Back mutation can produce phenotype reversion in Bloom syndrome somatic cells.

A unique and constant feature of Bloom syndrome (BS) cells is an excessive rate of sister-chromatid exchange (SCE). However, in approximately 20% of persons with typical BS, mosaicism is observed in which a proportion of lymphocytes (usually a small one) exhibits a low-SCE rate. Persons with such mosaicism predominantly are genetic compounds for mutation at BLM, and the low-SCE lymphocytes are the progeny of a precursor cell in which intragenic recombination between the two sites of BLM mutation had generated a normal allele. Very exceptionally, however, persons with BS who exhibit mosaicism are homozygous for the causative mutation. In two such exceptional homozygous persons studied here, back mutation has been demonstrated: one person constitutionally was homozygous for the mutation 1544insA and the other for the mutation 2702G-->A. Revertant (low-SCE) lymphoblastoid cells in each person were heterozygous for their mutations, i.e., a normal allele was now present. The normal alleles must have arisen by back mutation in a precursor cell, in one person by the deletion of an A base and, in the other, the nucleotide substitution of a G base for an A base. Thus, back mutation now becomes, together with intragenic recombination, an important genetic mechanism to consider when explaining examples of a reversion of somatic cells to "normal" in persons with a genetically determined abnormal phenotype.

The Ashkenazic Jewish Bloom syndrome mutation blmAsh is present in non-Jewish Americans of Spanish ancestry.

Bloom syndrome (BS) is more frequent in the Ashkenazic Jewish population than in any other. There the predominant mutation, referred to as "blmAsh," is a 6-bp deletion and 7-bp insertion at nucleotide position 2281 in the BLM cDNA. Using a convenient PCR assay, we have identified blmAsh on 58 of 60 chromosomes transmitted by Ashkenazic parents to persons with BS. In contrast, in 91 unrelated non-Ashkenazic persons with BS whom we examined, blmAsh was identified only in 5, these coming from Spanish-speaking Christian families from the southwestern United States, Mexico, or El Salvador. These data, along with haplotype analyses, show that blmAsh was independently established through a founder effect in Ashkenazic Jews and in immigrants to formerly Spanish colonies. This striking observation underscores the complexity of Jewish history and demonstrates the importance of migration and genetic drift in the formation of human populations.

The use of conversational repair strategies by children who are deaf.

The investigation examined conversational repair strategies of deaf and hearing children in response to a partner's indication of communication breakdown. Eight profoundly deaf children who used total communication were compared with eight hearing children; the children were matched by age and sex. Each child was videotaped engaging in two language sample elicitation activities--one structured, one informal. An investigator initiated 10 stacked clarification request sequences consisting of three neutral requests--"Huh?"; "What?"; "I don't understand"--per sequence. Language samples from the sequences were transcribed; repair response types were coded. Frequencies and percentages of occurrence were derived for each request type in each repair category and for each language condition. Deaf and hearing children employed different repair strategies. Deaf children were more likely to revise utterances; hearing children were as likely to repeat utterances as to revise, and were more likely to provide cue repairs. No significant differences were noted when communication conditions were compared. When facing communication breakdown, deaf children persisted effectively in clarifying utterances.

Physical mapping of the bloom syndrome region by the identification of YAC and P1 clones from human chromosome 15 band q26.1.

The gene for Bloom syndrome (BLM) has been mapped to human chromosome 15 band q26.1 by homozygosity mapping. Further refinement of the location of BLM has relied upon linkage-disequilibrium mapping and somatic intragenic recombination. In combination with these mapping approaches and to identify novel DNA markers and probes for the BLM candidate region, a contiguous representation of the 2-Mb region that contains the BLM gene was generated and is presented here. YAC and P1 clones from the region have been identified and ordered by using previously available genetic markers in the region along with newly developed sequence-tagged sites from radiation-reduced hybrids, polymorphic dinucleotide repeat loci, and end sequences of YACs and P1s. A long-range restriction map of the 2-Mb region that allowed estimation of the distance between polymorphic microsatellite loci is also reported. This map and the DNA markers derived from it were instrumental in the recent identification of the BLM gene.

The Bloom's syndrome gene product is homologous to RecQ helicases.

The Bloom's syndrome (BS) gene, BLM, plays an important role in the maintenance of genomic stability in somatic cells. A candidate for BLM was identified by direct selection of a cDNA derived from a 250 kb segment of the genome to which BLM had been assigned by somatic crossover point mapping. In this novel mapping method, cells were used from persons with BS that had undergone intragenic recombination within BLM. cDNA analysis of the candidate gene identified a 4437 bp cDNA that encodes a 1417 amino acid peptide with homology to the RecQ helicases, a subfamily of DExH box-containing DNA and RNA helicases. The presence of chain-terminating mutations in the candidate gene in persons with BS proved that it was BLM.