遗传性痉挛性截瘫一家系的临床特点与遗传学分析

目的 探讨遗传性痉挛性截瘫(HSP)一家系的基因型和临床特点.方法 抽取1个HSP家系15名成员外周血,选择与已知HSP致病基因位点在物理距离上紧密连锁的微卫星分子进行标记[短串联重复序列(STR)],连锁分析并构建单体型.对患者进行观察,行心肌酶学、肌电图以及头颅、颈髓、胸髓MRI检查,总结其临床特点.结果 家系成员SIR的扩增产物进行基因分型,连锁分析发现与HSP 31型(SPG31)位点连锁,2个SIR(D2S2951、D2S2333)最大LOD值为1.8,表明连锁.经过连锁分析后得到的对应致病基因为REEP1基因,经过突变筛查发现了1个REEP1 c417+1G＞A杂合突变.SPG31临床特点以痉挛步态、下肢肌张力增高为主要表现,MRI显示胸髓萎缩.结论 SPG31患者临床特征表现为典型的HSP特征,致病基因为REEP1基因,存在REEP1 c417+1G＞A杂合突变.     

遗传性痉挛性截瘫2家系的临床特点与spastin基因突变分析

目的:探讨2个家系遗传3代以上常染色体显性遗传性痉挛性截瘫(AD-HSP)的临床特点及其与spastin基因突变的关系。方法:对2个AD-HSP家系进行详细的临床检查,总结所有患者临床特点,并应用PCR技术结合DNA序列分析方法,检测2家系先证者spastin基因的突变情况。结果:2家系中所有患者均具有HSP的典型表现,PCR-DNA序列分析2例先证者spastin基因的17个外显子均未发现有异常突变。结论:2家系HSP患者具有典型的AD-HSP临床表现,并非spastin基因外显子突变所致。     

发作性运动诱发性运动障碍一家系致病基因定位与突变分析

目的 探讨发作性运动诱发性运动障碍(PKD)家系临床特点,定位致病基因和检测突变.方法 对1个PKD家系的患者及其亲属进行临床资料分析,采集外周静脉血标本提取基因组DNA.选取16号染色体目前已报道位点内的微卫星标记,采用多重PCR技术对该家系进行连锁分析;普通PCR方法扩增候选基因SCNN1G和ITGAL外显子及毗邻序列,进行测序及家系共分离检测.结果 该家系3代12人,共5例患者.连锁分析提示当重组率(0)为0.0时在D16S3396和D16S3057处取得最大两点LOD值1.47,支持连锁.所有患者均携带完全相同的单体型并与疾病表型共分离.ITGAL、SCNN1G测序共发现8个序列变异,但均为已报道的单核苷酸多态(SNP),未发现家系共分离的致病性突变.结论 该PKD家系致病基因与位于16号染色体上已报道的PKD遗传位点连锁,进一步证明其为PKD的重要遗传位点;基本排除SCNN1G和ITGAL为该家系的致病基因,其致病基因有待进一步探索.     

贵州少数民族遗传性痉挛性截瘫患者spastin基因突变的研究

目的 研究贵州地区少数民族遗传性痉挛性截瘫(HSP)患者spastin基因突变的特征.方法 应用PCR产物直接DNA测序法,对贵州16例少数民族(布依、苗、彝族)HSP患者(其中14例患者来自3个常染色体显性遗传家系,2例散发患者)spastin基因的8、10、14号外显子进行分析.将测序结果与人类基因组SPG4基因序列进行比对.结果 16例患者的spastin基因8、10、14号外显子直接DNA测序结果均未发现有突变.结论 贵州少数民族HSP患者spastin基因8、10、14号外显子的突变可能较少见,其与汉族HSP患者的spastin基因突变形式可能不同.     

遗传性痉挛性截瘫spastin、atlastin和paraplegin基因突变分析

目的探讨遗传性痉挛性截瘫(HSP)spastin、atlastin和parap legin基因的突变特点。方法应用聚合酶链反应-单链构象多态性(PCR-SSCP)结合DNA序列分析方法对24个常染色体显性遗传HSP家系和14例散发患者进行spastin基因和atlastin基因突变分析;对12个常染色体隐性遗传HSP家系和14例散发患者进行parap legin基因突变分析。结果在5个不同的常染色体显性遗传HSP家系中发现4个spastin基因新突变(1223 insCTCA、1258T→A,1293A→G和1668delCTA),在2例散发患者中发现2个spastin基因多态(IVS1-31C→G和IVS2-47A→G);在常染色体显性遗传HSP家系和散发患者中未发现atlastin基因突变或多态;在常染色体隐性遗传HSP家系和散发患者中未发现致病突变,仅在2例散发患者中发现2个parap legin基因多态(2063G→A及2066G→A)。结论我国遗传性痉挛性截瘫患者中spastin基因突变较常见,atlastin和parap legin基因的突变率可能较低。     

一个2A型肢带型肌营养不良家系CAPN3基因的突变分析

目的对一个2A型肢带型肌营养不良(limb-girdle muscular dystrophy type 2A)家系进行CAPN3基因的致病突变分析。方法收集先证者及家系成员的外周血,提取DNA,应用全外显子测序技术对先证者进行致病基因检测,然后用Sanger测序技术对先证者家系成员进行突变位点的验证。结果全外显子测序发现先证者携带CAPN3基因c. 1194-9A G和c. 1437C T (p. ser479=)的复合杂合突变。Sanger测序验证先证者母亲为CAPN3基因c. 1194-9A G变异携带者。家系中其他患者均存在相同的复合杂合突变,其未发病的姐姐和女儿为CAPN3基因c. 1437C T (p. ser479=)变异携带者,先证者的女婿未检测到上述位点变异。结论 CAPN3基因c. 1194-9A G和c. 1437C T (p. ser479=)的复合杂合突变为该家系的致病原因。     

SPAST基因新位点突变致遗传性痉挛性截瘫的家系报道

目的 分析SPAST基因突变引起的遗传性痉挛性截瘫(HSP),提高临床医生对该病的认识。方法 回顾性分析1个2020年7月就诊于山东大学齐鲁医院最终确诊为HSP 4型的家系,明确致病基因,分析其临床表现,并复习相关文献。结果 患者及其母亲在SPAST基因第8外显子区域携带一处单杂合变异：c.1105A>C(腺嘌呤>胞嘧啶),导致氨基酸改变p.T369P(苏氨酸>脯氨酸)。SPAST基因c.1105A>C杂合突变可能为其家系致病性变异。结论 该家系携带的SPAST基因c.1105A>C杂合突变可能为其家系发病的原因。     

贵州部分少数民族遗传性痉挛性截瘫Spastin基因突变研究

目的筛查及分析遗传性痉挛性截瘫(HSP)Spastin基因突变,了解贵州地区少数民族(彝族、布衣族、苗族)Spastin基因突变特点。方法应用PCR产物直接DNA测序法,对9例HSP患者(包括3个家系中7例现证者和2例散发患者)Spastin基因1-17号外显子进行突变筛查;被发现存在突变的外显子,其次行家系内其他成员相对应外显子的筛查。结果在9例HSP患者中发现家系3两例患者(Ⅴ24、Ⅴ25)的Spastin基因第4号外显子同一位点上发生错义突变c.847C>T,其他参与抽血的亲属均无该位点突变,推测该位点的突变为一多态。另外的突变位点均位于外显子序列前后的内含子区域。结论此次贵州地区部分少数民族spastin基因突变率低,与国内文献报道的汉族人群不同。     

家族性低钾型周期性麻痹基因型和表型分析

研究背景分析一中国汉族家族性低钾型周期性麻痹家系的致病基因和相关临床资料。方法采用DNA序列技术对先证者(Ⅲ3)进行CACNA1S、SCN4A、KCNE3全基因组筛查,针对检测到的变异进一步检测家系中其他患者和无症状家系成员是否存在相同基因突变,经对临床资料分析以确定相关基因突变是否为致病性突变基因。结果先证者(Ⅲ3)及家系中其他患者(Ⅱ1、Ⅲ4、Ⅳ3)均检测到CACNA1S基因IVS25-194C/T突变,而无症状家系成员(Ⅲ1)未检测到该突变;该家系成员(除Ⅰ1)均检测到SCN4A基因IVS18-130G/A突变,该位点位于内含子区域且有症状和无症状家系成员同时出现;先证者(Ⅲ3)和无症状家系成员(Ⅲ1)同时检测到SCN4A基因外显子12区域c.1984GA突变,系错义突变(V662I),但家系中其他患者(Ⅱ1、Ⅲ4、Ⅳ3)均未发现该位点突变。结论结合临床资料和生物信息学预测,推测CACNA1S、SCN4A、KCNE3基因突变均非该家系致病性突变基因。但该家系资料丰富了我国原发性低钾型周期性麻痹家系的临床和基因数据库。除KCNE3、CACNA1S和SCN4A基因外,中国低钾型周期性麻痹家系可能存在新的致病基因突变,尚待进一步研究。     

广西地区一家系先天性肌强直的临床资料和基因测定

目的探讨先天性肌强直(MC)一家系的临床特点及CLCN1基因部分外显子位点突变的情况。方法收集广西壮族自治区1例MC患者的临床及家系资料,提取家系成员和对照组(无血缘关系的健康体检者6名)的外周静脉血DNA,采用聚合酶链反应(PCR)扩增部分CLCN1基因,测定该基因第3、5、8、13、14、15、16号外显子序列,并对突变位点进行分析。结果 MC患者的6名家系和对照组成员的PCR扩增凝胶电泳分析表明,同一引物对应各样本条带均无显著差异;CLCN1基因被测序的第3、5、8、13、14、15、16号外显子序列均未发现有突变位点。结论该MC患者及家系中患者的MC致病基因位点未位于CLCN1基因这7个外显子序列上,需要对CLCN1基因全外显子序列进行检测分析。     

Hereditary spastic paraplegia: clinical genetic study of 15 families

BACKGROUND: Autosomal dominant hereditary spastic paraplegia (ADHSP) is mainly caused by mutations in the SPG4 gene, which encodes a new member of the AAA (adenosine triphosphatases associated with diverse cellular activities) protein family (spastin). Accumulation of genotype-phenotype correlation is important for better understanding of SPG4-linked hereditary spastic paraplegia. OBJECTIVES: To perform a clinical and genetic study of families with ADHSP and to perform the functional analysis of the founder mutation discovered in the SPG4 gene. DESIGN: Genetic and clinical study.Patients Fifteen unrelated families with ADHSP originating from southern Scotland. MAIN OUTCOME MEASURES: Clinical assessment, linkage analysis, haplotype study, expression of mutant spastin protein in cultured cells. RESULTS: Nine families with ADHSP were linked to the SPG4 locus at 2p21-p24. Sequence analysis of SPG4showed a novel N386S mutation in all 9 of these families. Expression of mutant spastin showed aberrant distribution in cultured cells. Haplotype analysis suggested the existence of a common founder. Clinical examination of the affected members carrying the mutation showed phenotypic variations including broad range of age at onset and disease duration and additional neurologic features such as mental retardation. Magnetic resonance imaging demonstrated unique features, including thin corpus callosum and atrophy of the cerebellum in 2 patients. Linkage and sequence analyses showed no evidence of linkage to the currently known ADHSP loci in the remaining 6 families. CONCLUSIONS: A founder SPG4 mutation N386S was identified in the families with ADHSP originating from southern Scotland. Clinical investigation showed intrafamilial and interfamilial phenotypic variations. The genetic study demonstrated evidence of further genetic heterogeneity in ADHSP.     

Spectrum of SPG4 mutations in a large collection of North American families with hereditary spastic paraplegia

BACKGROUND: Hereditary spastic paraplegia (HSP) is a neurodegenerative disease characterized by progressive spasticity and weakness of the lower limbs. The most common form of HSP is caused by mutations in the SPG4 gene, which codes for spastin, an adenosine triphosphatase with various cellular activities (AAA) protein family member. OBJECTIVE: To investigate a large collection of predominantly North American patients with HSP for mutations in the spastin encoding gene, SPG4. METHODS: DNA from 76 unrelated affected individuals was studied for mutations by single-stranded conformational polymorphism analysis and direct sequencing. Each new variant identified was then analyzed in 80 control subjects to determine whether the variant is a common polymorphism or a rare mutation. All DNA samples were amplified by polymerase chain reaction, followed by electrophoresis and autoradiography. RESULTS: We identified 8 novel mutations and 5 previously reported mutations in 15 affected individuals. The novel mutations are 4 missense, 1 nonsense, 1 frameshift, and 2 splice mutations. Two polymorphisms (one in an affected individual) were also identified. CONCLUSIONS: Our collection of families with HSP is different on a genetic level from those previously described. The percentage of our families with a SPG4 mutation is 10% lower than the 40% estimate of families with autosomal dominant HSP noted to be linked to this locus, and splice mutations are not predominant in our collection. Interestingly, we also identified 2 recurring mutations in specific populations (R562Q and G559D), which may facilitate the development of future spastin diagnostic testing in these populations.     

Novel mutations in spastin gene and absence of correlation with age at onset of symptoms

Autosomal dominant hereditary spastic paraplegia is genetically heterogeneous, with at least five loci identified by linkage analysis. Recently, mutations in spastin were identified in SPG4, the most common locus for dominant hereditary spastic paraplegia that was previously mapped to chromosome 2p22. We identified five novel mutations in the spastin gene in five families with SPG4 mutations from North America and Tunisia and showed the absence of correlation between the predicted mutant spastin protein and age at onset of symptoms.     

Motor system abnormalities in hereditary spastic paraparesis type 4 (SPG4) depend on the type of mutation in the spastin gene

BACKGROUND: Hereditary spastic paraparesis (HSP) denotes a group of inherited neurological disorders with progressive lower limb spasticity as their clinical hallmark; a large proportion of autosomal dominant HSP belongs to HSP type 4, which has been linked to the SPG4 locus on chromosome 2. A variety of mutations have been identified within the SPG4 gene product, spastin. OBJECTIVE: Correlation of genotype and electrophysiological phenotype. MATERIAL: Two large families with HSP linked to the SPG4 locus with a very similar disease with respect to age of onset, progression, and severity of symptoms. METHODS: Mutation analysis was performed by PCR from genomic DNA and cDNA, and direct sequencing. The motor system was evaluated using transcranial magnetic stimulation. RESULTS: Patients differ in several categories depending on the type of mutation present. CONCLUSIONS: For the first time in hereditary spastic paraparesis, a phenotypic correlate of a given genetic change in the spastin gene has been shown.     

Spastin related hereditary spastic paraplegia with dysplastic corpus callosum

Thin corpus callosum has been recently observed in two patients with an autosomal dominant trait of hereditary spastic paraplegia (HSP) linked to a novel mutation in the spastin gene (SPG4). In the same two patients cerebellar atrophy has been found. Reportedly, in other members of the same family, there has been a variable presence of mental retardation. We report on the clinical and genetic investigation of an Austrian family with a novel mutation in the spastin gene. Genetic analysis of the SPG4 locus revealed a mutation (C1120A) and a known intronic polymorphism (996-47G>A) of the spastin gene. In one affected family member, previously undescribed dysplasia of the corpus callosum (CC) was found in conjunction with otherwise uncomplicated HSP. Dysplastic CC was not paralleled with cortical atrophy, cognitive impairment or other phenotypic variations. Two further affected family members showed the same mutation and polymorphism, but no evidence of CC abnormalities. We conclude that apparently pure HSP may present with MRI features of dysplastic CC. This finding extended the spastin-related phenotype which is distinct from previous reports of thin CC in HSP.     

Mutation analysis of SPG4 and SPG3A genes and its implication in molecular diagnosis of Korean patients with hereditary spastic paraplegia

BACKGROUND: Hereditary spastic paraplegia (HSP), a genetically and clinically heterogeneous group of neurodegenerative disorders, is characterized by progressive lower limb weakness and spasticity. Among the 8 loci associated with the autosomal dominant uncomplicated HSP (AD-HSP), the spastin (SPG4) and atlastin (SPG3A) genes have been known to account for approximately 40% and 10% of all cases, respectively. OBJECTIVE: To investigate the contribution of these 2 genes in the occurrence of HSP in Korean patients. DESIGN: Clinical and genetic study. SETTING: Tertiary care center. PATIENTS: Eighteen patients with uncomplicated HSP (11 AD and 7 sporadic) underwent screening for gene mutation. MAIN OUTCOME MEASURES: Mutations in the SPG4 and SPG3A genes as detected by direct sequencing of all coding exons and flanking intronic sequences. RESULTS: We identified 8 different SPG4 mutations, 7 of which have not been reported elsewhere. Among the detected mutations were 3 missense mutations, 2 in-frame deletions, 2 frameshift mutations, and 1 splice-site mutation. No mutation was found in the SPG3A gene. CONCLUSION: Compared with previous studies, a higher frequency of SPG4 gene mutations in AD-HSP (7/11; 64%) was observed, suggesting that a mutation analysis for the SPG4 gene might be helpful for molecular diagnosis of AD-HSP in Korean patients.     

Hereditary spastic paraplegia with cerebellar ataxia: a complex phenotype associated with a new SPG4 gene mutation

Complex forms of hereditary spastic paraplegia (HSP) are rare and usually transmitted in an autosomal recessive pattern. A family of four generations with autosomal dominant hereditary spastic paraplegia (AD-HSP) and a complex phenotype with variably expressed co-existing ataxia, dysarthria, unipolar depression, epilepsy, migraine, and cognitive impairment was investigated. Genetic linkage analysis and sequencing of the SPG4 gene was performed and electrophysiologic investigations were carried out in six individuals and positron emission tomography (PET) in one patient. The disease was linked to the SPG4 locus on chromosome 2p as previously reported for pure HSP. Sequence analysis of the SPG4 (spastin) gene identified a novel 1593 C > T (GLN490Stop) mutation leading to premature termination of exon 12 with ensuing truncation of the encoded protein. However, the mutation was only identified in those individuals who were clinically affected by a complex phenotype consisting of HSP and cerebellar ataxia. Other features noted in this kindred including epilepsy, cognitive impairment, depression, and migraine did not segregate with the HSP phenotype or mutation, and therefore the significance of these features to SPG4 is unclear. Electrophysiologic investigation showed increased central conduction time at somatosensory evoked potentials measured from the lower limbs as the only abnormal finding in two affected individuals with the SPG4 mutation. Moreover, PET of one patient showed significantly relatively decreased regional cerebral blood flow in most of the cerebellum. We conclude that this kindred demonstrates a considerable overlap between cerebellar ataxia and spastic paraplegia, emphasizing the marked clinical heterogeneity of HSP associated with spastin mutations.     

An atypical intronic deletion widens the spectrum of mutations in hereditary spastic paraplegia

OBJECTIVE: To identify the genetic mutation responsible for autosomal dominant spastic paraplegia (HSP) in a large family with a "pure" form of the disorder. BACKGROUND: The disease locus in most families with HSP is genetically linked to the SPG4 locus on chromosome 2p21-p22. Some of these families have mutations in the splice-site or coding regions of the spastin gene (SPAST). METHODS: Linkage and mutational analyses were used to identify the location and the nature of the genetic defect causing the disorder in a large family. After the disease phenotype was linked to the SPG4 locus, all 17 coding regions and flanking intronic sequences of SPAST were analyzed by single-strand conformation polymorphism analysis (SSCP) and compared between affected and normal individuals. Direct sequencing and subcloning methods were used to investigate incongruous mobility shifts. RESULTS:The genomic sequence of SPAST showed a heterozygous four--base pair deletion (delTAAT) near the 3' splice-site of exon three in all 11 affected individuals but not in 21 normal family members or in 50 unrelated controls (100 chromosomes). CONCLUSIONS: This study identifies an atypical intronic microdeletion in SPAST that causes HSP and widens the spectrum of genetic abnormalities that cause the disorder.     

Clinical and genetic study of a large Italian family linked to SPG12 locus

BACKGROUND: Seven loci for autosomal dominant hereditary spastic paraplegia (ADHSP) have been mapped. To date, two families of SPG12 (chromosome 19q13) have been analyzed; however, there is not enough clinical information on SPG12 to establish locus-phenotype correlations. METHODS: The authors studied 60 individuals from a large Italian family with ADHSP, in which 16 members in four generations were affected. They performed genetic linkage analysis with DNA markers from currently known ADHSP loci. After database searching, one candidate gene for SPG12 was analyzed by sequencing. RESULTS: The patients in this family showed an early onset and rapid progression of symptoms, resulting in severe disability, with a large proportion of affected members requiring use of a wheelchair. By age 16, most patients had sensory disturbance. Evidence for linkage to the SPG12 locus was obtained. Obligate recombination events observed in this family have narrowed the SPG12 locus from the 16.1 cM to 11.3 cM region between markers D19S416 and D19S412. In combination with previous genetic studies, the SPG12 locus was further narrowed to the 3.3 cM region between D19S416 and D19S220. A homologue of the AAA (ATPases associated with a variety of cellular activities) protein family, proteasome 26S subunit ATPase mapped near D19S220, was excluded by sequencing. CONCLUSIONS: This study refined the SPG12 region between D19S416 and D19S220 and revealed several clinical characteristics-early onset, rapid progression, and involvement of sensory disturbance-that may be unique to SPG12. Suggestive evidence of genetic anticipation was obtained, but should be confirmed in other SPG12 families.     

Clinical signs and symptoms in a large hereditary spastic paraparesis pedigree with a novel spastin mutation.

The most common form of autosomal dominant hereditary spastic paraparesis (HSP), SPG4, is caused by mutations in the spastin gene on chromosome 2p. This disease is characterized by intra- and interfamilial phenotypic variation. To determine the predictive values of clinical signs and symptoms in SPG4, we examined 43 members of a large pedigree with autosomal dominant HSP. We then identified the genetic etiology of the disorder in this family, a novel nonsense mutation in exon 1 of spastin, carried by 24 of the examined family members. The best clinical predictors of positive gene status were the presence of hyperreflexia in the lower extremities, >2 beats of ankle clonus, pes cavus, bladder symptoms and increased tone in the legs. The mean age of onset was 32.2 +/- 7.4 years, but the age of onset was earlier in children from 10 of 12 child-parent gene-positive pairs, with a mean difference of 10.8 +/- 3.3 years. The finding of leg weakness was especially common in older-onset affected family member with leg hyperreflexia. These results suggest that specific clinical signs and symptoms may be of value in differentiating individuals affected with SPG4 from family members with nonspecific neurological findings.