定位于1p36.12～1p35.1 的良性家族性婴儿惊厥家系 8 个候选基因的排除克隆*

目的:克隆定位于1p36.12～1p35.1上微卫星标志D1S2864和D1S2830之间12.4cM的区间内的腓骨肌萎缩症2L型的致病基因。方法:应用生物信息学方法筛选8个候选基因(NHE1、SMN、STX12、OX1R、BDR2、DHHC18、FLJ10315和SESN2),设计合成扩增8个基因外显子及外显子与内含子交界的引物,DNA直接测序法进行序列变异分析。结果:未发现与BFIS共分离的致病突变,但发现3个已知的多态。结论:排除了8个候选基因为该BFIS致病基因的可能。     

合作猪SLA-DQA基因外显子2多态性分析

旨在研究合作猪DQA基因外显子2多态性,确定其等位基因数、核苷酸多态位点、氨基酸多态位点及各个等位基因之间的遗传关系,分析其进化意义。选用PCR-SSCP对439只合作猪SLA-DQA基因外显子2的多态性进行检测;测序群体内因变异而产生的各等位基因序列,并分析序列数据。结果显示,在合作猪SLA-DQA外显子2中发现了7个新等位基因,共18个核苷酸多态位点,10个氨基酸多态位点。合作猪SLA-DQA外显子2具有较丰富的多态性,群体内可能蕴藏着更加丰富的遗传资源;合作猪SLA-DQA外显子2基因最初可能由一个等位基因突变分化成一大类基因;合作猪SLA-DQA外显子2序列与各个猪种的SLA-DQA外显子2序列具有较高的同源性,预示着这些猪种的SLA-DQA外显子2基因最早可能来源于其分歧之前的共同祖先原始序列;新发现的7个SLA-DQA外显子2等位基因,可能由遗传关系较近的两个等位基因突变产生。     

常染色体显性遗传非综合征性耳聋致病基因定位研究

耳聋具有高度的遗传异质性, 迄今已定位了51个常染色体显性遗传非综合征型耳聋(autosomal dominant non-syndromic sensorineural hearing loss, DFNA)基因位点, 20个DFNA相关基因被克隆。文章收集了一个DFNA巨大家系, 家系中有血缘关系的家族成员共170人, 对73名家族成员进行了详细的病史调查、全身检查和耳科学检查, 提示39人有不同程度的迟发性感音神经性听力下降, 未见前庭及其他系统的异常。应用ABI公司382个常染色体微卫星多态标记进行全基因组扫描连锁分析, 将该家系致聋基因定位于14q12-13处D14S1021-D14S70之间约7.6 cM (3.18 Mb)的区域, 最大LOD值为6.69 (D14S1040), 与已知DFNA9位点有4.7 cM (2.57 Mb)的重叠区, DFNA9致病基因COCH位于重叠区域内。下一步拟进行COCH基因的突变筛查, 以揭示该家系耳聋的分子致病机制。     

常染色体显性遗传非综合征型耳聋致病基因定位研究

耳聋具有高度的遗传异质性, 迄今已定位了51个常染色体显性遗传非综合征型耳聋(autosomal dominant non-syndromic sensorineural hearing loss, DFNA)基因位点, 20个DFNA相关基因被克隆.文章收集了一个DFNA巨大家系, 家系中有血缘关系的家族成员共170人, 对73名家族成员进行了详细的病史调查、全身检查和耳科学检查, 提示39人有不同程度的迟发性感音神经性听力下降, 未见前庭及其他系统的异常.应用ABI公司382个常染色体微卫星多态标记进行全基因组扫描连锁分析, 将该家系致聋基因定位于14q12-13处D14S1021-D14S70之间约7.6 cM (3.18 Mb)的区域, 最大LOD值为6.69 (D14S1040), 与已知DFNA9位点有4.7 cM (2.57 Mb)的重叠区, DFNA9致病基因COCH位于重叠区域内.下一步拟进行COCH基因的突变筛查, 以揭示该家系耳聋的分子致病机制.     

混合DNA样品池扩增法及其应用

将个体 DNA提取出来后 ,按一定方式进行混合 ,构成混合 DNA样品池。这种混合 DNA样品可用于病因未明的遗传性及遗传易感性疾病的研究。在研究常染色体隐性遗传性耳聋致病基因时 ,发现与染色体 9q的 D9S92 2和 D9S30 1位点有相关性。此方法比通常的连锁分析法省时省力。在肿瘤相关基因或责任基因的研究、法医学的个体认定、基因突变的检测等方面均显示出实用性 ,值得推广     

青藏高原5种害鼠D型肉毒素抗性相关基因VAMP1的序列分析

突触小泡相关膜蛋白1基因(VAMP1)的变异是导致鼠类对D型肉毒梭毒素灭鼠剂产生抗性的主要原因。本研究利用转录组测序的方法,分析青藏高原地区5种主要害鼠:高原鼠兔(Ochotona curzoniae)、高原鼢鼠(Eospalax baileyi)、长尾仓鼠(Cricetulus longicaudatus)、青海松田鼠(Neodon fuscus)和喜马拉雅旱獭(Marmota himalayana)的VAMP1序列信息。同时,分别采集来自5个地理种群的58只高原鼠兔和59只高原鼢鼠,对VAMP1基因第二外显子区序列进行分析。结果显示,从转录组组装文件中成功获得5种动物的VAMP1基因全序列,长度均为357 bp,共检测到46个核苷酸变异位点和4个氨基酸变异位点,但未发现与D型肉毒素抗性相关的氨基酸位点。对高原鼠兔群体和高原鼢鼠群体的VAMP1基因第二外显子序列的分析显示,高原鼠兔所有个体的序列高度保守,而在高原鼢鼠中则存在一个同义突变位点,但两物种在D型肉毒素抗性相关位点上都未监测出位点变异。该研究结果提示,D型肉毒杀鼠剂在青藏高原地区害鼠防治方面应该可以长期发挥重要作用。     

中国汉族群体5个STR分子遗传标记

为了解中国人5个STR基因座等位片段结构特征,获得汉族群体D2S2955、D3S4014、D20S604、D22S689和GATA198B05基因座的群体遗传学数据。采取成都地区无血缘关系汉族个体血样EDTA抗凝血。Chelex法提取DNA,PCR扩增,非变性聚丙烯酰胺凝胶不连续缓冲系统水平电泳分型,自动激光荧光测序仪测定DNA序列。序列分析显示,中国人D2S2955、D3S4014、D20S604基因座具有简单重复序列,而D22S689、GATA198B05基因座具有复杂重复序列。5个STR基因座在成都汉族群体中均具有遗传多态性。揭示了我国汉族人群5个STR基因座的等位基因片段结构特征,为人类群体遗传研究提供了数据,建立的不连续缓冲系统水平电泳分型方法为检测这5个STR基因座提供了简便技术。     

LITAF、RAB7、LMNA和MTMR2基因在中国人腓骨肌萎缩症患者的突变分析

为了分析LITAF、RAB7、LMNA和MTMR2基因在中国人腓骨肌萎缩症(Charcot-Marie-Tooth disease, CMT)的突变特点, 文章分别应用PCR结合DNA序列分析方法和PCR-单链构象多态性(PCR-SSCP)结合DNA序列分析方法对6个常染色体显性遗传家系先证者和27个散发病例进行LITAF和RAB7基因突变分析; 应用PCR-SSCP结合DNA序列分析方法对14个常染色体遗传的CMT家系先证者和27个散发患者进行LMNA和MTMR2基因突变分析。结果发现: LITAF基因c.269G→A、c.274A→G序列变异和LMNA基因c.1243G→A、c.1910C→T序列变异, 未发现RAB7和MTMR2基因的序列变异。其中LITAF基因c.269G→A、LMNA基因c.1243G→A和c.1910C→T为新发现的单核苷酸多态; LITAF基因c.274A→G为已知多态。说明LITAF、RAB7、LMNA和MTMR2基因突变在中国人CMT患者中罕见。     

高通量测序技术在遗传性耳聋研究中的应用及研究进展

耳聋是一种常见的严重出生缺陷,阐明遗传性耳聋的致病机理不仅能够在临床上辅助诊断,为遗传咨询及耳聋预防提供依据,而且能促进人们更深入地了解耳聋的致病机制,开发新的治疗方法。随着基因组研究技术不断创新,以全基因组测序、全外显子组测序、目标区域测序为代表的高通量测序技术在遗传性耳聋研究中已得到广泛应用。本文总结了近5年全外显子组测序和目标区域测序在遗传性耳聋致病基因研究及临床分子诊断中应用及研究进展,希望能够有助于我国临床耳聋基因诊断技术的发展及诊断水平的提升。     

近亲结婚所致一遗传性非综合征型耳聋家系的调查

耳聋是一种最常见的人类感觉系统缺陷, 在已发现的遗传性耳聋中,有70％的属于非综合征型听力缺损。据估计非综合征型遗传性耳聋基因总数在100个以上,目前已经确定了近80个非综合征型遗传性耳聋的遗传位点,其中23个基因已经被成功克隆。文章报道一遗传性非综合征型耳聋家系。该家系中存在2代近亲结婚,共2代13人出现聋哑症状。经遗传分析,该家系的遗传方式与常染色体显性或隐性遗传均不符合,提示此家系中的非综合征型遗传性耳聋可能为线粒体突变所致。     

A gene for fluctuating, progressive autosomal dominant nonsyndromic hearing loss, DFNA16, maps to chromosome 2q23-24.3.

The sixteenth gene to cause autosomal dominant nonsyndromic hearing loss (ADNSHL), DFNA16, maps to chromosome 2q23-24.3 and is tightly linked to markers in the D2S2380-D2S335 interval. DFNA16 is unique in that it results in the only form of ADNSHL in which the phenotype includes rapidly progressing and fluctuating hearing loss that appears to respond to steroid therapy. This observation suggests that it may be possible to stabilize hearing through medical intervention, once the biophysiology of deafness due to DFNA16 is clarified. Especially intriguing is the localization of several voltage-gated sodium-channel genes to the DFNA16 interval. These cationic channels are excellent positional and functional DFNA16 candidate genes.     

Genomic structures of SCN2A and SCN3A - candidate genes for deafness at the DFNA16 locus

DFNA16 is a form of autosomal dominant non-syndromic hearing loss (ADNSHL) characterized by fluctuating progressive hearing impairment. Earlier, we mapped the deafness-causing gene to chromosome 2q23-24.3. In this paper, we describe fine mapping results using additional markers tightly linked to the DFNA16 candidate region. Critical recombinants at markers D2S354 and D2S124 define a 3.5-cM interval that contains the DFNA16 gene. Positional candidate genes include two members of the voltage-gated sodium channel family, the type 2 alpha subunit (SCN2A) and the type 3 alpha subunit (SCN3A). After showing that SCN2A is expressed in human fetal cochlea, we determined its genomic structure to facilitate mutation screening in our DFNA16 kindred. We also determined the genomic structure of SCN3A. These two genes are oriented head-to-head, with their 5' ends separated by approximately 40 kb; their homology is 82% at the nucleotide level, and 85% for identities and 90% for positives at the amino acid level. They share similar genomic structures and have alternative splice isoforms that are developmentally regulated and highly conserved between species. Although no DFNA16-causing mutations were found in either gene, haplotype analysis with polymorphic markers in SCN2A introns further narrowed the candidate gene interval to the region flanked by D2S354 and STS SHGC-82894.     

A gene for autosomal dominant nonsyndromic hearing loss (DFNA12) maps to chromosome 11q22-24.

We performed linkage analysis in a Belgian family with autosomal dominant midfrequency hearing loss, which has a prelingual onset and a nonprogressive course in most patients. We found LOD scores >6 with markers on chromosome 11q. Analysis of key recombinants maps this deafness gene (DFNA12) to a 36-cM interval on chromosome 11q22-24, between markers D11S4120 and D11S912. The critical regions for the recessive deafness locus DFNB2 and the dominant locus DFNA11, which were previously localized to the long arm of chromosome 11, do not overlap with the candidate interval of DFNA12.     

Complex repetitive arrangements of gene sequence in the candidate region of the spinal muscular atrophy gene in 5q13.

Childhood-onset proximal spinal muscular atrophy (SMA) is a heritable neurological disorder, which has been mapped by genetic linkage analysis to chromosome 5q13, in the interval between markers D5S435 and D5S557. Here, we present gene sequences that have been isolated from this interval, several of which show sequence homologies to exons of beta-glucuronidase. These gene sequences are repeated several times across the candidate region and are also present on chromosome 5p. The arrangement of these repetitive gene motifs is polymorphic between individuals. The high degree of variability observed may have some influence on the expression of the genes in the region. Since SMA is not inherited as a classical autosomal recessive disease, novel genomic rearrangements arising from aberrant recombination events between the complex repeats may be associated with the phenotype observed.     

A novel autosomal dominant non-syndromic deafness locus (DFNA48) maps to 12q13-q14 in a large Italian family

Non-syndromic hearing loss is the most common sensory disorder in humans; 15%-20% of cases are transmitted as a dominant trait (NSDA) with 40 loci having been mapped and 16 genes having been identified. Here, we report the mapping of a novel NSDA locus, DFNA48, to chromosome 12q13-q14 in a large multigenerational Italian family. A maximum lod score of 3.31 was obtained with marker D12S83, whereas markers D12S347 and D12S1703 defined a region of approximately 18 cM. Positional candidate genes are being screened for deafness-causing mutations.     

A new locus for late-onset, progressive, hereditary hearing loss DFNA20 maps to 17q25

We report the localization of DFNA20, a gene causing dominant, nonsyndromic, progressive hearing loss in a three-generation Midwestern family, to chromosome 17q25. Affected family members show a bilateral, sloping, progressive, sensorineural hearing loss, first evident at 6000 and 8000 Hz, that can be identified in some family members in the early teens and is clearly evident by the early twenties. As age increases, the degree of hearing loss increases with threshold shifts seen at all frequencies. Linkage to known hereditary hearing loss loci was excluded. A genome-wide screen detected positive linkage to D17S784 (LOD(Z) = 6.62; θ = 0). Haplotype analysis refines the DFNA20 critical region to 12 cM between D17S1806 and D17S668. Radiation hybrid mapping with Stanford G3 and TNG panels was used to evaluate the genes ACTG1, GRIN2C, FKHL13, P4HB, SPARC, and ARHGDIA as candidates for DFNA20.     

A new locus for hereditary gingival fibromatosis (GINGF2) maps to 5q13-q22

Gingival fibromatosis (GINGF) is an oral disorder characterized by enlargement of the gingiva. It occurs either as the sole phenotype or combined with other symptoms. Thus far, one GINGF locus has been mapped on chromosome 2, at 2p21, and a second possible locus has been mapped to 2p13. However, the genes responsible for this disorder have not been elucidated. We identified a four-generation Chinese GINGF family in which the disease manifests within 1 year after birth. After exclusion of the two known GINGF loci in this family, we performed a genome-wide search to map the chromosome location of the responsible gene. We identified a new locus, GINGF2, on chromosome 5q13-q22 with a maximum two-point lod score of 4.31 at D5S1721 (theta = 0.00). Haplotype analysis placed the critical region in the interval defined by D5S1491 and D5S1453. Within this region, calcium/calmodulin-dependent protein kinase IV (CAMK4) is a strong candidate.     

Physical mapping of the human ATX1 homologue (HAH1) to the critical region of the 5q- syndrome within 5q32, and immediately adjacent to the SPARC gene

The 5q- syndrome is a myelodysplastic syndrome with the 5q deletion as the sole karyotypic abnormality. The human ATX1 homologue (HAH1), encodes a copper-binding protein with a role in antioxidant defence. We have mapped this gene to the 3 Mb critical region of gene loss of the 5q- syndrome within 5q32, flanked by the genes for ADRB2 and IL12B, using gene dosage analysis. Fine physical mapping of the HAH1 gene within this genomic interval was then performed by screening YAC and BAC contigs spanning the critical region of the 5q- syndrome using PCR amplification. The HAH1 gene maps immediately adjacent to the SPARC gene at 5q32, and is flanked by the genetic markers D5S1838 and D5S1419. The HAH1 gene is expressed in haematological tissues and plays a role in antioxidant defence. Antioxidant levels are low in most cancers and the importance of antioxidant enzymes in cancer genesis is well recognised. Genomic localisation, function and expression would suggest that the HAH1 gene represents a candidate gene for the 5q-syndrome.     

A locus for hereditary capillary malformations mapped on chromosome 5q

Capillary malformations (port-wine stains) are the most common vascular malformations occurring in 0.3% of live births. Most capillary malformations occur sporadically and present as a solitary lesion. Capillary malformations can also occur as a component of well-described syndromes. Familial occurrence of multiple capillary malformations has been described in the literature, suggesting autosomal dominant inheritance with variable expression in this subgroup. A hereditary basis underlying the development of solitary capillary malformations has not been found, but may well be possible. We have mapped a locus for an autosomal dominant disorder in a three-generation family that manifested itself with multiple cutaneous capillary malformations to chromosome 5q13-22. This locus spans 48 cM between the markers D5S647 and D5S659 and harbours several candidate genes. By defining the gene(s) responsible for capillary malformations, we will gain more insight in the pathogenesis of this disorder. It is likely that genes implicated in these familial cases may be involved in the more sporadic cases.