Vacuoliting megalencephalic leukoencephalopathy with subcortical cysts, mapped to chromosome 22qtel.

The leukodystrophies form a complex group of orphan genetic disorders that primarily affect myelin, the main constituent of the brain white matter. Among the leukodystrophies of undetermined etiology, a new clinical entity called "vacuoliting megalencephalic leukoencephalopathy" (VL) was recently recognized. VL is characterized by diffuse swelling of the white matter, large subcortical cysts, and megalencephaly with infantile onset. Family studies in several ethnic groups have suggested an autosomal recessive mode of inheritance. We mapped the VL gene to chromosome 22qtel, within a 3-cM linkage interval between markers D22S1161 and n66c4 (maximum LOD score 10.12 at recombination fraction.0, for marker n66c4; maximum multipoint LOD score 17 for this interval) by genome scan of 13 Turkish families. Linkage analysis under the genetic-heterogeneity hypothesis showed no genetic heterogeneity. No abnormalities were found in three tested candidate genes (fibulin-1 and glutathione S-transferases 1 and 2).

Linkage analysis of candidate myelin genes in familial multiple sclerosis.

Multiple sclerosis (MS) is an autoimmune demyelinating disease of the central nervous system. A complex genetic etiology is thought to underlie susceptibility to this disease. The present study was designed to analyze whether differences in genes that encode myelin proteins influence susceptibility to MS. We performed linkage analysis of MS to markers in chromosomal regions that include the genes encoding myelin basic protein (MBP), proteolipid protein (PLP), myelin-associated glycoprotein (MAG), oligodendrocyte myelin glycoprotein (OMGP), and myelin oligodendrocyte glycoprotein (MOG) in a well-characterized population of 65 multiplex MS families consisting of 399 total individuals, 169 affected with MS and 102 affected sibpairs. Physical mapping data permitted placement of MAG and PLP genes on the Genethon genetic map; all other genes were mapped on the Genethon genetic map by linkage analysis. For each gene, at least one marker within the gene and/or two tightly linked flanking markers were analyzed. Marker data analysis employed a combination of genetic trait model-dependent (parametric) and model-independent linkage methods. Results indicate that MAG, MBP, OMGP, and PLP genes do not have a significant genetic effect on susceptibility to MS in this population. As MOG resides within the MHC, a potential role of the MOG gene could not be excluded.

Vocal cord and pharyngeal weakness with autosomal dominant distal myopathy: clinical description and gene localization to 5q31.

Distal myopathy refers to a heterogeneous group of disorders in which the initial manifestations are weakness and atrophy of the hands and feet. We report a family segregating an autosomal dominant distal myopathy, with multiple affected individuals in whom vocal cord and pharyngeal weakness may accompany the distal myopathy, without involvement of the ocular muscles. To our knowledge, this pedigree displays a distinct distal myopathy with the added features of pharyngeal and vocal cord dysfunction (VCPDM) that has not been previously reported. We mapped the MPD2 gene for VCPDM to chromosome 5q within a 12-cM linkage interval between markers D5S458 and D5S1972 in a large pedigree (a maximum LOD score of 12.94 at a recombination fraction of 0 for D5S393) and combined genome screening and DNA pooling successfully adapted to fluorescent markers. This technique provides for the possibility of fully automated genome scans.

Gene sequence, localization, and evolutionary conservation of DAZLA, a candidate male sterility gene.

We have isolated the human homologue of the mouse germ cell-specific transcript Tpx2, which we had previously mapped to mouse chromosome 17. Sequence analysis shows that the human gene is part of the DAZ (Deleted in Azoospermia) family, represents the human homologue of the mouse Dazla and Drosophila boule genes, and is termed DAZLA. Like Dazla and boule, DAZLA is single copy and maps to 3p25. This defines a new region of synteny between mouse chromosome 17 and human chromosome 3. Unlike DAZ, which has multiple DAZ repeats, DAZLA encodes a putative RNA-binding protein with a single RNA-binding motif and a single DAZ repeat. DAZLA is more closely related to Dazla in the mouse than to the Y-linked homologue DAZ (88% identity overall with mouse Dazla compared to 76% identity with the human DAZ protein sequence). Southern blot analysis showed that DAZLA is autosomal in all mammals tested and that DAZ has been recently translocated to the Y chromosome, sometime after the divergence of Old World and New World primates. To investigate the evolutionary relatedness of DAZLA and DAZ further, their partial genomic structures were obtained and compared. This revealed that the genomic organization of both genes in the 5' region is highly conserved. DAZLA is a new member of the DAZ family of genes, which is associated with spermatogenesis and male sterility. Familial cases of male infertility in humans show an autosomal recessive mode of inheritance. It is possible that some of these families may carry mutations in the DAZLA gene.

A complete genomic screen for multiple sclerosis underscores a role for the major histocompatability complex. The Multiple Sclerosis Genetics Group.

Multiple sclerosis (MS), an inflammatory autoimmune demyelinating disorder of the central nervous system, is the most common cause of acquired neurological dysfunction arising in the second to fourth decades of life. A genetic component to MS is indicated by an increased relative risk of 20-40 to siblings compared to the general population (lambda s), and an increased concordance rate in monozygotic compared to dizygotic twins. Association and/or linkage studies to candidate genes have produced many reports of significant genetic effects including those for the major histocompatability complex (MHC; particularly the HLA-DR2 allele), immunoglobulin heavy chain (IgH), T-cell receptor (TCR) and myelin basic protein (MBP) loci. With the exception of the MHC, however, these results have been difficult to replicate and/or apply beyond isolated populations. We have therefore conducted a two-stage, multi-analytical genomic screen to identify genomic regions potentially harbouring MS susceptibility genes. We genotyped 443 markers and 19 such regions were identified. These included the MHC region on 6p, the only region with a consistently reported genetic effect. However, no single locus generated overwhelming evidence of linkage. Our results suggest that a multifactorial aetiology, including both environmental and multiple genetic factors of moderate effect, is more likely than an aetiology consisting of simple mendelian disease gene(s).

Genetics of demyelinating diseases.

Multiple sclerosis (MS), the prototypic demyelinating disease in humans, is the most common cause of acquired neurological dysfunction arising between early to mid adulthood. MS is an inflammatory disorder and is believed to result from an autoimmune response, directed against myelin proteins and perhaps other antigens, resulting in demyelination and dense astrogliosis. A genetic component in MS is indicated by an increased relative risk to siblings compared to the general population (lambda s) of 20-40, and an increased concordance rate in monozygotic compared to dizygotic twins. Association and/or linkage studies to candidate genes have yielded a considerable number of reports showing significant genetic effects for the major histocompatibility complex (MHC), immunoglobulin heavy chain, T cell antigen receptor, and myelin basic protein loci. With the exception of the MHC, however, these results have been difficult to replicate or apply beyond isolated populations. Recently, a multi-analytical genomic screen effort was completed to identify genomic regions potentially harboring MS susceptibility genes. Nineteen such regions were identified. The data confirm the reported genetic effect of the MHC region. However, no single locus generated overwhelming evidence of linkage. These results suggest a multifactorial etiology, including both environmental and multiple genetic factors of moderate effect.

A comprehensive genetic map of the human genome based on 5,264 microsatellites.

The great increase in successful linkage studies in a number of higher eukaryotes during recent years has essentially resulted from major improvements in reference genetic linkage maps, which at present consist of short tandem repeat polymorphisms of simple sequences or microsatellites. We report here the last version of the Généthon human linkage map. This map consists of 5,264 short tandem (AC/TG)n repeat polymorphisms with a mean heterozygosity of 70%. The map spans a sex-averaged genetic distance of 3,699 cM and comprises 2,335 positions, of which 2,032 could be ordered with an odds ratio of at least 1,000:1 against alternative orders. The average interval size is 1.6 cM; 59% of the map is covered by intervals of 2 cM at most and 1% remains in intervals above 10 cM.

Unusual organization of the human T-cell receptor beta-chain gene complex is linked to recombination hotspots.

Two rare Sfi I polymorphisms of 360 kb and 280 kb present within the human T-cell antigen receptor beta-chain gene complex were revealed by pulsed-field gel electrophoresis. They represent allelic variants of the polymorphic 330- and 300-kb Sfi I fragments previously described. The 360-kb polymorphism results from duplication of the 30-kb DNA fragment responsible for the 330/300-kb insertion/deletion-related polymorphism. The 280-kb polymorphism results from a 20-kb deletion from the 300-kb SfiI allele. The rare polymorphisms also map on either side of a Sal I site located near a recombination hotspot, suggesting that germline duplications and deletions arose from nonhomologous crossover events.

Haplotypic origin of beta-chain genes expressed by human T-cell clones.

A contribution of allelic variation of T-cell receptor (Tcr) genes to the immune response has not been studied. Here we report that the presence of insertion-deletion-related polymorphisms (IDRP) of the Tcr beta chain (Tcrb) can be utilized to distinguish the parental origin of the gene complex that undergoes rearrangement in individual T-cell clones. Phytohemagglutinin stimulated clones from an individual heterozygous for an IDRP located between the variable (V) and diversity (D)-joining (J) region genes were studied for the presence of V to DJ rearrangements in each of the two parental chromosomes. Results indicate that single rearrangements were present in the majority of clones, in contrast to the double rearrangements of D to J genes that were generally present. In this individual, V to DJ rearrangement also occurred with different frequencies on each of the two germline genes. IDRP clonotyping of the Tcrb complex should prove generally applicable to the study of the influence of allelic variation of Tcrb genes in selection of the expressed T-cell repertoire.

Fos RNA accumulation in multiple sclerosis white matter tissue.

In order to better characterize the molecular events that accompany lesion development in multiple sclerosis (MS), we studied the accumulation of RNA specific to the nuclear proto-oncogenes c-fos and c-myb in post mortem white matter brain tissue. RNA was prepared from plaque and periplaque regions of 6 different MS brains, from "normal" white matter regions of 3 MS brains and from 6 normal control samples. Quantitation of specific RNA corresponding to each proto-oncogene was performed by Northern blot hybridization and by scanning densitometry. Results indicate a 2-fold increase in c-fos RNA in MS white matter, compared to control tissue. No c-myb signal was identified in any sample. In situ hybridization studies confirmed the selective upregulation of c-fos RNA levels in MS tissue, and suggested that glial cells and not inflammatory cells were responsible for the enhanced c-fos signal. These results suggest that persistent glial cell activation is present within chronic MS lesions irrespective of whether the lesions are active (e.g., inflammatory) or inactive.

Insertion/deletion-related polymorphisms in the human T cell receptor beta gene complex.

Insertion/deletion related polymorphisms (IDRP) involving stretches of 15-30 kb within the human TCR-beta gene complex were revealed by pulse-field gel electrophoresis. Two independent IDRP systems were detected by analysis of Sfi I- and Sal I-digested human DNA samples using probes for TCR C and V region gene segments. The allelic nature of these systems was verified in family studies, and mapping data allowed localization of one area of insertion/deletion among the V gene segments and the other near the C region genes. All but one of 50 individuals tested could be typed for the two allelic systems, and gene frequencies for the two allelic forms were 0.37/0.61 and 0.46/0.54, indicating that these polymorphisms are widespread.

A susceptibility locus for multiple sclerosis is linked to the T cell receptor beta chain complex.

Inheritance of T cell receptor beta chain (TCR beta) genes was analyzed in families of 40 sibling pairs concordant for the relapsing-remitting form of multiple sclerosis (MS). TCR beta haplotypes were determined by segregation analysis of polymorphic markers within the TCR beta complex. The mean proportion of TCR beta haplotypes identical by descent (IBD) inherited by MS sibling pairs was significantly increased compared with expected values (means test, p less than 0.004), whereas the distribution of haplotype sharing was random when MS patients were compared with their unaffected siblings. Furthermore, one allelic form of a TCR beta variable region gene segment was overrepresented on MS chromosomes compared with those parental chromosomes not transmitted to MS offspring both in the MS sibling pair families and in a second group of families containing only one individual affected with MS. These results demonstrate that a gene within the TCR beta complex or a closely linked locus influences susceptibility to MS.

[An XX male newborn infant. A genetic and endocrinologic study]. / Nouveau-né mâle XX. Etude génétique et endocrinienne.

The second child of a non consanguineous couple had a male phenotype with two intrascrotal testes of normal size however a scrotum bifidum was noted. The karyotype of the child was 46 XX and the parents one's was normal. No Y specific sequence was detected by using four Y specific probes (47 B, 12 F3, 52 D and 118). During the first semester of life, hormonal investigations showed a normal testicular function.

Testis-specific transcripts detected by a human Y-DNA-derived probe.

A genomic sequence (12f3), derived from the long arm of the human Y chromosome, detects a 1.6 kb mRNA, expressed in human and mouse testis, but not in other tissues tested by Northern blot analysis. Using 12f3 as a probe, a mouse cDNA, designated PL5, was isolated from an adult mouse testis cDNA library. The profile obtained by Southern blot analysis using PL5 as probe under high-stringency conditions, reveals that 12f3 probably represents a Y-located pseudogene which was derived from an autosomally located gene. Southern blot analysis of different vertebrate species, using probe PL5, shows that this gene has been highly conserved during evolution. Preliminary in situ hybridizations on testis tissue sections indicate that PL5 is expressed during the postmeiotic stages of male germ cell differentiation and thus may play a role during spermatogenesis. A second cDNA, also obtained from the testis cDNA library, weakly cross-reacts with 12f3. This cDNA, designated PL10, detects a mRNA of approximately 4 kb which is highly expressed in mouse testis, but not in male or female mouse liver. The gene corresponding to this cDNA is also well conserved among vertebrates.