中国人Ⅱ型MPS家系IDS基因的一种新突变的鉴定

为了研究粘多糖贮积症Ⅱ型(MPSⅡ)患者发病的分子遗传学机制, 以便为今后的产前基因诊断等创造必要的前提条件, 文章先采用尿糖胺聚糖(GAGs)定性检测法对疑似MPSⅡ的先证者进行初诊, 然后采用PCR、PCR 产物直接测序法对先证者及其家系成员进行突变检测。在检出IDS基因c.876del2新突变后, 对随机采集的120例正常对照和其他非II型MPS患者包括MPSⅠ, Ⅳ, Ⅵ三型的病人共15例的IDS基因exon 6进行序列分析, 同时采用不同物种突变点序列的保守性分析法, 以及直接测定患儿及其家庭相关成员IDS酶活性的方法对该新突变进行致病性分析。结果显示: 先证者尿检呈强阳性(GAGs +++); 其IDS基因exon 6编码区内存在c.876-877 del TC新缺失突变, 为半合子突变, 而其母、其姐为杂合突变; 正常对照和其他非II型MPS患者的IDS基因exon 6的检测结果均未发现该突变; 不同物种氨基酸序列的同源性比对显示: c.876-877 del TC突变所在的位置即p.292-293的苯丙氨酸(F)谷氨酰胺(Q)高度保守; 酶活性测定的结果显示: 先证者的IDS酶活性仅为2.3 nmol/4 h/mL, 大大低于正常值, 而其父的为641.9 nmol/4 h/mL, 其母的血浆酶活性为95.8 nmol/ 4h/mL, 其姐的为103.2 nmol/4 h/mL。说明所发现的c.876-877 del TC缺失移码突变是一种新的病理性突变, 是该MPSⅡ患儿发病的根本内因。     

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。     

一例CYP11B基因突变导致11β-羟化酶缺乏症的诊疗和基因检测分析

先天性肾上腺皮质增生症(congenital adrenal hyperplasia,CAH)是一种常染色体隐性遗传病,在不同类型的CAH发病率中,11β-羟化酶缺乏症排第二位,该疾病的发生与人8号常染色体上CYP11B基因突变有关。本研究采集了1名14岁患者的外周血,通过提取基因组DNA,应用全外显子测序对其进行了基因检测,对疑似变异进行Sanger测序验证,并分析其特点。结果发现,患者CYP11B1基因第8外显子存在c.1226C>T纯合错义突变,导致其编码蛋白第409位丝氨酸突变为苯丙氨酸(p.Ser409Phe),从而影响血红素与酶的结合,最终导致CYP11B1酶活性丧失,引起一系列临床症状。这一突变目前尚未见国内外有相关报道。本研究丰富了CYP11B1基因变异谱,为进一步研究11β-羟化酶缺乏症的致病机制提供了临床资料和遗传资源。     

汉族马凡综合征(MFS)患者FBN1基因两种新发突变分析

为调查马凡综合征(Marfan syndrome, MFS)患者的原纤维蛋白-1(Fibrillin-1, FBN1)基因突变情况, 应用聚合酶链反应(PCR)和变性高效液相色谱法(Denaturing high-performance liquid chromatography, DHPLC)对MFS患者的FBN1基因进行突变筛查, 对DHPLC初筛异常的DNA片段进行测序分析。结果在两个MFS家系中发现FBN1基因两种新的突变: 一种为复合突变包含第55号外显子的缺失突变c.6862_6871delGGCTGTGTAG (p.Gly2288MetfsX109)、同义突变c.6861A>G和内含子的突变c.[6871+1_6871+11delGTAAGAGGATC; 6871+34dupCATCAGAAGTGACAGTGGACA]; 另一种为第20号外显子的错义突变c.2462G>A(p.Cys821Tyr)。研究表明, FBN1基因的缺失突变c.[6862_6871delGGCTGTGTAG; 6871+1_6871+11delGTAAGAGGATC] (p.Gly2288MetfsX109)和错义突变c.2462G>A(p.Cys821Tyr)可能分别是这两个家系患者的致病原因。     

成骨不全Ⅰ型家系的基因检测和COL1A2基因新突变的致病性鉴定

为了揭示成骨不全(Osteogenesis imperfecta,OI)Ⅰ型家系的分子遗传学发生机制,文章采用PCR-DNA直接测序法,对患儿COL1A1和COL1A2基因共103个外显子(E)进行突变检测。结果显示:患儿COL1A1基因未发现任何病理性突变,而在COL1A2基因E19内发现一新的杂合错义突变(p.G316C),该突变来自其父,而其母正常,其他表型正常的6位亲属也均未发现该突变;通过DHPLC(Denaturing high performance uid chromatography)筛检,发现患儿与其父均有异常双峰,而其母和所有正常对照均为正常单峰;通过ASA(Allele specific amplification)筛检,患儿与其父均有391 bp的特异扩增带,而其母和所有正常对照均未见特异扩增带;保守性分析结果显示,该突变位点所在甘氨酸在进化上具有高度保守性;SIFT和Poly Phen-2软件预测结果显示,新突变造成的结果是"有害的"和"很可能有害"。上述结果均说明COL1A2基因c.946GT/p.G316C新突变是导致OI-Ⅰ型的致病性突变,是引起患儿发病的真正内因。患儿父母若再次孕育,可在孕早期进行产前基因诊断或孕前期进行PGD(Preimplantation genetic diagnosis)予以防患。     

进行性骨化性纤维增殖不良症临床及基因突变分析

目的:研究一例具有超经典型临床特征的FOP患者,并对其ACVR1/ALK2基因进行分析。方法:根据患者的大踇趾畸形和进行性异位骨化等表现进行临床诊断,确诊为FOP。经患者及家属同意,采集患者、父母外周血,提取DNA,通过PCR扩增并直接测序测定ACVR1基因全部外显子序列,以此来确定突变位点。结果:患者具有超经典型FOP的临床表现:先天性大踇趾畸形,先天性双手拇指、食指远端关节僵直和进行性异位骨化,父母无FOP的相关临床表现。基因测序分析示该患者在ACVR1第七外显子发现存在c.1067G>A(p.G356D)杂合错义突变,而其父母无此杂合突变。结论:该患者在ACVR1的c.1067G>A(p.G356D)发生杂合错义突变,这有助于我们更好地理解认识中国FOP患者的临床表现和发病机制。     

一个Ⅰ型遗传性淋巴水肿中国家系的VEGFR3基因的新突变方式

通过对国人Ⅰ型遗传性淋巴水肿一家系分子遗传学检测,报告VEGFR-3基因新突变。首先在Ⅰ型遗传性淋巴水肿对该家系进行致病基因的连锁分析,然后用DNA直接测序方法进行基因突变分析。连锁分析和单倍体分析确定该家系致病基因位于5q35.3,与Ⅰ型遗传性淋巴水肿连锁。VEGFR-3基因突变分析发现了一个新的错义突变D1055V,该错义突变在家系中共分离,且在100个正常对照组中未发现该序列改变。本研究首次报告了国内Ⅰ型遗传性淋巴水肿VEGFR-3基因新的错义突变D1055V,丰富了VEGFR-3基因基因突变谱,为今后开展遗传性淋巴水肿的基因诊断和遗传咨询奠定基础。     

一个Ⅰ型遗传性淋巴水肿中国家系的VEGFR3基因的新突变方式

通过对国人Ⅰ型遗传性淋巴水肿一家系分子遗传学检测,报告VEGFR-3基因新突变.首先在Ⅰ型遗传性淋巴水肿对该家系进行致病基因的连锁分析,然后用DNA直接测序方法进行基因突变分析.连锁分析和单倍体分析确定该家系致病基因位于5q35.3,与Ⅰ型遗传性淋巴水肿连锁.VEGFR-3基因突变分析发现了一个新的错义突变D1055V.该错义突变在家系中共分离,且在100个正常对照组中未发现该序列改变.本研究首次报告了国内Ⅰ型遗传性淋巴水肿VEGFR-3基因新的错义突变D1055V,丰富了VEGFR-3基因基因突变谱,为今后开展遗传性淋巴水肿的基因诊断和遗传咨询奠定基础.     

进行性骨化性纤维増殖不良症临床及基因突变分析

目的：研究一例具有超经典型临床特征的FOP患者,并对其ACVR1/ALK2基因进行分析。方法：根据患者的大踇趾畸形和进行性异位骨化等表现进行临床诊断,确诊为FOP。经患者及家属同意,采集患者、父母外周血,提取DNA,通过PCR扩增并直接测序测定ACVR1基因全部外显子序列,以此来确定突变位点。结果：患者具有超经典型FOP的临床表现：先天性大踇趾畸形,先天性双手拇指、食指远端关节僵直和进行性异位骨化,父母无FOP的相关临床表现。基因测序分析示该患者在ACVR1第七外显子发现存在c.1067G〉A（p.G356D）杂合错义突变,而其父母无此杂合突变。结论：该患者在ACVR1的c.1067G〉A（p.G356D）发生杂合错义突变,这有助于我们更好地理解认识中国FOP患者的临床表现和发病机制。     

两例抗凝血蛋白缺乏患者的基因诊断

目的:探讨导致蛋白C、蛋白S、抗凝血酶缺乏症的分子发病机制。方法:检测蛋白C活性(PC:C)、蛋白S活性(PS:C)以及抗凝血酶活性(AT:C);PCR法分别扩增患者PC、PS、AT基因序列,寻找突变点。结果:蛋白C合并蛋白S合并抗凝血酶AT缺乏患者PC基因启动子区域存在C4867T杂合突变(NG_016323.1),为蛋白C基因的多态性位点;在蛋白S基因第四号外显子区域有G68395T杂合突变(NG_009813.1),导致Arg90Leu(NP_000304.2),为国际首次报道。遗传性PS缺陷在家系:四名家系成员均检测到PS基因第四号外显子区域一个杂合(错义)突变,G68395T(NG_009813.1)。结论:PC基因启动子的多态性位点C4867T杂合突变(NG_016323.1),PS基因第四号外显子区域的G68395T杂合突变(NG_009813.1),可能是导致患者PC、PS联合缺乏的原因。PS基因第四号外显子区域G68395T(NG_009813.1)杂合突变,可能是导致PS缺陷症家系成员PS缺乏的原因。     

Detection of a new mutation (T1140C) in a patient with Hunter syndrome from Guangdong,China

This study identified mutations of the idumate-2-suffatase (IDS) gene in a patient with Hunter syndrome,and established a basis for the diagnosis of the prenatal gene of Hunter syndrome.Urine glyeosaminoglycan (GAG) assay was used to make the preliminary diagnosis of mucopolysaccharidosis type H.Polymerase chain reaction (PCR) from dried blood spots and DNA sequencing were applied to analyze hotspot mutations in exons 9,3 and 8 of the IDS gene in the proband and his parents.A new missense mutation (T1140C) in exon 8 of the IDS gene was found by using DNA sequencing.This mutation caused a substitution of codon 339 from CTA (leucine) to CCA (praline).The patient is a hemizygote,and his mother is a heterozygote.The new missense mutation results in a change in the primary and tertiary structure of the IDS protein.It is possible that this mutation severely impairs enzymatic activity and is the underlying basis for the pathology seen in this patient with Hunter syndrome.     

Detection of a new mutation (T1140C) in a patient with Hunter syndrome from Guangdong, China

This study identified mutations of the idurnate-2-sulfatase (IDS) gene in a patient with Hunter syndrome, and established a basis for the diagnosis of the prenatal gene of Hunter syndrome. Urine glyeosaminoglycan (GAG) assay was used to make the preliminary diagnosis of mucopolysaccharidosis type II. Polymerase chain reaction (PCR) from dried blood spots and DNA sequencing were applied to analyze hotspot mutations in exons 9,3 and 8 of the IDS gene in the proband and his parents. A new missense mutation (T1140C) in exon 8 of the IDS gene was found by using DNA sequencing. This mutation caused a substitution of codon 339 from CTA (leucine) to CCA (praline). The patient is a hemizygote, and his mother is a heterozygote. The new missense mutation results in a change in the primary and tertiary structure of the IDS protein. It is possible that this mutation severely impairs enzymatic activity and is the underlying basis for the pathology seen in this patient with Hunter syndrome. __________ Translated from Hereditas, 2006, 28(5): 521–524 [译自: 遗传]     

Frequent deletions at Xq28 indicate genetic heterogeneity in Hunter syndrome

Summary Hunter syndrome is a human X-linked disorder caused by deficiency of the lysosomal exohydrolase iduronate-2-sulphatase (IDS). The consequent accumulation of the mucopolysaccharides dermatan sulphate and heparan sulphate, in the brain and other tissues, often results in death before adulthood. There is, however, a broad spectrum of severity that has been attributed to different mutations of the Hunter syndrome gene. We have used an IDS cDNA clone to localise the IDS gene to Xq28, distal to the fragile X mutation (FRAXA). One-third of Hunter syndrome patients had various deletions or rearrangements of their IDS gene, proving that different mutations are common in this condition. Deletions of the IDS gene can include a conserved locus that is tightly linked to FRAXA, suggesting that deletion of nearby genes may contribute to the variable clinical severity noted in Hunter syndrome. The cDNA clone was also shown to span the X chromosome breakpoint in a female Hunter syndrome patient with an X;autosome translocation.     

Mutational spectrum of the iduronate-2-sulfatase (IDS) gene in 36 unrelated Russian MPS II patients

We present a mutational analysis of the iduronate-2-sulfatase (IDS) gene of 36 Russian patients with Hunter syndrome. Among 29 mutant alleles, there were 19 missense mutations, 1 nonsense mutation, 6 mutations affecting splice sites, and 3 major structural alterations resulting in deletions. Of the 25 different mutations, 15 are novel and unique. Most of the missense mutations result in intermediate or severe phenotypes. Received: 1 June 1998 / Accepted: 27 July 1998     

Detection of point mutations and a gross deletion in six Hunter syndrome patients.

We have used screening with the polymerase chain reaction and chemical mismatch detection of amplified cDNA to detect and characterize deletions and point mutations in six Hunter Syndrome patients. A high degree of mutational heterogeneity was observed. The first patient is completely deleted for the gene coding for alpha-L-iduronate sulfate sulfatase, while the second has a point mutation that creates a stop codon. The third patient shows a point mutation that creates a novel splice site that is preferentially utilized and results in partial loss of one exon in the RNA. Patients 4, 5, and 6 have point mutations resulting in single amino acid substitutions. Four of the six single-base changes observed in this study were examples of transitions of the highly mutable dinucleotide CpG to TpG. This study has demonstrated a procedure capable of detecting all types of mutation that affect the function of the IDS protein and should enable direct carrier and prenatal diagnosis for Hunter syndrome families.     

Evidence for an iduronate-sulfatase pseudogene near the functional Hunter syndrome gene in Xq27.3-q28

We are currently characterizing mutations of the iduronate-2-sulfatase (IDS) gene in patients with Hunter syndrome (mucopolysaccharidosis type II). Surprisingly, all 17 patients with a mutation in exon III of the IDS gene identified by us were found to carry both the mutant and wild-type sequences in polymerase chain reaction (PCR) products amplified from genomic DNA. Similarly, two unaffected male controls showed a heterozygous pattern for two different point mutations in exon III. Collectively, the data suggest that at least intron 2, exon III, and the 3-half of exon II of the functional IDS gene are present in the human genome as (part of) a non-expressed IDS gene. Deletion mapping further suggests that the pseudogene is in distal Xq in physical proximity to the functional IDS gene. The high degree of sequence homology observed between the functional IDS gene and pseudogene results in permanent co-amplification in PCR-based screening methods and makes mutation analysis at the genomic DNA level difficult.     

A germ line mutation within the coding sequence for the putative 5-phosphoribosyl-1-pyrophosphate binding site of hypoxanthine-guanine phosphoribosyltransferase (HPRT) in a Lesch-Nyhan patient: missense mutations within a functionally important region probably cause disease

Lesch-Nyhan syndrome caused by a complete deficiency of hypoxanthine guanine phosphoribosyltransferase (HPRT) is the result of a heterogeneous group of germ line mutations. Identification of each mutant gene provides valuable information as to the type of mutation that occurs spontaneously. We report here a newly identified HPRT mutation in a Japanese patient with Lesch-Nyhan syndrome. This gene, designated HPRT Tokyo, had a single nucleotide change from G to A, as identified by sequencing cDNA amplified by the polymerase chain reaction. Allele specific oligonucleotide hybridization analysis using amplified genomic DNA showed that the mutant gene was transmitted from the maternal germ line. This mutation would lead to an amino acid substitution of Asp for Gly at the amino acid position 140 located within the putative 5-phosphoribosyl-1-pyrophosphate (PRPP) binding region. Missense mutations in human HPRT deficient patients thus far reported tend to accumulate in this functionally active region. However, a comparison of the data suggested that both missense and synonymous mutations can occur at any coding sequence of the human germ line HPRT gene, but that a limited percentage of all the missense mutations cause disease. The probability that a mutation will cause disease tends to be higher when the missense mutation is within a functionally important sequence.     

Expression studies of mutations underlying Taiwanese Hunter syndrome (mucopolysaccharidosis type II)

Nearly 300 different mutations underlying mucopolysaccharidosis type II (MPS II) have been identified worldwide. To investigate the molecular lesions underlying Taiwanese MPS II, probands and families were identified and screened for iduronate-2-sulfatase (IDS) mutation by single-strand conformation polymorphism and DNA sequencing. Five novel and five previously reported mutations were found. Together with those previously reported, a total of 17 identified missense, small deletion, and nonsense mutations were further characterized by transient expression studies. Transfection of COS-7 cells by the mutated cDNA did not yield active enzyme, demonstrating the deleterious nature of the mutations. A 57% decrease in IDS mRNA level was seen with the 231del6 mutation. Among the 11 missense mutations examined, K347E substitution showed apparent normal maturation and targeting on immunoblot and confocal fluorescence microscopy examination. The other 10 missense mutations showed apparent normal precursor with little or reduced mature forms, indicating normal maturation but incorrect targeting of the mutant enzymes. Among the six deletion and nonsense mutations examined, 1055del12 and E521X showed abnormal maturation. The staining pattern of the truncated W267X and 1184delG proteins suggested retention within early vacuolar compartments. The mutated 231del6 and 1421delAG proteins were unstable and largely degraded. Molecular analysis of the IDS gene will clearly identify the cause of the disease within patients and allow antenatal and family studies. The further characterization of gene mutations may delineate their functional consequences on IDS activity and processing and may enable future studies of genotype–phenotype correlation to estimate a prognosis and to lead to possible therapeutic interventions.Jui-Hung Chang and Shuan-Pei Lin contributed equally to this work