注意缺损多动障碍的X染色体基因组扫描分析

摘 要：注意缺损多动障碍（ADHD）是儿童期多见行为障碍。男孩发病多于女孩。家系、双生儿和寄养子研究显示该障碍发生具有遗传基础。但是病因尚不清楚。分子遗传学和药理学研究表明ADHD涉及到多巴胺和去甲肾上腺素等神经递质系统,一系列报告发现ADHD与多巴胺D4受体（DRD4）、多巴胺转运体（DAT1）和儿茶酚-O-甲基转移酶（COMT）等基因相关联。我们以往研究表明ADHD与X染色体上DXS7位点和MAOA基因相关联,而DXS7是紧密连锁于MAO基因。依此假设,我们应用基因组扫描技术探讨ADHD在X染色体上易感位点。采用TDT方法分析X染色体上48个DNA标志的多态性与中国人群中84个ADHD核心家系间的连锁关系,ADHD诊断依据DSM-III-R标准。TDT分析结果观察到如下位点与ADHD相连锁,DXS1214(TDT:χ2=18.1,df=7, P<0.01), DXS8102(TDT: χ2=7.9, df=3, P<0.05),DXS1068(TDT: χ2=21.9, df=9, P<0.01), DXS8015(TDT:χ2=14.6, df=7, P<0.05),DXS1059(TDT: χ2=27.8, df=10, P<0.01) 和DXS8088(TDT:χ2=20.4, df=3, P<0.01).研究资料提示X染色体上Xp11.4-Xp21和Xq23区域可能存在ADHD的易感基因。     

广州地区106例汉族人群MICA和MICB微卫星基因座 单体型研究 The Study on the Haplotype of MICA and MICB Microsatellite Locus In Guangzhou Han Population

利用聚合酶链反应和荧光（6－FAM）自动化检测技术对广东地区汉族106例无亲缘关系样本进行MICA基因外显子5和MICB基因内含子1微卫星基因座多态性及其单体型分布调查。根据群体资料估算两者间的单体型频率、连锁不平衡参数、相对连锁不平衡参数。结果显示，广州地区汉族人群MICA和MICB微卫星基因座基因型分布符合Hardy-Weinberg平衡法则，共检出MICA微卫星基因座 5个等位基因， MICB微卫星基因座14个等位基因。其中MICA A5基因频率最高（0.2877），A4基因频率最低（0.1321）。MICB CA14等位基因频率最高（0.3255），CA19、CA28等位基因频率最低（0.0047），未检出CA27。21种MICA－MICB单体型频率大于1%(连锁不平衡参数>0), 其中单体型A5－CA14 (16.73%), A5.1－CA18 (8.75%), A4－CA26(3.76%)，A9－CA15(3.66%)和A6－CA21(2.61%)为强连锁常见单体型（χ2>3.84, P<0.05）。广州地区汉族人群MICA和MICB微卫星基因座多态性和单体型分布有其自身特点，MICA和MICB微卫星基因座适合做为遗传标志，用于人类学、遗传疾病基因连锁分析、法医学亲子鉴定和个体识别等研究领域。Abstract: This study is to investigate genetic polymorphisms and haplotypes of microsatellite locus in the exon 5 of the MICA gene and intron 1 of the MICB gene based on 106 samples of Guangzhou Han Population by polymerase chain reaction and fluorescent technique (6-FAM). The corresponding haplotype frequencies, linkage disequilibria values and relative linkage disequilibria values were estimated based on population data. The results show that the genotype distributions of MICA and MICB microsatellite meet Hardy-Weinberg equilibrium in Guangdong Han population. In total, 5 alleles of MICA microsatellite locus and 14 alleles of MICB microsatellite locus were observed. MICA A5 was the most common allele (0.2877), whereas A4 was the least popular one (0.1321). MICB CA14 was the most common allele (0.3255), and CA19 and CA28 were the least popular ones (0.0047). CA27 was not observed. Twenty-one kinds of MICA-MICB haplotypes occurred at frequencies of more than 1% (linkage disequilibria value>0). The common MICA-MICB haplotypes were A5-CA14（16.73％）, A5.1- CA18 (8.75%), A4- CA26(3.76%)，A9-CA15(3.66%) and A6-CA21(2.61%)（χ2>3.84, P<0.05）, and they were strong linkage disequilibria. The polymorphisms and haplotypes distributions of MICA and MICB microsatellite locus in Guangzhou Han population have their own genetic characteristics. The microsatellite locus of the exon5 of the MICA gene and intron 1 of the MICB gene could be used as the genetic markers in the studies of anthropology, linkage analysis of genetic disease genes, individual identification and paternity test in forensic medicine.     

广州地区106例汉族人群MICA和MICB微卫星基因座 单体型研究

利用聚合酶链反应和荧光（6－FAM）自动化检测技术对广东地区汉族106例无亲缘关系样本进行MICA基因外显子5和MICB基因内含子1微卫星基因座多态性及其单体型分布调查。根据群体资料估算两者间的单体型频率、连锁不平衡参数、相对连锁不平衡参数。结果显示,广州地区汉族人群MICA和MICB微卫星基因座基因型分布符合Hardy-Weinberg平衡法则,共检出MICA微卫星基因座 5个等位基因, MICB微卫星基因座14个等位基因。其中MICA A5基因频率最高（0.2877）,A4基因频率最低（0.1321）。MICB CA14等位基因频率最高（0.3255）,CA19、CA28等位基因频率最低（0.0047）,未检出CA27。21种MICA－MICB单体型频率大于1%(连锁不平衡参数>0), 其中单体型A5－CA14 (16.73%), A5.1－CA18 (8.75%), A4－CA26(3.76%),A9－CA15(3.66%)和A6－CA21(2.61%)为强连锁常见单体型（χ2>3.84, P<0.05）。广州地区汉族人群MICA和MICB微卫星基因座多态性和单体型分布有其自身特点,MICA和MICB微卫星基因座适合做为遗传标志,用于人类学、遗传疾病基因连锁分析、法医学亲子鉴定和个体识别等研究领域。Abstract: This study is to investigate genetic polymorphisms and haplotypes of microsatellite locus in the exon 5 of the MICA gene and intron 1 of the MICB gene based on 106 samples of Guangzhou Han Population by polymerase chain reaction and fluorescent technique (6-FAM). The corresponding haplotype frequencies, linkage disequilibria values and relative linkage disequilibria values were estimated based on population data. The results show that the genotype distributions of MICA and MICB microsatellite meet Hardy-Weinberg equilibrium in Guangdong Han population. In total, 5 alleles of MICA microsatellite locus and 14 alleles of MICB microsatellite locus were observed. MICA A5 was the most common allele (0.2877), whereas A4 was the least popular one (0.1321). MICB CA14 was the most common allele (0.3255), and CA19 and CA28 were the least popular ones (0.0047). CA27 was not observed. Twenty-one kinds of MICA-MICB haplotypes occurred at frequencies of more than 1% (linkage disequilibria value>0). The common MICA-MICB haplotypes were A5-CA14（16.73％）, A5.1- CA18 (8.75%), A4- CA26(3.76%),A9-CA15(3.66%) and A6-CA21(2.61%)（χ2>3.84, P<0.05）, and they were strong linkage disequilibria. The polymorphisms and haplotypes distributions of MICA and MICB microsatellite locus in Guangzhou Han population have their own genetic characteristics. The microsatellite locus of the exon5 of the MICA gene and intron 1 of the MICB gene could be used as the genetic markers in the studies of anthropology, linkage analysis of genetic disease genes, individual identification and paternity test in forensic medicine.     

DXS6804/DXS9896/GATA144D04基因座在中国汉族群体中的遗传多态性及其法医学应用Genetic

为了调查X染色体上DXS6804、DXS9896和 GATA144D04等3个STR基因座在中国汉族群体的遗传多态性及其法医学应用价值,来用PCR和聚丙烯酰胺凝胶电泳对X染色体3个STR基因座进行分型,并检验女性基因型频率分布是否符合Hardy-Weinberg平衡,计算法医学常用各种概率。DXS6804、DXS9896和 GATA144D04的非父排除率分别为0.5990、0.6220、0.4280,表明3个STR基因座在中国汉族群体均具有遗传多态性,χ2检验表明女性的基因型频率分布符合Hardy-Weinberg平衡。X染色体上的基因座DXS6804、DXS9896和 GATA144D04在中国汉族群体中具有较高的遗传多态性,可应用于法医学检验和群体遗传学分析。 Abstract： To investigate the genetic polymorphisms of three short tandem repeats loci of chromosome X in Chinese Han population in Chengdu area and its use in forensic science. Three X-chromosome linked short tandom repeat loci were analyzed by PCR followed by polyacrylamide gel electrophoresis. Hardy-Weinberg equilibrium was tested and forensic interested value was calculated .The power of exlcution of DXS6804、DXS9896和 GATA144D04 is 0.5990、0.6220、0.4280,respectively. The result showed that all the three STR loci were polymorphic among 100 unrelated females and 120 unrelated males from Chinese Han population. χ2 tests demonstrated that genotype frequencies in females did not depart from Hardy-Weinberg equilibrium. Three X-chromosome linked short tandem repeat loci have high polymorphism, they can be applied to forensic medicine and population genetics.     

两个基因座位的遗传平衡原理

由于许多教科书中关于连锁平衡的介绍,多是引用结论或是推导不太严谨,使学生在学习群体遗传学时对理解连锁平衡的原理感到困难。本文从遗传平衡的基本条件出发,通过较严谨的数学推导,介绍了两个基因座的连锁平衡条件、平衡过程等原理,供教师和学生在群体遗传学教学中参考。Abstract: Because linkage equilibrium is introduced by directly quoting the conclusions or imprecise mathematical reasoning in most of textbooks, many students are puzzled with the problem of linkage equilibrium when they learn population genetics. Based on the radical conditions of genetic equilibrium, the principle of linkage equilibrium condition and process, for two gene loci is introduced by precise mathematical reasoning. The article may provide reference to teachers and students in the teaching and learning of population genetics.     

常染色体显性遗传小眼球病与12个微卫星多态标志的初步连锁分析

本文报道了一个常染色体显性遗传小眼球的大家系,初步排除了此家系致病基因在目前已知位点(CHX10、MITF、RX、MCOP、NNO1、NNO2)的可能,并探讨了与11号染色体上的微卫星DNA标志的连锁关系。采用聚合酶链(PCR)扩增微卫星DNA片段,扩增产物进行聚丙烯酰胺凝胶电泳,用银染显示结果;用MLINK连锁分析软件计算LOD值。结果显示,本家系小眼球致病基因与6个已知位点及11号染色体上的微卫星DNA标志之间不存在连锁,提示此家系的致病位点目前尚未被定位。     

蛋用鹌鹑伴性羽色基因互作与连锁的关系

本研究首次发现了鹌鹑伴性羽基因的基因互作关系并进行了遗传验证.试验证明,鹌鹑的栗羽、黄羽和白羽是Z染色体上两个有连锁关系的基因座B/b和Y/y相互作用的结果.B和b为一对等位基因,不控制任何性状,只与色素的合成有关,B为有色基因,b为白化基因,B对b为显性;Y和y为另一对等位基因,分别控制栗羽和黄羽,Y对y为显性.栗羽和黄羽的表现取决于有色基因B的存在,B与Y相互作用产生栗羽,B与y相互作用产生黄羽,白羽是白化基因b对Y和y上位作用的结果.B/b和Y/y两基因座在雄性表现出一定的互换率,在雌性为完全连锁.这一研究补充和发展了以前人们对鹌鹑羽色伴性遗传的研究,为人们利用鹌鹑羽色进行自别雌雄配套系生产提供了重要的遗传学基础。 Abstract:The interaction of sex-linked gene for plumage color in quails was first discovered and identified by genetictest.It was proved that the phenotypic expressions of the maroon feather,the yellow feather and the white feather result from the interaction between B/b and Y/y loci in the Z-chromosome.The allele B and b have something to do with the composition of pigment in plumage and nothing to do with any relative characters,the coloured gene B is dominant to its albino allele b.The maroon and yellow feather constituted a pair of relative characters determined by a couple of alleles Y and y,the maroon feather was caused by a dominant allele Y,and the yellow feather caused by a recessive allele y.But the phenotypic expression of maroon and yellow was decided by the present of the coloured gene B in Z-chromosome,the maroon feather was the result of interaction between gene B and Y,the yellow feather was result of interaction between gene B and y.The white was caused by a recessive albino gene b which epistasis to gene Y and y.The incomplete linkage was present between B/b and Y/y in Z-chromosome in male and complete linkage in female.This research enriches and delelops the earlier studies of the sex-linked inheritance of plumage color.It provides an important genetic basis for the quail autosexing system production by means of plumage color.     

中国人St14/TaqⅠRFLPs及其在甲型血友病基因连锁分析与产前基因诊断中的应用

St 14(DXS 52)是人X染色体长臂远端的一段基因外DNA序列,与FVⅢ基因紧密连锁。我们分析了95个中国人的St 14/Taq I RFLPs,在44条无遗传关系的X染色体中,St14/Taq 13.6 kb片段出现的频率为31％而4.5kb、4.1kb片段出现的频率则相对较低,与国外报道明显不同。以此RFLPs作为FVⅢ基因的遗传标志,我们分析了8个甲型血友病家系。3个家系中有缺陷FVⅢ基因的可以用此RFLPs进行连锁分析,其中1例为首次应用这一RFLPs连锁分析完成的产前基因诊断。     

多态信息量（PIC）等于杂合度吗？ Does the Polymorphism Information Content Equal the Heterozygosity?

多态信息量用于连锁分析时对标志基因（或标志序列）的多态性估计,杂合度则用于群体遗传学上对群体多态性的描述;前者主要服务于基因定位和产前诊断,而后者则可对进化因子的效应予以分析,两者不仅含义不同,而且往往值也不同。本文对上述问题进行了分析并提出了自己的一些看法。Abstract: The polymorphism information content(PIC) that measures the extent of polymorphism for marker gene(s) or marker sequence(s) is applied to the linkage analysis of pedigree(s), whereas the heterozygosity that estimates polymorphic amount within a population or a subpopulation is used to population genetics study, so that PIC is different from Heterozygosity. This paper will discuss points at length some of which are personal views.     

中国甘肃裕固族X-STR遗传多态性及其应用研究

为研究中国甘肃裕固族人群X染色体STR基因座的遗传多态性及其在群体遗传学中的应用, 采用PCR扩增, 变性聚丙烯酰胺凝胶电泳结合银染显带技术, 检测120名(女55, 男65)裕固族无关个体9个X-STR基因座(DXS7130、DXS7132、DXS6804、DXS7423、DXS7424、DXS6789、DXS6799、DXS8378和HPRTB)的等位基因频率及基因型分布, 以及存在连锁的X-STR基因座的单体型多态性; 同时, 利用X-STR构建系统发生树和进行聚类分析, 分析裕固族与我国其他民族的群体遗传关系。结果发现, DXS7130、DXS7132、DXS6804、DXS7423、DXS7424、DXS6789、DXS6799、DXS8378和HPRTB基因座分别检出8、6、6、5、6、7、6、4、6个等位基因和16、14、13、6、13、20、11、6、12种基因型, 9个X-STR基因座女性的基因型频率分布均符合Hardy-Weinberg平衡(P>0.05)。由DXS7130和DXS8378基因座组成的单体型共检出15种, 由DXS6789、DXS6799、DXS7424和DXS6804基因座组成的单体型共检出55种, 单体型多样性分别为0.8212和0.9947。群体遗传多态性指标显示上述9个X-STR基因座均具有较高多态性, 在法医学个体识别、亲权鉴定及群体遗传学研究中有重要应用价值。对裕固族与我国其他民族群体遗传关系的研究结果显示, 裕固族与蒙古族及同处西北的汉族、藏族关系较近, 而与回族、维族关系较远, 提示裕固族是一个在起源上与蒙古族、汉族以及藏族关系密切的民族群体。     

Congenital motor nystagmus linked to Xq26-q27.

Congenital motor nystagmus (CMN) is a hereditary disorder characterized by bilateral ocular oscillations that begin in the first 6 mo of life. It must be distinguished from those genetic disorders-such as ocular albinism (OA), congenital stationary night blindness (CSNB), and blue-cone monochromatism (BCM)-in which nystagmus accompanies a clinically apparent defect in the visual sensory system. Although CMN is presumed to arise from a neurological abnormality of fixation, it is not known whether the molecular defect is located in the eye or in the brain. It may be inherited in an autosomal dominant, autosomal recessive, or X-linked pattern. Three families with CMN inherited in an X-linked, irregularly dominant pattern were investigated with linkage and candidate gene analysis. The penetrance among obligate female carriers was 54%. Evaluation of markers in the region of the genes for X-linked OA, CSNB, and BCM revealed no evidence of linkage, supporting the hypothesis that CMN represents a distinct entity. The gene was mapped to chromosome Xq26-q27 with the following markers: GATA172D05 (LOD score 3.164; recombination fraction [theta] = 0.156), DXS1047 (LOD score 10.296; theta = 0), DXS1192 (LOD score 8.174; theta = 0.027), DXS1232 (LOD score 6.015; theta = 0.036), DXS984 (LOD score 6.695; theta = 0), and GATA31E08 (LOD score 4.940; theta = 0.083). Assessment of haplotypes and multipoint linkage analysis, which gave a maximum LOD score of 10.790 with the 1-LOD-unit support interval spanning approximately 7 cM, place the gene in a region between GATA172D05 and DXS1192. Evaluation of candidate genes CDR1 and SOX3 did not reveal mutations in affected male subjects.     

Confirmation and refinement of a genetic locus of congenital motor nystagmus in Xq26.3-q27.1 in a Chinese family

Congenital motor nystagmus (CMN), a subtype of nystagmus, may reduce vision or be associated with other, more serious, conditions that limit vision. The genetic basis for CMN is still unknown. To identify a locus for CMN, genotyping and linkage analysis were performed in 22 individuals from a Chinese family with X-linked CMN using markers from X chromosome. The maximum LOD score obtained for microsatellite maker DXS1192 linked the CMN locus in this family to Xq. By haplotype construction the locus for CMN was finally localized to an approximately 4.4-cM region at chromosome Xq26.3-q27.1. The SLC9A6 and FGF13 genes in this region, were selected and screened for mutation in this family, but no mutation was detected.B. Zhang and K. Xia contribute to this work equally     

A family with X-linked deafness showing linkage to the proximal Xq region of the X chromosome

Linkage analysis has been carried out in a family with severe congenital sensorineural deafness with a structural abnormality of the inner ear. Recombinations show the gene responsible for deafness in this family to lie between the loci DXS255 (Xp11.22) and DXS94 (Xq22). Close linkage was found to locus DXS159 (cpX289) in Xq12, with a LOD score of 3.155 and 0 recombination. This location is consistent with other linkage studies of X-linked deafness.     

Localization of the Aland Island eye disease locus to the pericentromeric region of the X chromosome by linkage analysis.

Aland Island eye disease (AIED) is an X-chromosomal disorder characterized by reduced visual acuity, progressive axial myopia, regular astigmatism, latent nystagmus, foveal hypoplasia, defective dark adaptation, and fundus hypopigmentation. The syndrome was originally reported in 1964 in a family on the Aland Islands. To determine the localization of the AIED gene, linkage studies were performed in this family. total of 37 polymorphisms, covering loci on the entire X chromosome, were used. By two-point analysis the strongest evidence for linkage was obtained between AIED and DXS255 (maximum lod score [Zmax] 4.92 at maximum recombination fraction [theta max] .00). Marker loci DXS106, DXS159, and DXS1 also showed no recombination with AIED. Other positive lod scores at theta max .00 were obtained with markers localized in the XY homologous region in Xq13-q21, but the numbers of informative meioses were small. Multilocus linkage analysis indicated that the most probable location of AIED is in the pericentromeric region between DXS7 and DXS72. These results rule out localizations of AIED more distal on Xp that have been proposed by others. Our data do not exclude the possibility that AIED and incomplete congenital stationary night blindness are caused by mutations in the same gene. This question should be resolved by careful clinical comparison of the disorders and ultimately by the molecular dissection of the genes themselves.     

Assignment of the Nance-Horan syndrome to the distal short arm of the X chromosome

Summary There are three types of X-linked cataracts recorded in Mendelian Inheritance in Man (McKusick 1988): congenital total, with posterior sutural opacities in heterozygotes: congenital, with microcornea or slight microphthalmia; and the cataract-dental syndrome or Nance-Horan (NH) syndrome. To identify a DNA marker close to the gene responsible for the NH syndrome, linkage analysis on 36 members in a three-generation pedigree including seven affected males and nine carrier females was performed using 31 DNA markers. A LOD score of 1.662 at 0=0.16 was obtained with probe 782 from locus DXS85 on Xp22.2–p22.3. Negative LOD scores were found at six loci on the short arm, one distal to DXS85, five proximal, and six probes spanning the long arm were highly negative. These results make the assignment of the locus for NH to the distal end of the short arm of the X chromosome likely.     

Tightly linked flanking markers for the Lowe oculocerebrorenal syndrome, with application to carrier assessment.

The Lowe oculocerebrorenal syndrome (OCRL) is characterized by congenital cataract, mental retardation, and defective renal tubular function. A map assignment of OCRL to Xq24-q26 has been made previously by linkage analysis with DXS42 at Xq24-q26 (theta = 0, z = 5.09) and with DXS10 at Xq26 (theta = 0, z = 6.45). Two additional families were studied and three additional polymorphisms were identified at DXS42 by using a 35-kb sequence isolated with the probe detecting the original polymorphism at DXS42. With additional OCRL families made informative for DXS42, theta remained 0 with z = 6.63; and for DXS10 theta = 0.03 and z = 7.07. Evidence for placing OCRL at Xq25 also comes from a female with Lowe syndrome and an X;3 translocation. We have used the Xq25 breakpoint in this patient to determine the position of OCRL relative to the two linked markers. Each derivative chromosome was isolated away from its normal counterpart in somatic cell hybrids. DXS42 was mapped to the derivative chromosome X containing Xpterq25, and DXS10 was mapped to the derivative chromosome 3 containing Xq25-qter. The markers DXS10 and DXS42 therefore show tight linkage with OCRL in six families and flank the Xq25 breakpoint in a female patient with an X;3 translocation. Linkage analysis with flanking markers was used to assess OCRL carrier status in women at risk. Results, when compared with carrier determination by ophthalmologic examination, indicated that the slit-lamp exam can be a sensitive and specific method of carrier determination in many cases.     

Familial skewed X inactivation: a molecular trait associated with high spontaneous-abortion rate maps to Xq28.

We report a family ascertained for molecular diagnosis of muscular dystrophy in a young girl, in which preferential activation (> or = 95% of cells) of the paternal X chromosome was seen in both the proband and her mother. To determine the molecular basis for skewed X inactivation, we studied X-inactivation patterns in peripheral blood and/or oral mucosal cells from 50 members of this family and from a cohort of normal females. We found excellent concordance between X-inactivation patterns in blood and oral mucosal cell nuclei in all females. Of the 50 female pedigree members studied, 16 showed preferential use (> or = 95% cells) of the paternal X chromosome; none of 62 randomly selected females showed similarly skewed X inactivation was maternally inherited in this family. A linkage study using the molecular trait of skewed X inactivation as the scored phenotype localized this trait to Xq28 (DXS1108; maximum LOD score [Zmax] = 4.34, recombination fraction [theta] = 0). Both genotyping of additional markers and FISH of a YAC probe in Xq28 showed a deletion spanning from intron 22 of the factor VIII gene to DXS115-3. This deletion completely cosegregated with the trait (Zmax = 6.92, theta = 0). Comparison of clinical findings between affected and unaffected females in the 50-member pedigree showed a statistically significant increase in spontaneous-abortion rate in the females carrying the trait (P < .02). To our knowledge, this is the first gene-mapping study of abnormalities of X-inactivation patterns and is the first association of a specific locus for recurrent spontaneous abortion in a cytogenetically normal family. The involvement of this locus in cell lethality, cell-growth disadvantage, developmental abnormalities, or the X-inactivation process is discussed.     

Localization of a mutant gene for cleft palate and ankyloglossia in an X-linked Icelandic family.

Common congenital malformations such as cleft lip and cleft palate are in most cases multifactorial in origin, involving both environmental and genetic components. Molecular biology techniques have enabled the successful chromosomal localization of many mutant genes from disorders that exhibit simple Mendelian segregation, whether autosomally dominant (e.g., Huntington's disease), autosomal recessive (e.g., cystic fibrosis), or X-linked (e.g., Duchenne muscular dystrophy). Studying the genetic aspect of multifactorial disorders is more complex. It requires a model family or families within which the common multifactorial phenotype is displayed as a single gene defect. Such a model has been recently exploited in the form of a large Icelandic family (over 280 members) exhibiting X-linked secondary cleft palate (CP) and ankyloglossia (A) (tongue-tied) as a single gene mutation. Using this family and the large bank of well-characterized DNA probes available for the human X chromosome, the gene for CP + A was localized by linkage analysis to Xq13-q21.1 (LOD score = 3.07, linked to anonymous probe DXYS1). Further fine mapping, using other X probes from this region (confirmed by analysis of DNA from a deletion cell-line) has placed the gene between markers DXYS12 and DXS17 (LOD score = 4.1) at Xq21.3-q22. The approximate distance between these two probes is 5 centimorgans (cM), equivalent to approximately 5 million base pairs. Now that the limits of genetic linkage have been fully tested and there are two markers flanking the defect locus, strategies are being pursued to clone the gene responsible.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic mapping of X-linked albinism-deafness syndrome (ADFN) to Xq26.3-q27.1

X-linked albinism-deafness syndrome (ADFN) was described in one Israeli Jewish family and is characterized by congenital nerve deafness and piebaldness. The ADFN mutation probably affects the migration of neural crest-derived precursors of the melanocytes. As a first step toward identifying the ADFN gene, a linkage study was performed to localize the disease locus on the X chromosome. The family was found to be informative for 11 of 107 RFLPs along the X, and two-point analysis showed four of them--factor 9 (F9), DXS91, DXS37, and DNF1--to have definite or suggestive linkage with ADFN. Multipoint linkage analysis indicated two possible orders within this cluster of loci, neither of which was preferable. In both orders F9 was the most distal, and the best estimate for the location of ADFN was between F9 and the next proximal marker (8.6 cM from F9 [Z = 8.1] or 8.3 cM from F9 [Z = 7.9]). These results suggest that the ADFN is at Xq26.3-q27.1. Disagreement between our data and previous localization of DXS91 at Xq11-q13 was resolved by hybridization of the probe pXG-17, which detects the DXS91 locus, to a panel of somatic cell hybrids containing different portions of the X chromosome. This experiment showed that this locus is definitely at Xq24-q26. Together with the linkage data, our results place DXS91 at Xq26 and underscore the importance of using more than one mapping method for the localization of molecular probes.     

Exclusion mapping of the gene for X-linked neural tube defects in an Icelandic family

Various polymorphic markers with a random distribution along the X chromosome were used in a linkage analysis performed on a family with apparently Xlinked recessive inheritance of neural tube defects (NTD). The lod score values were used to generate an exclusion map of the X chromosome; this showed that the responsible gene was probably not located in the middle part of Xp or in the distal region of Xq. A further refining of these results was achieved by haplotype analysis, which indicated that the gene for X-linked NTD was located either within Xp21.1-pter, distal from the DMD locus, or in the region Xq12–q24 between DXS106 and DXS424. Multipoint linkage analysis revealed that the likelihood for gene location is highest for the region on Xp. The region Xq26–q28, which has syntenic homology with the segment of the murine X chromosome carrying the locus for bent tail (Bn), a mouse model for X-linked NTD, is excluded as the location for the gene underlying X-linked NTD in the present family. Thus, the human homologue of the Bn gene and the present defective gene are not identical, suggesting that more than one gene on the X chromosome plays a role in the development of the neural tube.