Different somatic and germline HPRT1 mutations promote use of a common, cryptic intron 1 splice site. Mutation in brief no. 259. Online.

Aberrant hypoxanthine phosphoribosyltransferase (HUGO-approved gene symbol HPRT1; MIM# 308000) RNA splicing promoted by splice site mutation or loss is a common mechanism for loss of the purine salvage enzyme HPRT1 from human cells. We report here two in vivo somatic HPRT1 mutations in human kidney tubular epithelial cells that disrupt HPRT1 intron 1 splicing and lead to the inclusion of intron 1 sequence in mature mRNA. Analysis of these mutations and of 14 additional HPRT1 intron 1 inclusion mutations provides an explanation for use of a common, cryptic intron 1 splice donor site by all 16 mutations.

Different somatic and germline HPRT1 mutations promote use of a common, cryptic intron 1 splice site. Mutations in brief no. 246. Online.

Aberrant hypoxanthine phosphoribosyltransferase (HUGO-approved gene symbol HPRT1; MIM# 308000) mRNA splicing, promoted by splice site mutation or loss, is a common mechanism for loss of the purine salvage enzyme HPRT1 from human cells. We report here two in vivo somatic HPRT1 mutations in human kidney tubular epithelial cells that disrupt HPRT1 intron 1 splicing and lead to the inclusion of intron 1 sequence. We propose an explanation for the use of a common, cryptic intron 1 splice donor site by these two mutations, and by 14 additional human HPRT1 mutations that lead to aberrant splicing with the incorporation of intron 1 sequence into mRNA.

Generation of highly site-specific DNA double-strand breaks in human cells by the homing endonucleases I-PpoI and I-CreI.

We have determined the ability of two well-characterized eukaryotic homing endonucleases, I-PpoI from the myxomycete Physarum polycephalum and I-CreI from the green alga Chlamydomonas reinhardtii, to generate site-specific DNA double-strand breaks in human cells. These 18-kDa proteins cleave highly conserved 15- or 24-bp rDNA homing sites in their respective hosts to generate homogeneous 4-base, 3' ends that initiate target intron transposition or "homing." We show that both endonucleases can be expressed in human cells and can generate site-specific DNA double-strand breaks in 28S rDNA and homing site plasmids. These endonuclease-induced breaks can be repaired in vivo, although break repair is mutagenic with the frequent generation of short deletions or insertions. I-PpoI and I-CreI should be useful for analyzing DNA double-strand break repair in human cells and rDNA.

Nucleotide sequence analysis of human hypoxanthine phosphoribosyltransferase (HPRT) gene deletions.

We have determined the nucleotide sequences of 10 intragenic human HPRT gene deletion junctions isolated from thioguanine-resistant PSV811 Werner syndrome fibroblasts or from HL60 myeloid leukemia cells. Deletion junctions were located by fine structure blot hybridization mapping and then amplified with flanking oligonucleotide primer pairs for DNA sequence analysis. The junction region sequences from these 10 HPRT mutants contained 13 deletions ranging in size from 57 bp to 19.3 kb. Three DNA inversions of 711, 368, and 20 bp were associated with tandem deletions in two mutants. Each mutant contained the deletion of one or more HPRT exon, thus explaining the thioguanine-resistant cellular phenotype. Deletion junction and donor nucleotide sequence alignments suggest that all of these HPRT gene rearrangements were generated by the nonhomologous recombination of donor DNA duplexes that share little nucleotide sequence identity. This result is surprising, given the potential for homologous recombination between copies of repeated DNA sequences that constitute approximately a third of the human HPRT locus. No difference in deletion structure or complexity was observed between deletions isolated from Werner syndrome or from HL60 mutants. This suggests that the Werner syndrome deletion mutator uses deletion mutagenesis pathway(s) that are similar or identical to those used in other human somatic cells.

Molecular structure and genetic stability of human hypoxanthine phosphoribosyltransferase (HPRT) gene duplications.

We have determined the genetic stability of three independent intragenic human HPRT gene duplications and the structure of each duplication at the nucleotide sequence level. Two of the duplications were isolated as spontaneous mutations from the HL60 human myeloid leukemia cell line, while the third was originally identified in a Lesch-Nyhan patient. All three duplications are genetically unstable and have a reversion rate approximately 100-fold higher than the rate of duplication formation. The molecular structures of these duplications are similar, with direct duplication of HPRT exons 2 and 3 and of 6.8 kb (HL60 duplications) or 13.7 kb (Lesch-Nyhan duplication) of surrounding HPRT sequence. Nucleotide sequence analyses of duplication junctions revealed that the HL60-derived duplications were generated by unequal homologous recombination between clusters of Alu repeats contained in HPRT introns 1 and 3, while the Lesch-Nyhan duplication was generated by the nonhomologous insertion of duplicated HPRT DNA into HPRT intron 1. These results suggest that duplication substrates of different lengths can be generated from the human HPRT exon 2-3 region and can undergo either homologous or nonhomologous recombination with the HPRT locus to form gene duplications.