Mutation of a gene encoding a protein with extracellular matrix motifs in Usher syndrome type IIa

Usher syndrome type IIa (OMIM 276901), an autosomal recessive disorder characterized by moderate to severe sensorineural hearing loss and progressive retinitis pigmentosa, maps to the long arm of human chromosome 1q41 between markers AFM268ZD1 and AFM144XF2. Three biologically important mutations in Usher syndrome type IIa patients were identified in a gene (USH2A) isolated from this critical region. The USH2A gene encodes a protein with a predicted size of 171.5 kilodaltons that has laminin epidermal growth factor and fibronectin type III motifs; these motifs are most commonly observed in proteins comprising components of the basal lamina and extracellular matrixes and in cell adhesion molecules.     

Localization of the Usher syndrome type ID gene (Ush1D) to chromosome 10

The Usher syndromes (USH) are a group of autosomal recessive diseases characterized by progressive pigmentary retinopathy and sensorineural hearing loss. Five USH genes have been mapped and at least one additional gene is known to exist. By homozygosity mapping in a consanguineous family, a sixth USH gene has been localized. Clinical findings in the four affected children are consistent with established diagnostic criteria for Ush1. Linkage to known USH loci was excluded, and using two genomic DNA pools, one from the affected children and the other from the parents, 161 polymorphic markers evenly spaced across the autosomal human genome were screened. The location of the Ush1D gene was defined by the only region showing homozygosity by descent in the affected siblings, a 15 cM interval on chromosome 10q bounded by D10S529 and D10S573.     

MALT lymphoma of labial minor salivary gland in an immunocompetent child with a gastric Helicobacter pylori infection

Autosomal recessive nonsyndromic sensorineural deafness segregating in a large consanguineous Indian family was mapped to chromosome 11p14-p15.1 defining a new locus, DFNB18. A maximum lod score of 4.4 at theta = 0 was obtained for the polymorphic micro-satellite marker D11S1888. Haplotype analysis localizes this gene between markers D11S1307 and D11S2368, which is approximately 1.6 cM and encompasses the region of Usher syndrome type 1C (USH1C). We postulate that DFNB18 and USH1C are allelic variants of the same gene.     

Histamine sustains fMLP-stimulated leukocyte adhesion in rat mesenteric venules in vivo

Hereditary non-syndromic profound deafness affects about 1 in 2000 children prior to language acquisition. In 80% of the cases, the mode of transmission is autosomal recessive. The number of genes involved in these recessive forms of isolated deafness (DFNB genes) has been estimated to between 30 and 100. So far, ten DFNB genes have been mapped to human chromosomes, one of which has been isolated. By linkage analysis of a single family whose members were affected with profound deafness, some of them presenting with vestibular dysfunction, DFNB2 has been mapped to chromosome 11q13 (ref. 3). The gene responsible for a form of Usher syndrome type I, USH1B, has been assigned to the same chromosomal region. Usher syndrome associates profound congenital deafness and vestibular dysfunction with retinitis pigmentosa. In the homologous murine region are located the shaker-1 mutations responsible for deafness and vestibular dysfunction. It has been demonstrated that the murine shaker-1 and human USH1B phenotypes result from mutations in the gene encoding myosin-VIIA. Based on mapping data as well as on the similarities between the phenotypes of DFNB2-affected patients and shaker-1 mouse mutants, we have proposed that a defective myosin-VIIA may also be responsible for DFNB2 (ref. 1). Sequence analysis of each of the coding exons of the myosin-VIIA gene (MYO7A) was thus undertaken in the DFNB2-affected family. In the last nucleotide of exon 15, a G to A transition was detected, a type of mutation that is known to decrease the efficiency of splicing. Accordingly, this result shows that different mutations in MYO7A result in either an isolated or a syndromic form of deafness.     

Bovine IgG2a antibodies to Haemophilus somnus and allotype expression

AIMS/BACKGROUND: To characterise clinically a large kindred segregating retinitis pigmentosa and sensorineural hearing impairment in an autosomal dominant pattern and perform genetic linkage studies in this family. Extensive linkage analysis in this family had previously excluded the majority of loci shown to be involved in the aetiologies of RP, some other forms of inherited retinal degeneration, and inherited deafness. METHODS: Members of the family were subjected to detailed ophthalmic and audiological assessment. In addition, some family members underwent skeletal muscle biopsy, electromyography, and electrocardiography. Linkage analysis using anonymous microsatellite markers was performed on DNA samples from all living members of the pedigree. RESULTS: Patients in this kindred have a retinopathy typical of retinitis pigmentosa in addition to a hearing impairment. Those members of the pedigree examined demonstrated a subclinical myopathy, as evidence by abnormal skeletal muscle histology, electromyography, and electrocardiography. LOD scores of Zmax = 3.75 (theta = 0.10), Zmax = 3.41 (theta = 0.10), and Zmax = 3.25 (theta = 0.15) respectively were obtained with the markers D9S118, D9S121, and ASS, located on chromosome 9q34-qter, suggesting that the causative gene in this family may lie on the long arm (q) of chromosome 9. CONCLUSIONS: These data indicate that the gene responsible for the phenotype in this kindred is located on chromosome 9 q. These data, together with evidence that a murine deafness gene is located in a syntenic area of the mouse genome, should direct the research community to consider this area as a candidate region for retinopathy and/or deafness genes.     

Stable and progressive hearing loss in type 2A Usher's syndrome

Audiograms were traced or additionally performed on 23 Usher's syndrome patients in 10 Dutch multi-affected families, all linked to chromosome 1q (USH2A locus). Serial audiograms, available in 13 patients, were used for a regression analysis of binaural pure tone average on age (follow-up, 9 to 32 years) to test for "significant progression," ie, a significant regression coefficient, here called the "annual threshold increase" (ATI, expressed in decibels per year). A significant ATI (> 1 dB/y) was observed in 3 patients. Analysis of variance of ATI demonstrated significant heterogeneity; hearing loss was either stable or progressive. This implies a significant clinical heterogeneity. A similar analysis performed on our progressive USH2A cases and "type III" cases previously reported by others (ATI of 1 to 5 dB/y), some of which were recently linked to chromosome 3q (USH3 locus), failed to show any significant heterogeneity in the progression of hearing loss.     

The Bjornstad syndrome (sensorineural hearing loss and pili torti) disease gene maps to chromosome 2q34-36

We report that the Bjornstad syndrome gene maps to chromosome 2q34-36. The clinical association of sensorineural hearing loss with pili torti (broken, twisted hairs) was described >30 years ago by Bjornstad; subsequently, several small families have been studied. We evaluated a large kindred with Bjornstad syndrome in which eight members inherited pili torti and prelingual sensorineural hearing loss as autosomal recessive traits. A genomewide search using polymorphic loci demonstrated linkage between the disease gene segregating in this kindred and D2S434 (maximum two-point LOD score = 4.98 at theta = 0). Haplotype analysis of recombination events located the disease gene in a 3-cM region between loci D2S1371 and D2S163. We speculate that intermediate filament and intermediate filament-associated proteins are good candidate genes for causing Bjornstad syndrome.     

Genetic mapping of the copper toxicosis locus in Bedlington terriers to dog chromosome 10, in a region syntenic to human chromosome region 2p13-p16

Abnormal hepatic copper accumulation is recognized as an inherited disorder in man, mouse, rat and dog. The major cause of hepatic copper accumulation in man is a dysfunctional ATP7B gene, causing Wilson disease (WD). Mutations in the ATP7B genes have also been demonstrated in mouse and rat. The ATP7B gene has been excluded in the much rarer human copper overload disease non-Indian childhood cirrhosis, indicating genetic heterogeneity. By investigating the common autosomal recessive copper toxicosis (CT) in Bedlington terriers, we have identified a new locus involved in progressive liver disease. We examined whether the WD gene ATP7B was also causative for CT by investigating the chromosomal co-localization of ATP7B and C04107, using fluorescence in situ hybridization (FISH). C04107 is an anonymous microsatellite marker closely linked to CT. However, BAC clones containing ATP7B and C04107 mapped to the canine chromosome regions CFA22q11 and CFA10q26, respectively, demonstrating that WD cannot be homologous to CT. The copper transport genes CTR1 and CTR2 were also excluded as candidate genes for CT since they both mapped to canine chromosome region CFA11q22. 2-22.5. A transcribed sequence identified from the C04107-containing BAC was found to be homologous to a gene expressed from human chromosome 2p13-p16, a region devoid of any positional candidate genes.     

HIV-1 viral load: comparative evaluation of three commercially available assays in Argentina

Autosomal recessive nonsyndromic hearing loss (ARNSHL) is the most common form of hereditary hearing impairment (HHI). To date, 16 different loci have been reported, making ARNSHL an extremely heterogeneous disorder. One of these loci, DFNB4, was mapped to a 5-cM interval of 7q31 in a large Middle-Eastern Druze family. This interval also includes the gene for Pendred syndrome. We report on three new families with HHI from the Madras region of southern India that demonstrate linkage to 7q. Their pedigrees are compatible with autosomal recessive inheritance. Furthermore, the largest family identifies a novel locus (DFNB17) telomeric to the DFNB4 and Pendred intervals. A 3-cM region of homozygosity by descent between markers D7S486 and D7S2529 is present in all affected individuals in this family and generates a multipoint LOD score of 4.24. The two other families map to the previously reported DFNB4 region but have insufficient power to attain significant LOD scores. However, mutations in the Pendred syndrome gene are present in one of these families.     

Ophthalmologic findings in Usher syndrome type 2A

Thirty-seven patients, comprising 24 familial cases and 13 isolated patients with Usher syndrome type II (USH2), underwent ophthalmologic examination. Based on the degree of hearing loss, normal vestibular function, and gene-linkage analysis, familial cases were assumed to have USH2A. An analysis of genetic heterogeneity failed to reveal the presence of a second locus in the Dutch population. Although the patients appear to belong to a genetically homogeneous group, remarkable ophthalmologic variability was found. Corrected visual acuity decreased with age and remarkable differences in visual acuity were found within one family. Fundoscopic findings were classified as type A if attenuated vessels and bone corpuscles in all quadrants were found or as type B if findings other than these were found. The prevalence of type A significantly increased with age.     

A missense mutation of mouse OCTN2, a sodium-dependent carnitine cotransporter, in the juvenile visceral steatosis mouse

Carnitine is an essential cofactor for the mitochondrial beta-oxidation of long-chain fatty acids. The juvenile visceral steatosis (JVS) mouse, an animal model of systemic carnitine deficiency, is inherited in an autosomal recessive manner. Recently, a human OCTN2 gene encoding a sodium-dependent carnitine cotransporter was isolated and mapped to human chromosome 5q31. Since the mouse jvs locus was assigned to the region of chromosome 11 where it is syntenic to human chromosome 5q31, we isolated the mouse octn2 gene and screened for its mutation in the jvs mouse. DNA sequencing analysis disclosed a missense mutation from CTG (Leu) to CGG (Arg) at codon 352 located within the sixth transmembrane domain of octn2. This amino acid replacement possibly causes the conformational change of the protein that leads to dysfunction of the gene product. Hence, we conclude that octn2 is a candidate gene responsible for the JVS mouse.     

A major gene affecting age-related hearing loss in C57BL/6J mice

A major gene responsible for age-related hearing loss (AHL) in C57BL/6J mice was mapped by analyses of a (C57BL/6J x CAST/Ei) x C57BL/6J backcross. AHL, as measured by elevated auditory-evoked brainstem response (ABR) thresholds, segregated among backcross mice as expected for a recessive, primarily single-gene trait. Both qualitative and quantitative linkage analyses gave the same genetic map position for the AHL gene (Ahl on chromosome 10, near D10Mit5. Marker assisted selection was then used to produce congenic lines of C57BL/6J that contain different CAST-derived segments of chromosome 10. ABR test results and cochlear histopathology of aged progenitors of these congenic lines are presented. Ahl is the first gene causing late-onset, non-syndromic hearing loss that has been reported in the mouse.     

A microtiter plate assay for cytochrome c oxidase in permeabilized whole cells

A new mouse retinal degeneration that appears to be an excellent candidate for modeling human retinitis pigmentosa is reported. In this degeneration, called rd-3, differentiation proceeds postnatally through 2 weeks, and photoreceptor degeneration starts by 3 weeks. The rod photoreceptor loss is essentially complete by 5 weeks, whereas remnant cone cells are seen through 7 weeks. This is the only mouse homozygous retinal degeneration reported to date in which photoreceptors are initially normal. Crosses with known mouse retinal degenerations rd, Rds, nr, and pcd are negative for retinal degeneration in offspring, and linkage analysis places rd-3 on mouse chromosome 1 at 10 +/- 2.5 cM distal to Akp-1. Homology mapping suggests that the homologous human locus should be on chromosome 1q.     

Fine genetic mapping defines the genetic order of Pax9, Tcf3a, and Acrodysplasia (Adp)

We present here the fine genetic mapping of the proximal part of mouse Chromosome (Chr) 12 between D12Mit54 and D12Mit4. This chromosomal region contains three loci, Pax9, Tcf3a, and Acrodysplasia (Adp), which seem to play an important role in pattern formation during mouse embryogenesis. The Adp mutation, which was created by transgene integration, causes skull, paw, and tail deformities. Pax9, which is expressed in the face, paws, and tail, once qualified as a possible candidate for the Adp locus. We analyzed 997 interspecific backcross progeny for recombination between the markers D12Mit54 and D12Mit4; we recovered 117 recombinants, which were further typed for Pax9, Tcf3a, Adp, D12Mit88, D12Nds1, D12Mit36, and D12Mit34. This study represents the first instance in which all the above loci have been included in a single analysis, thereby allowing unambiguous determination of the genetic order and distance between D12Mit54 and D12Mit4. From our results, we conclude that the Adp locus is distinct from either Pax9 or Tcf3a.     

Refinement of two chromosome 11q regions of loss of heterozygosity in ovarian cancer

Loss of heterozygosity on chromosome 11q23.3-qter is a frequent event in ovarian carcinoma, implying the existence of an important ovarian tumor suppressor gene(s) within the region. To refine a minimum region(s) of loss, 67 ovarian tumors were analyzed for loss of heterozygosity with eight microsatellite markers spanning 11q23.3-qter. Forty tumors (61%) demonstrated allelic losses. Twenty-seven of these had allelic losses on only part of 11q23.3, which enabled the identification of two distinct regions likely to harbor ovarian tumor suppressor genes. The proximal region, flanked by markers D11S925 and D11S1336, is less than two megabases while the second more distal region, flanked by markers D11S912 and D11S439, is approximately eight megabases. The refinement of these candidate tumor suppressor gene loci will facilitate future loss of heterozygosity studies and enable the isolation of candidate genes from these regions.     

A Bedouin kindred with infantile nephronophthisis demonstrates linkage to chromosome 9 by homozygosity mapping

A novel type of infantile nephronophthisis was identified in an extended Bedouin family from Israel. This disease has an autosomal recessive mode of inheritance, with the phenotypic presentation ranging from a Potter-like syndrome to hyperechogenic kidneys, renal insufficiency, hypertension, and hyperkalemia. Affected individuals show rapid deterioration of kidney function, leading to end-stage renal failure within 3 years. Histopathologic examination of renal tissue revealed variable findings, ranging from infantile polycystic kidneys to chronic tubulointerstitial nephritis, fibrosis, and cortical microcysts. A known familial juvenile nephronophthisis locus on chromosome 2q13 and autosomal recessive polycystic kidney disease on chromosome 6p21.1-p12 were excluded by genetic linkage analysis. A genomewide screen for linkage was conducted by searching for a locus inherited by descent in all affected individuals. Pooled DNA samples from parents and unaffected siblings and individual DNA samples from four affected individuals were used as PCR templates with trinucleotide- and tetranucleotide-repeat polymorphic markers. Using this approach, we identified linkage to infantile nephronophthisis for markers on chromosome 9q22-31. The disorder maps to a 12.9-cM region flanked by markers D9S280 and GGAT3G09.     

Retinitis pigmentosa inversa

BACKGROUND: Retinitis pigmentosa (RP) is one of the most common inherited retinal diseases, with a prevalence of about 1 in 3500 to 4500. Retinitis pigmentosa inversa is a rare variant of this disorder characterized by areas of choroidal degeneration with pigment migration and bony spicule formation in the macular area. In contrast to more typical forms of RP, this anomaly destroys central vision, leaving peripheral vision intact. CASE REPORT: A 47-year-old white male was followed for about 7 years with evidence of progressive retinal pigment epithelial atrophy and hyperpigmentation affecting both maculae. Since 1970, he had noted difficulty seeing at night as well as an acquired hearing deficit that appeared to be getting worse, ultimately impairing his ability to safely drive a truck. Medical history was positive for either chloroquine or hydroxychloroquine use for 2 to 3 years as malaria prophylaxis while he served in Vietnam. In addition, his father in Louisiana had visual loss of unknown cause. During the 7-year period, the condition progressed rapidly. The patient became virtually blind secondary to visual acuity loss with dense central and paracentral scotomas. The peripheral visual fields remained intact. After several years of extensive examinations, including laboratory, electroretinography, and genetic testing, a definitive diagnosis of RP inversa was made. DISCUSSION: RP inversa is a rare form of tapetoretinal degeneration that is characterized by decreased central vision with normal peripheral vision. A recessive form of inheritance has been postulated but never substantiated. Although there is currently no treatment, recent studies have indicated that 15,000 IU of vitamin A palmitate daily may slow the progression of retinitis pigmentosa; however, it is unknown whether this treatment would be effective for the inverse form of RP. Differential diagnoses include Leber's congenital amaurosis, central gyrate atrophy, central areolar choroidal sclerosis, progressive cone-rod dystrophy, syphilitic retinopathy, retinal toxicity from phenothiazine use, and chloroquine/hydroxychloroquine retinopathy.