A Diphenol Oxidase Gene Is Part of a Cluster of Genes Involved in Catecholamine Metabolism and Sclerotization in Drosophila. II. Molecular Localization of the Dox-A2 Coding Region

Mutations at the Dox-A2 (2-53.9) locus alter the A2 component of diphenol oxidase, an enzyme having an important role in cuticle formation. This locus is in the dopa decarboxylase, Df(2L)TW130 region, which contains a cluster of at least 14 genes involved in catecholamine metabolism and the formation, sclerotization and melanization of cuticle in Drosophila. The region is subdivided by deficiencies, and localization of breakpoints in cloned DNA reveals a dense subcluster of six genes in the 23 kb proximal to Ddc. Five lethal loci distal to Ddc comprise a second such subcluster. The proximal breakpoints of deficiencies Df(2L)hk18 and Df(2L)OD15 define a 14.3- to 16.8-kb region containing Dox-A2 and l(2)37Bb, and those of Df(2L)OD15 and Df(2L)TW203 define a 9.3- to 12.1-kb region containing l(2)37Ba, l(2)37Bc and l(2)37Be. Southern blots show two of the Dox-A2 mutations are small deletions (0.1 and 1.1 kb). The Dox-A2 locus mRNA is 1.7 kb. cDNA clones indicate that the 3' end is centromere proximal and that the coding region contains at least one small intron. The Dox-A2 locus is within 3.4 to 4.4 kb of the Df(2L)OD15 breakpoint, placing four of the vital loci within a maximum of 15.5 kb. The location of Dox-A2 in a cluster of genes affecting cuticle formation is discussed.     

Fine mapping of the McLeod locus (XK) to a 150-380-kb region in Xp21.

McLeod syndrome, characterized by acanthocytosis and the absence of a red-blood-cell Kell antigen (Kx), is a multisystem disorder involving a late-onset myopathy, splenomegaly, and neurological defects. The locus for this syndrome has been mapped, by deletion analysis, to a region between the loci for Duchenne muscular dystrophy (DMD) and chronic granulomatous disease (CGD). In this study, we describe a new marker, 3BH/R 0.3 (DXS 709), isolated by cloning the deletion breakpoint of a DMD patient. A long-range restriction map of Xp21, encompassing the gene loci for McLeod and CGD, was constructed, and multiple CpG islands were found clustered in a 700-kb region. Using the new marker, we have limited the McLeod syndrome critical region to 150-380-kb. Within this interval, two CpG-rich islands which may represent candidate sites for the McLeod gene were identified.     

Characterization of the NPHP1 locus: mutational mechanism involved in deletions in familial juvenile nephronophthisis

Familial juvenile nephronophthisis is an autosomal recessive, genetically heterogeneous kidney disorder representing the most frequent inherited cause of chronic renal failure in children. A gene, NPHP1, responsible for approximately 85% of the purely renal form of nephronophthisis, has been mapped to 2q13 and characterized. The major NPHP1 gene defect is a large homozygous deletion found in approximately 80% of the patients. In this study, by large-scale genomic sequencing and pulsed-field gel electrophoresis analysis, we characterized the complex organization of the NPHP1 locus and determined the mutational mechanism that results in the large deletion observed in most patients. We showed that the deletion is 290 kb in size and that NPHP1 is flanked by two large inverted repeats of approximately 330 kb. In addition, a second sequence of 45 kb located adjacent to the proximal 330-kb repeat was shown to be directly repeated 250 kb away within the distal 330-kb repeat deleting the sequence tag site (STS) 804H10R present in the proximal copy. The patients' deletion breakpoints appear to be located within the 45-kb repeat, suggesting an unequal recombination between the two homologous copies of this smaller repeat. Moreover, we demonstrated a nonpathologic rearrangement involving the two 330-kb inverted repeats found in 11 patients and, in the homozygous state, in 2 (1.3%) control individuals. This could be explained by interchromosomal mispairing of the 330-kb inverted repeat, followed by double recombination or by a prior intrachromosomal mispairing of these repeats, leading to an inversion of the NPHP1 region, followed by an interchromosomal unequal crossover event. This complex rearrangement, as well as the common deletion found in most patients, illustrates the high level of rearrangements occurring in the centromeric region of chromosome 2.     

Targeted isolation of a designated region of the Bacillus subtilis genome by recombinational transfer

A method for positional cloning of the Bacillus subtilis genome was developed. The method requires a set of two small DNA fragments that flank the region to be copied. A 38-kb segment that carries genes ppsABCDE encoding five enzymes for antibiotic plipastatin synthesis and another genome locus as large as 100 kb including one essential gene were examined for positional cloning. The positional cloning vector for ppsABCDE was constructed using a B. subtilis low-copy-number plasmid that faithfully copied the precise length of the 38-kb DNA in vivo via the recombinational transfer system of this bacterium. Structure of the copied DNA was confirmed by restriction enzyme analyses. Furthermore, the unaltered structure of the 38-kb DNA was demonstrated by complementation of a ppsABCDE deletion mutant.     

Molecular Cloning and Duplication of the Nematode Sex-Determining Gene Tra-1

The autosomal sex-determining gene tra-1 plays a major role in controlling sexual phenotype in the nematode Caenorhabditis elegans. This gene is the terminal global regulator in a well-characterized cascade of sex-determining genes. It governs all aspects of somatic sexual differentiation, and it also has important functions in governing germ-line differentiation. Previous genetic analyses have led to the characterization of many loss-of-function (masculinizing) and gain-of-function (dominant feminizing) alleles, and to models for the functions and regulation of tra-1. The gene was cloned by identifying linked transposon insertions, about 200 kb away from tra-1. From this starting point a series of YAC, cosmid and phage clones were assembled into a genomic walk covering over 400 kb. Much of this region was found to be unrepresented in the cosmid database that covers most of the C. elegans genome. This deficit is largely or wholly due to the presence of sequences that cannot be cloned in rec(+)bacterial hosts. The ratio of physical map distances to recombinational map distances in the tra-1 region of the genome appears to be unusually low, indicating considerable local map expansion. The location of tra-1 within the cloned region was determined using a variety of tra-1 mutations that are associated with physical rearrangements of the gene. One of these is a 14-kb deletion, which behaves as a null allele. Another rearrangement, eDp24, is a tandem duplication of 22 kb. Genetic analysis demonstrates that eDp24 carries two incomplete copies of tra-1, and that these copies appear to interact, suggesting some form of negative autoregulation at this locus. Three variant forms of the tra-1 locus have been identified in different natural isolates of C. elegans.     

Cloning the Arabidopsis GA1 Locus by Genomic Subtraction

Arabidopsis thaliana ga1 mutants are gibberellin-responsive dwarfs. We used the genomic subtraction technique to clone DNA sequences that are present in wild-type Arabidopsis (ecotype Landsberg erecta, Ler) but are missing in a presumptive ga1 deletion mutant, ga1-3. The cloned sequences correspond to a 5.0-kb deletion in the ga1-3 genome. Three lines of evidence indicated that the 5.0-kb deletion in the ga1-3 mutant is located at the GA1 locus. First, restriction fragment length polymorphism mapping showed that DNA sequences within the 5.0-kb deletion map to the GA1 locus. Second, cosmid clones that contain wild-type DNA inserts spanning the deletion in ga1-3 complemented the dwarf phenotype when integrated into the ga1-3 genome by Agrobacterium tumefaciens-mediated transformation. Third, we identified molecular lesions in four additional ga1 alleles within the 5.0-kb region deleted in mutant ga1-3. One of these lesions is a large insertion or inversion located within the most distal intron encoded by the GA1 locus. The three other lesions are all single base changes located within the two most distal exons. RNA gel blot analysis indicated that the GA1 locus encodes a 2.8-kb mRNA. We calculated a recombination rate of 10-5 cM per nucleotide for the GA1 region of the Arabidopsis genome.     

Penetrance of craniofacial anomalies in mouse models of Smith-Magenis syndrome is modified by genomic sequence surrounding Rai1: not all null alleles are alike

Craniofacial abnormality is one of the major clinical manifestations of Smith-Magenis syndrome (SMS). Previous analyses in a mixed genetic background of several SMS mouse models--including Df(11)17/+ and Df(11)17-1/+, which have 2-Mb and 590-kb deletions, respectively, and Rai1(-/+)--revealed that the penetrance of the craniofacial phenotype appears to be influenced by deletion size and genetic background. We generated an additional strain with a 1-Mb deletion intermediate in size between the two described above. Remarkably, the penetrance of its craniofacial anomalies in the mixed background was between those of Df(11)17 and Df(11)17-1. We further analyzed the deletion mutations and the Rai1(-/+) allele in a pure C57BL/6 background, to control for nonlinked modifier loci. The penetrance of the craniofacial anomalies was markedly increased for all the strains in comparison with the mixed background. Mice with Df(11)17 and Df(11)17-1 deletions had a similar penetrance, suggesting that penetrance may be less influenced by deletion size, whereas that of Rai1(-/+) mice was significantly lower than that of the deletion strains. We hypothesize that potential trans-regulatory sequence(s) or gene(s) that reside within the 590-kb genomic interval surrounding Rai1 are the major modifying genetic element(s) affecting the craniofacial penetrance. Moreover, we confirmed the influence of genetic background and different deletion sizes on the phenotype. The complicated control of the penetrance for one phenotype in SMS mouse models provides tools to elucidate molecular mechanisms for penetrance and clearly shows that a null allele caused by chromosomal deletion can have different phenotypic consequences than one caused by gene inactivation.     

Deletions encompassing the manganese superoxide dismutase gene in the Drosophila melanogaster genome.

Two deletions, Df(2R)Sod2-11 and Df(2R)Sod2-332, are recovered that encompass the manganese superoxide dismutase (MnSOD) gene or a null mutant referred to as SOD2n283 in Drosophila. Molecular analysis has revealed that the Df(2R)Sod2-332 deletion completely uncovered both MnSOD and its adjacent gene, Arp53D, whereas Df(2R)Sod2-11 was missing the promoter region of MnSOD gene. As a consequence of reduced MnSOD expression, these deletion heterozygotes are now sensitive to oxidative stress. Complementation analysis with some recently recovered deletions in the 53C/D region has established that other essential loci exist in this interval, and second, that Arp53D function is not essential for the survival of the organism. These deletions will be instrumental in the recovery of missense substitutions in the MnSOD peptide and their influence on oxidative stress resistance.     

Haploinsufficiency of <Emphasis Type="Italic">PAX9</Emphasis> is associated with autosomal dominant hypodontia

We recently identified a frame-shift mutation in the PAX9 gene as the underlying cause for hypodontia involving permanent molar teeth segregating in an autosomal dominant pattern in a single large family (Stockton et al. 2000). Here we report a small nuclear family in which a father and his daughter are affected with severe hypodontia, involving agenesis of all primary and permanent molars, evidently caused by deletion of the entire PAX9 gene. Hemizygosity at the PAX9 locus in the two affected individuals was initially discovered when an informative single nucleotide polymorphism, identified while sequencing the gene for mutations, appeared to demonstrate non-Mendelian inheritance. Fluorescence in situ hybridization (FISH) analysis with a cosmid containing the PAX9 gene yielded a signal on only one chromosome 14 homologue and confirmed the presence of a deletion encompassing the PAX9 locus. Analysis of microsatellite loci in the vicinity of PAX9 delineated one breakpoint of the deletion. These data, in concert with FISH analysis with cosmids encompassing a 199 kb region, indicated that the deletion is between approximately 44 kb and 100 kb. PAX9 is one of two genes, and the only odontogenic gene within the deletion interval, thus supporting the model of haploinsufficiency for PAX9 as the underlying basis for hypodontia.