Harvesting the human genome: the Israeli perspective.

The post-genome era is at our door, and soon the complete human genome sequence will be available for the next set of goals. Israel is well equipped and skilled to join the worldwide harvest of the human genome, but additional massive government investment is required. This will affect various domains of activity, including the fields of diagnostics and therapeutics. The technologies and know-how described above constitute the basis for future human genome applications in Israel.

Deafness heterogeneity in a Druze isolate from the Middle East: novel OTOF and PDS mutations, low prevalence of GJB2 35delG mutation and indication for a new DFNB locus.

About 60% of congenital hearing impairment cases in developed countries are due to genetic defects. Data on the molecular basis of hereditary hearing reflects vast genetic heterogeneity. There are >400 disorders in which hearing impairment is one of the characteristic traits of a syndrome. Linkage studies have identified more than 40 human chromosomal loci associated with non-syndromic hearing loss. So far, 16 of these 40 non-syndromic hearing impairment genes have been identified. We have studied the molecular basis of hearing impairment in four Druze families from the same village in Northern Galilee. The Druze are a small, isolated population in the Middle East practising endogamous marriage. Thus it was expected that a single mutation would account for hearing impairments in all these families. Our results show that at least four different genes are involved. Hearing impairment was caused in one family by a novel mutation in the recently identified OTOF (the DFNB9 gene), by a novel Pendred syndrome mutation (Thr193Ile) in another family, and by a GJB2 mutation (35delG also known as 30delG) in the third family. In the fourth family linkage was excluded from all known hearing impairments loci (recessive and dominant) as well as from markers covering chromosomes 11-22, pointing therefore to the existence of another non-syndromic recessive hearing loss (NSRD) locus on chromosomes 1-10.

Three novel mutations and twelve polymorphisms identified in the USH2A gene in Israeli USH2 families.

The Usher syndromes are autosomal recessive hereditary disorders characterized by hearing impairment and progressive visual loss due to Retinitis Pigmentosa (RP). Moderate to severe sensorineural hearing loss and progressive RP characterizes Usher syndrome type IIa (USH2A), which maps to the long arm of chromosome 1q41. Recently, three deletions carried by USH2 patients, which were found in a novel gene isolated from the critical 1q41 region, defined this gene as responsible for USH2A. The USH2A gene is predicted to encode a 1546 amino acid protein which possesses domains that are observed in basal lamina and extracellular matrix proteins and in cell adhesion molecules. Affected individuals and additional members from eleven USH2 Israeli families of diverse ethnic origin were screened for the presence of changes in all 20 coding exons of the USH2A gene. Three novel mutations (239-242insCGTA, R334W, T1515M) were identified in three families of Jewish Moroccan and Jewish Iranian origins. Twelve polymorphisms were found in the families, four of which are novel. None of the known USH2 mutations were identified in the families studied in this work. Hum Mutat 15:388, 2000.

Usher syndrome in the Samaritans: strengths and limitations of using inbred isolated populations to identify genes causing recessive disorders.

We have previously reported significant linkage between markers on 11q13.5 and Usher syndrome type 1 (USH1B) in a large Samaritan kindred. USH1B is an autosomal recessive disease characterized by profound congenital sensorineural deafness, vestibular dysfunction and progressive visual loss. A unique haplotype found only in all USH1B carriers and affected individuals implied that the disease-causing mutation probably entered the community from a single founder. Screening for mutations in a gene called GARP, which was mapped to the same genetic interval as USH1B, revealed a base substitution in the coding region of the gene, in a homozygous state in all affected individuals. This base substitution, which results in an arginine to tryptophane change, is not found in control individuals and occurs at an amino acid residue that is conserved across species, including mouse, gorilla, chimpanzee and macaque. This study emphasizes the strength of using an isolated inbred population for efficient identification of the primary linkage and for narrowing the disease interval, but also demonstrates its limitations in distinguishing between mutations causing the disease and those representing unique and private polymorphisms.

Mutation profile of all 49 exons of the human myosin VIIA gene, and haplotype analysis, in Usher 1B families from diverse origins.

Usher syndrome types I (USH1A-USH1E) are a group of autosomal recessive diseases characterized by profound congenital hearing loss, vestibular areflexia, and progressive visual loss due to retinitis pigmentosa. The human myosin VIIA gene, located on 11q14, has been shown to be responsible for Usher syndrome type 1B (USH1B). Haplotypes were constructed in 28 USH1 families by use of the following polymorphic markers spanning the USH1B locus: D11S787, D11S527, D11S1789, D11S906, D11S4186, and OMP. Affected individuals and members of their families from 12 different ethnic origins were screened for the presence of mutations in all 49 exons of the myosin VIIA gene. In 15 families myosin VIIA mutations were detected, verifying their classification as USH1B. All these mutations are novel, including three missense mutations, one premature stop codon, two splicing mutations, one frameshift, and one deletion of >2 kb comprising exons 47 and 48, a part of exon 49, and the introns between them. Three mutations were shared by more than one family, consistent with haplotype similarities. Altogether, 16 USH1B haplotypes were observed in the 15 families; most haplotypes were population specific. Several exonic and intronic polymorphisms were also detected. None of the 20 known USH1B mutations reported so far in other world populations were identified in our families.