Charcot-Marie-Tooth disease type 1A (CMT1A) is an autosomal dominant peripheral neuropathy associated with a large DNA duplication on the short arm of human chromosome 17. The trembler (Tr) mouse serves as a model for CMT1A because of phenotypic similarities and because the Tr locus maps to mouse chromosome 11 in a region of conserved synteny with human chromosome 17. Recently, the peripheral myelin gene Pmp-22 was found to carry a point mutation in Tr mice. We have isolated cDNA and genomic clones for human PMP-22. The gene maps to human chromosome 17p11.2-17p12, is expressed at high levels in peripheral nervous tissue and is duplicated, but not disrupted, in CMT1A patients. Thus, we suggest that a gene dosage effect involving PMP-22 is at least partially responsible for the demyelinating neuropathy seen in CMT1A.
Smith-Magenis syndrome (SMS) is caused by an interstitial deletion of chromosome band 17p11.2 averaging 4-5 Mb. This deletion is likely to contain a large number of genes, each of which could potentially contribute toward the clinical phenotype. We report that the gene for topoisomerase III (hTOP3) is commonly deleted in SMS patients and maps between D17S447 and D17S258 on the short arm of chromosome 17. Cellular studies of SMS patient lymphoblasts and their respective parental cell lines were undertaken to determine the consequences of haploinsufficiency of hTOP3. Our studies indicate that hemizygosity for hTOP3 does not appreciably affect cell-cycle kinetics or activation of ionizing radiation-sensitive cell-cycle checkpoints. Furthermore, the induction of apoptosis in response to ionizing radiation in SMS and parental cells was similar. Our studies suggest that haploinsufficiency of hTOP3 does not have a major impact on the behavior of cells from SMS patients and may not play a significant role in the SMS phenotype.
Smith-Magenis syndrome (SMS) is caused by an interstitial deletion of chromosome band 17p11.2 averaging 4-5 Mb. This deletion is likely to contain a large number of genes, each of which could potentially contribute toward the clinical phenotype. We report that the gene for topoisomerase III (hTOP3) is commonly deleted in SMS patients and maps between D17S447 and D17S258 on the short arm of chromosome 17. Cellular studies of SMS patient lymphoblasts and their respective parental cell lines were undertaken to determine the consequences of haploinsufficiency of hTOP3. Our studies indicate that hemizygosity for hTOP3 does not appreciably affect cell-cycle kinetics or activation of ionizing radiation-sensitive cell-cycle checkpoints. Furthermore, the induction of apoptosis in response to ionizing radiation in SMS and parental cells was similar. Our studies suggest that haploinsufficiency of hTOP3 does not have a major impact on the behavior of cells from SMS patients and may not play a significant role in the SMS phenotype.
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