Fragile X syndrome, one of the most common human genetic diseases, is characterized by a unique genetic mechanism which involves dynamic mutation in a heritable unstable DNA sequence, a p(CCG)n repeat, in the FRAXA locus. It has recently been suggested that a few founder chromosomes are responsible for most fragile X mutations in the Caucasian population. In order to investigate the origin of the fragile X mutations in the Japanese population, we analyzed haplotypes of the FRAXA locus in 40 unrelated fragile X chromosomes and 142 normal X chromosomes in Japanese males, by using two polymorphic AC repeats, FRAXAC1 and FRAXAC2, which flank the fragile site. This analysis provided evidence for founder fragile X chromosomes in the Japanese population, similar to that in Caucasians, although different haplotypes are involved. The distribution of normal allele size of the p(CCG)n repeat among the X chromosomes in the Japanese population is very similar to that reported for Caucasians, except that the most frequent copy number (n = 28) is one copy less than that in Caucasians and that there is an additional peak at 35 copies. There is significant correlation between FRAXAC alleles and the p(CCG)n repeat copy number in non-fragile X chromosomes, however, alleles with more than 31 copies of the p(CCG)n repeat do not segregate with either of the fragile X common FRAXAC haplotypes.
A tiny interstitial deletion of 7p was found in a 5-month-old boy with a craniosynostosis and many anomalies. His karyotype was 46,XY,del(7)(p15.3p21.3). Here we present not only further evidence of an association between craniosynostosis and 7p monosomy, but also deletion mapping to indicate that the critical segment for craniosynostosis lies in the mid-portion of 7p21, that is at 7p21.2 or the proximal part of 7p21.3.
To localize the human deoxyribonuclease I (DNase I) gene, DNASE1 (DNL1), we performed a polymerase chain reaction (PCR) using DNA extracted from a panel of cloned human × rodent hybrid cell lines carrying different human chromosomes and screened for the presence of the expected PCR products. Two different sets of oligonucleotide primers specific for human DNase I cDNA sequences were used to amplify unique fragments in the human DNase I gene. Based on this work, DNL1 could be assigned to human chromosome 16. Furthermore, regional localization of the gene to 16p13.3 was performed by PCR analysis of a high-resolution mouse × human somatic cell hybrid panel that contained defined portions of human chromosome 16.
SUMMARYWe report a malformed girl with a single chromosome band deletion of 4q26 in peripheral lymphocytes. This patient is the fourth case reported with an interstitial deletion involving 4q26 and has the smallest deletion of those reported. Deletion mapping indicates that psychomotor retardation, coloboma, prominent forehead, epicanthus, broad based nose, and broad, thin upper lip are associated with monosomy 4q26, and that gene(s) associated with Rieger syndrome can be excluded from the 4q26 segment.To our knowledge there have been only three previously described cases of interstitial deletion 4q involving q26,'-3 although more than 20 cases of terminal deletion have been reported. We present here a malformed girl with a tiny interstitial deletion of 4q. The deletion involves only one band, 4q26, a very small part of chromosome 4.
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