Asia, Africa, and even Europe. In conclusion, attempts to include an extra DNA samples might reflect a valid vision of the deletions within the high frequency deletion regions (HFDR’s) in the DMD gene mutations in KSA.     

Strategy for comprehensive molecular testing for Duchenne and Becker muscular dystrophies

Comprehensive molecular testing for mutations in the DMD gene causing Duchenne and Becker muscular dystrophy (DMD/BMD) is challenging because of the large size of the gene and the variety of mutation types. There is an increasing demand for comprehensive DMD gene molecular testing, including deletion/duplication testing of 79 exons and direct sequencing of the 14-kb coding region from genomic DNA, to provide confirmation of clinical diagnoses in affected patients and to determine carrier risk for family members. To determine an efficient strategy to prioritize patients for comprehensive molecular testing of the DMD gene, we tested a consecutive cohort of 165 males referred over a 4-year period because of a suspicion of DMD or BMD using: (1) a new quantitative multiplex polymerase chain reaction (PCR) assay designed to detect deletions or duplications in all exons of the gene and the brain promoter and (2) direct sequencing of the coding region and intron/exon boundaries. For the patients being tested because of a suspicion of DMD, deletion/duplication testing followed by direct sequencing detected pathogenic mutations in 98% (106/108 total patients). However, of the patients tested because of a suspicion of BMD, only 60% (34/57 total patients) had causative mutations identified, all of which were deletions or duplications. Our results suggest that direct genomic sequence analysis of the DMD gene is a useful addition to deletion/duplication testing for diagnosis of DMD, but does not provide an improved sensitivity compared to deletion/duplication analysis alone for the diagnosis of BMD. In addition, due to the relatively common finding of single exon deletions and duplications (22%, 27 of 125 total patients with deletions/duplications), methods to examine all exons of the gene for deletions/duplications should be used as the initial molecular quantitative test for DMD and BMD.     

Identification of sequence variants in genetic disease-causing genes using targeted next-generation sequencing

Background

Identification of gene variants plays an important role in research on and diagnosis of genetic diseases. A combination of enrichment of targeted genes and next-generation sequencing (targeted DNA-HiSeq) results in both high efficiency and low cost for targeted sequencing of genes of interest.

Methodology/Principal Findings

To identify mutations associated with genetic diseases, we designed an array-based gene chip to capture all of the exons of 193 genes involved in 103 genetic diseases. To evaluate this technology, we selected 7 samples from seven patients with six different genetic diseases resulting from six disease-causing genes and 100 samples from normal human adults as controls. The data obtained showed that on average, 99.14% of 3,382 exons with more than 30-fold coverage were successfully detected using Targeted DNA-HiSeq technology, and we found six known variants in four disease-causing genes and two novel mutations in two other disease-causing genes (the STS gene for XLI and the FBN1 gene for MFS) as well as one exon deletion mutation in the DMD gene. These results were confirmed in their entirety using either the Sanger sequencing method or real-time PCR.

Conclusions/Significance

Targeted DNA-HiSeq combines next-generation sequencing with the capture of sequences from a relevant subset of high-interest genes. This method was tested by capturing sequences from a DNA library through hybridization to oligonucleotide probes specific for genetic disorder-related genes and was found to show high selectivity, improve the detection of mutations, enabling the discovery of novel variants, and provide additional indel data. Thus, targeted DNA-HiSeq can be used to analyze the gene variant profiles of monogenic diseases with high sensitivity, fidelity, throughput and speed.     

Analysis of a dystrophin gene deletion by amplification of mRNA isolated from DMD myotubes cultured in vitro

The most frequent causes for the X-linked muscular dystrophy of the allelic Duchenne (DMD) or Becker (BMD) type are partial deletions of the dystrophin gene. These mutations are accompanied either by disrupted or by preserved translational reading frames in mRNAs derived from the deleted genes. As a rule, the reading frame is destroyed in the more severe DMD, whereas it is preserved in the less severe BMD (M. Koenig et al., 1989, Am. J. Hum. Genet. 45, 498-506). We have analyzed in detail a deletion that was detected in a fetus at risk of DMD. The analysis of this mutation included the delineation of the altered subregion in the dystrophin mRNA. mRNA was isolated from myotubes derived from embryonic DMD myoblasts propagated in vitro. This study was based on enzymatic amplification by the polymerase chain reaction (PCR) of dystrophin mRNA and direct sequencing of the amplified cDNA. Exons 47 to 50 were found to be missing in the mRNA. The splicing of exon 46 to exon 51 resulted in a reading frameshift, indicating that this mutation is likely to be responsible for a DMD type of dystrophy. The clinical diagnosis of DMD for a 10-year-old patient in this family was compatible with the "reading frame" assumption.     

A very small frame-shifting deletion within exon 19 of the Duchenne muscular dystrophy gene

We report the molecular characterization of a Japanese Duchenne muscular dystrophy (DMD) patient. The analysis of genomic gene by polymerase chain reaction indicates that the individuals have a limited deletion within an amplified region, which encompasses exon 19 of DMD gene. The amplified region was sequenced. Comparison of the deletion joint sequence with the normal amplified region sequence indicates that both 5' and 3' deletion end points are present within exon 19 and the deletion removes total 52 bp out of 88 bp of exon 19. Both his mother and sister are carriers of the deletion-containing allele. The mutation introduces a termination codon at residue 791 in exon 20, and is predicted to result in the production of a severely truncated protein. This sort of deletion (designated as DMD-Kobe) might be classified as a new type of DMD gene abnormality.     

Missense mutation G296S in GATA4 is not responsible for cardiac septal defects

BACKGROUND:

The most common type of congenital heart disease is the cardiac septal defects, which has reported to be caused by a missense mutation (G296S) in exon 3 of the GATA4 gene.

AIMS:

The present study was undertaken to find out whether GATA4 gene is the prime cause of the septal defects in Mysore population.

MATERIALS AND METHODS:

GATA4 gene analyses were undertaken on 21 confirmed CHD cases by PCR and DNA sequencing.

RESULTS AND CONCLUSION:

Analysis of this particular mutation in 21 septal defect patients revealed that none of the patients had the mutation, indicating that this mutation is population specific or septal defect in Mysore population is caused due to mutations in other regions of the GATA4 gene.     

Association of BMPR-1B and GDF9 genes polymorphisms and secondary protein structure changes with reproduction traits in Mehraban ewes

BMPR-1B and GDF9 genes are well known due to their important effects on litter size and mechanisms controlling ovulation rate in sheep. In the present study, polymorphisms of BMPR-1B gene exon 8 and GDF9 gene exon 1 were detected by single strand conformational polymorphism (SSCP) analysis and DNA sequencing methods in 100 Mehraban ewes. The PCR reaction forced to amplify 140 and 380-bp fragments of BMPR-1B and GDF9 genes, respectively. Two single nucleotide polymorphisms (SNP_S) were identified in two different SSCP patterns of BMPR-1B gene (CC and CA genotypes) that deduced one amino acid exchange. Also, two SNP_S were identified in three different SSCP patterns of GDF9 gene (AA, AG and GG genotypes) that deduced one amino acid exchanges. Two different secondary structures of protein were predicted for BMPR-1B exon 8, but the secondary protein structures predicted for GDF9 exon 1 were similar together. The evaluation of the associations between the SSCP patterns and the protein structure changes with reproduction traits showed that BMPR-1B exon 8 genotypes have significant effects on some of reproduction traits but the GDF9 genotypes did not have any significant effect. The CA genotype of BMPR-1B exon 8 had a significant positive effect on reproduction performance and could be considered as an important and new mutation, affecting the ewes reproduction performance. Marker assisted selection using BMPR-IB gene could be noticed to improve the reproduction traits in Mehraban sheep.     

Identification of one novel causative mutation in exon 4 of WFS1 gene in two Italian siblings with classical DIDMOAD syndrome phenotype

The aim of the present paper is to describe a novel missense mutation (G107R) of WFS1 gene that was unexpectedly detected, in two siblings from Southern Italy, outside exon 8; a very unusual finding which has previously been reported only twice in Italian patients with Wolfram syndrome (WS). Although in Spanish pedigrees' WFS1 mutations are frequently located in exon 4, this finding is very infrequent in other pedigrees, particularly in Italian patients. Conclusions: a) our report of two siblings with one novel WSF1 mutation (G107R) expands the molecular spectrum of WS; b) this is the 3rd report of Italian patients harbouring one mutation outside exon 8 and the 2nd with one mutation in exon 4; c) on the basis of the present observations, and literature data we can infer that mutation locations outside exon 8 do not seem to be clearly associated with peculiar phenotype expressions of WFS1 gene.     

Genetic and molecular analysis of the CLDN14 gene in Moroccan family with non-syndromic hearing loss

BACKGROUND:

Hearing loss is the most prevalent human genetic sensorineural defect. Mutations in the CLDN14 gene, encoding the tight junction claudin 14 protein expressed in the inner ear, have been shown to cause non-syndromic recessive hearing loss DFNB29.

AIM:

We describe a Moroccan SF7 family with non-syndromic hearing loss. We performed linkage analysis in this family and sequencing to identify the mutation causing deafness.

MATERIALS AND METHODS:

Genetic linkage analysis, suggested the involvement of CLDN14 and KCNE1 gene in deafness in this family. Mutation screening was performed using direct sequencing of the CLDN14 and KCNE1 coding exon gene.

RESULTS:

Our results show the presence of c.11C>T mutation in the CLDN14 gene. Transmission analysis of this mutation in the family showed that the three affected individuals are homozygous, whereas parents and three healthy individuals are heterozygous. This mutation induces a substitution of threonine to methionine at position 4.

CONCLUSION:

These data show that CLDN14 gene can be i mplicated in the development of hearing loss in SF7 family; however, the pathogenicity of c.11C>T mutation remains to be determined.     

Characterization of seven novel mutations on the HEXB gene in French Sandhoff patients

Sandhoff disease (SD) is an autosomal recessive lysosomal storage disease caused by mutations in the HEXB gene encoding the beta subunit of hexosaminidases A and B, two enzymes involved in GM2 ganglioside degradation. Eleven French Sandhoff patients with infantile or juvenile forms of the disease were completely characterized using sequencing of the HEXB gene. A specific procedure was developed to facilitate the detection of the common 5′-end 16 kb deletion which was frequent (36% of the alleles) in our study. Eleven other disease-causing mutations were found, among which four have previously been reported (c.850C>T, c.793T>G, c.115del and c.800_817del). Seven mutations were completely novel and were analyzed using molecular modelling. Two deletions (c.176del and c.1058_1060del), a duplication (c.1485_1487dup) and a nonsense mutation (c.552T>G) were predicted to strongly alter the enzyme spatial organization. The splice mutation c.558+5G>A affecting the intron 4 consensus splice site led to a skipping of exon 4 and to a truncated protein (p.191X). Two missense mutations were found among the patients studied. The c.448A>C mutation was probably a severe mutation as it was present in association with the known c.793T>G in an infantile form of Sandhoff disease and as it significantly modified the N-terminal domain structure of the protein. The c.171G>C mutation resulting in a p.W57C amino acid substitution in the N-terminal region is probably less drastic than the other abnormalities as it was present in a juvenile patient in association with the c.176del. Finally, this study reports a rapid detection of the Sandhoff disease-causing alleles facilitating genetic counselling and prenatal diagnosis in at-risk families.     

Rapid identification of HEXA mutations in Tay-Sachs patients

Tay-Sachs disease (TSD) is a recessively inherited neurodegenerative disorder due to mutations in the HEXA gene resulting in a β-hexosaminidase A (Hex A) deficiency. The purpose of this study was to characterize the molecular abnormalities in patients with infantile or later-onset forms of the disease. The complete sequencing of the 14 exons and flanking regions of the HEXA gene was performed with a unique technical condition in 10 unrelated TSD patients. Eleven mutations were identified, including five splice mutations, one insertion, two deletions and three single-base substitutions. Four mutations were novel: two splice mutations (IVS8+5G > A, IVS2+4delAGTA), one missense mutation in exon 6 (c.621T > G (p.D207E)) and one small deletion (c.1211-1212delTG) in exon 11 resulting in a premature stop codon at residue 429. The c.621T > G missense mutation was found in a patient presenting an infantile form. Its putative role in the pathogenesis of TSD is suspected as residue 207 is highly conserved in human, mouse and rat. Moreover, structural modelling predicted changes likely to affect substrate binding and catalytic activity of the enzyme. The time-saving procedure reported here could be useful for the characterization of Tay-Sachs-causing mutations, in particular in non-Ashkenazi patients mainly exhibiting rare mutations.     

两个弥漫性掌跖角化病家系的病理特征与基因突变分析

为了明确两个弥漫性掌跖角化病家系的临床、病理特征、角蛋白9在局部组织中的表达情况及KRT9基因的突变, 对2名先证者的手掌皮肤进行组织病理学、免疫组织化学分析, 并用聚合酶链反应技术及直接测序分析的方法, 对家系中46名成员的KRT9基因进行突变分析。发现两名先证者的表皮都呈显著的角化过度, 颗粒层和棘层明显增厚, 真皮浅层有轻度的炎症细胞浸润, 上基底的棘层和颗粒层的角质形成细胞中都有特征性的空泡变性存在; 角蛋白9只在棘层和颗粒层的角质形成细胞中特异性表达; 两个家系患者分别存在KRT9基因的点突变N160S和L167S; 说明这两个家系都属于表皮松解性掌跖角化病家系, KRT9基因N160S和L167S突变分别导致这两个家系发病。     

kitl非编码区突变导致RNA剪切异常的小鼠

本文主要采用RT-RCR技术从kitl1-bao纯合子和正常C57BL/6(B6)小鼠总RNA中扩增出kitl基因片段,测序后与GenBank(登录号:NM.013598)序列比对,找到mRNA上突变部位。PCR扩增kitl基因组DNA上对应部位进一步测序验证。结果发现kitl1-bao突变纯合子kitl基因mRNA缺少第8号外显子。在基因组DNA上kitl基因第8号内含子第2个碱基由T转换为C,是引起mRNA剪接错误的原因     

EDNRB基因编码区点突变及多态性在浙江地区散发性先天性巨结肠症中的检测与分析

本实验应用聚合酶链反应-单链构象多态性(single strand confbrmation polymorphism analysis of polymerase chain reaction products,PCR-SSCP)和DNA直接测序技术,对75例浙江地区散发性先天性巨结肠病例EDNRB基因编码区的全部7个外显子,进行了点突变与单核苷酸多态性的检测与分析,探讨浙江地区先天性巨结肠患者EDNRB基因的突变特征,阐明EDNRB基因与散发性先天性巨结肠症发病之间可能存在的关系。结果有6例患者在第4外显子上检测到密码子277位点 CTG→CTA的置换,导致亮氨酸的同义突变(L277L),属于单核苷酸多态性,发生率为8％(6/75)。有 2例患者在第2外显子上检测到密码子185位点GTG→ATG的置换,导致缬氨酸到蛋氨酸的错义突变(V185M),此突变型未在国内外文献中报道过,认为是新的基因突变型,突变率2．7％(2/75)。研究结果表明,浙江地区先天性巨结肠群体可发生EDNRB基因的杂合性突变,提示EDNRB基因与先天性巨结肠症的发病存在一定程度的关联。     

人肝细胞癌中抑癌基因PTEN/MMAC1/TEP1的突变分析

PTEN／MMAC1／TEP1(PTEN)是新近分离到的抑癌基因,在多种肿瘤中存在突变。我们检测了34例人肝细胞癌中PTEN基因第5外显子和第8外显子的突变。采用聚合酶链方法以内含子引物扩增第5和第8外显子,继之以单链构象多态性和测序技术分析PTEN基因突变。有4例肝细胞癌SSCP显示异常条带并经测序证实存在突变。2例发生于第4内含子,突变位点相同;另两例发生于第8外显子,其中1例碱基颠换导致PTEN蛋白产物304位半胱氨酸突变为甘氨酸。     

苯丙氨酸羟化酶（PAH）基因外显子7及其两侧内含子的突变研究

为探讨中国苯丙酮尿症（PKU）人群中苯丙氨酸羟化酶（PAH）基因外显子7的突变特征,对147例PKU患儿的294个PAH基因外显子7以及两侧部分内含子序列,应用PCR－单链构象多态性（SSCP）分析及基因序列分析的方法进行了筛查和确定。共发现13种突变基因：G239D、R241C、R241fs、R243Q、G247S、G247V、R252Q、L255S、R261Q、M276K、E280G、P281L、Ivs7+2T>A,其中7 种突变基因在中国PKU人群首次发现：G239D 、R241fs 、G247S 、E280G、L255S、R261Q、P281L,前4种在国际上尚未见到报道,并已提交到国际PAH突变数据库（www.pahdb.mcgill.ca）。突变基因的总频率为30.61%（90 /294）。突变涉及了错义、缺失、移码和剪接位点4种突变类型。结果明确了PAH基因外显子7的突变种类和分布等特征,表明外显子7是中国人PAH基因突变的热点区域。 Abstract: To study mutation in exon 7 of the gene for the phenylalanine hydroxylase（PAH）, the mutations in exon 7 and flanking sequence of PAH gene were detected by means of SSCP analysis and DNA sequencing, in 147 unrelated Chinese children with phynelketonuria and their parents. Thirteen different mutations, including 11 missense, 1 deletion and 1 splice mutation, were revealed in 90/294 mutant alleles (30.61%). The prevalent mutations were R243Q (22.8%) and Ivs7nt2t->a (2.38%). Seven novel mutations were identified: G239D, R241fsdelG, G247S, E280G, L255S, R261Q, P281L. These new mutations have not been described in Chinese PKU population and the first 4 mutants have not been reported and thus been submitted to www.pahdb,mcgill.ca. The missense was the most common type. The deletion and frameshift mutations were detected for the first time in Chinese PKU population. This study showed the mutation characteristics and their distribution in exon 7 of PAH gene and proved that the exon 7 was the hot region of PAH gene mutation in Chinese PKU population .     

A new ATP7B gene mutation with severe condition in two unrelated Iranian families with Wilson disease

Wilson disease is associated with a defect in copper metabolism and caused by different mutations in ATP7B gene. The aim of this study was to determine mutation frequency of ATP7B exons 8 and 14 in Wilson disease patients from the south of Iran. The exons 8 and 14 of ATP7B gene were analyzed in 65 unrelated Wilson disease patients by Denaturing High Performance Liquid Chromatography, and samples with abnormal peak profile were selected for direct DNA sequencing. Seven out of 65 (10.8%) patients had mutations at exon 14, including c.3061-1G>A in four and c.3207C>A in three patients. In addition, four different mutations were identified at exon 8 of six patients (9.2%). Three of these mutations have been previously reported, including c.2304delC in two patients, c.2293G>A and 2304dupC each in one patient. Furthermore, a novel mutation, c.2335T>G (p.Trp779Gly), was identified in two unrelated patients. The patients with this novel mutation demonstrated severe neuropsychiatric condition. All together, 13 out of 65 (20%) patients had mutations within exons 8 and 14. We also identified a lower frequency of the most common mutations of exons 8 and 14 in the southern Iranian population.