Fine structure DNA mapping studies of the chromosomal region harboring the genetic defect in neurofibromatosis type 1

To better map the location of the von Recklinghausen neurofibromatosis (NF1) gene, we have characterized a somatic cell hybrid designated 7AE-11. This microcell-mediated, chromosome-transfer construct harbors a centromeric segment and a neo-marked segment from the distal long arm of human chromosome 17. We have identified 269 cosmid clones with human sequences from a 7AE-11 library and, using a panel of somatic cell hybrids with a total of six chromosome 17q breakpoints, have mapped 240 of these clones on chromosome 17q. The panel included a hybrid (NF13) carrying a der(22) chromosome that was isolated from an NF1 patient with a balanced translocation, t(17;22) (q11.2;q11.2). Fifty-three of the cosmids map into a region spanning the NF13 breakpoint, as defined by the two closest flanking breakpoints (17q11.2 and 17q11.2-q12). RFLP clones from a subset of these cosmids have been mapped by linkage analysis in normal reference families, to localize the NF1 gene more precisely and to enhance the potential for genetic diagnosis of this disorder. The cosmids in the NF1 region will be an important resource for testing DNA blots of large-fragment restriction-enzyme digests from NF1 patient cell lines, to detect rearrangements in patients' DNA and to identify the 17;22 NF1 translocation breakpoint.     

Tandem duplication of the NF1 gene detected by high-resolution FISH in the 17q11.2 region

The gene for neurofibromatosis type 1 (NF1), mapping to 17q11.2, has one of the highest observed mutation rates, partially because of its large size and gene conversion primed by NF1 pseudogenes. We have previously shown by means of high resolution fluorescence in situ hybridization (FISH) that a number of the loci flanking the NF1 gene are duplicated, in agreement with the reported presence of NF1 repetitive sequences (REPs). We report a direct tandem duplication of the NF1 gene identified in 17q11.2 by high-resolution FISH. FISH on stretched chromosomes with locus-specific probes revealed the duplication of the NF1 gene from the promoter to 3'UTR, but with at least the absence of exon 22. Fiber FISH with P1 artificial and bacterial artifical chromosomes, including the NF1 5'UTR and 3'UTR and flanking regions, visualized the direct tandem duplication with a similar, but not identical, genomic organization of the NF1 duplicon copies. Duplication was probably present in the human-chimpanzee-gorilla common ancestor, as demonstrated here by the finding of the duplicated NF1 gene at orthologous chromosome loci. The NF1 intrachromosomal duplication may contribute to the high whole-gene mutation rate by gene conversion, although the functional activity of the NF1 copy remains to be investigated. Detection of the NF1 duplicon by high-resolution FISH may pave the way to filling the gaps in the human genomic sequence of the pericentromeric 17q11.2 region.     

Molecular characterisation of t(17;22)(q11.2;q11.2) is not consistent with NF1 gene duplication

A tandem duplication of the NF1 gene in 17q11.2 has recently been detected by high-resolution fluorescence in situ hybridisation (FISH) on stretched chromosomes and DNA fibres. These findings suggest not only that, in the 17q11.2 region, the NF1 gene is surrounded by NF1 low-copy repeats on each side of the gene, but also that the NF1 gene and its directly flanking regions are duplicated structures. However, if the NF1 gene is duplicated at 17q11.2, this should be observed by FISH analysis on metaphase chromosomes of relevant translocation carriers with the probes originally used to identify the duplication, since hybridisation signals of some of the probes would be expected on both derivative chromosomes, the der(17) and the der(22). We have only been able to obtain signals on the one or the other derivative of a female translocation carrier. Therefore, our results do not support the hypothesis of a duplication of the NF1 gene and its immediately flanking regions at 17q11.2 as had been previously postulated. Rather, our findings suggest that there is one NF1 gene in the 17q11.2 region.     

Refined physical and genetic mapping of the NF1 region on chromosome 17.

A total of 15 polymorphic markers were used to construct a genetic map that encompasses the NF1 locus on chromosome 17. The markers were a subset of a large collection of chromosome 17-specific probes and were selected for marker typing in NF1 families after physical localization to the pericentric region of the chromosome. Multilocus data for a total of 17 informative NF1 families and 39 other families were included in genetic analyses. No recombination was observed between NF1 and four markers, one or more of which was informative in 86% of parents. More-refined physical mapping studies demonstrated that all four of the markers are proximal to the chromosome 17 translocation breakpoints from two NF1 patients bearing balanced translocations. The region flanking the disease locus spans a distance of 1 centimorgan (cM) in males and 9 cM in females. Close flanking markers were informative in 76% of meioses. Sex differences in recombination rates in the pericentric region were highly significant statistically.     

Linkage analysis of chromosome 17 markers in British and South African families with neurofibromatosis type 1

Nine markers from the pericentromeric region of chromosome 17 were typed in 16 British and five South African families with neurofibromatosis type 1 (NF1). The markers--p17H8, pHHH202, and EW204--were linked to NF1 at recombination fractions less than 1%. No evidence of locus heterogeneity was detected. Inspection of recombinant events in families informative for several markers suggests that the NF1 gene is located between the markers EW301 (cen-p11.2) and EW206 (cen-q12) and possibly distal to pHHH202 (q11.2-q12).     

Precise localization of NF1 to 17q11.2 by balanced translocation.

A female patient is described with von Recklinghausen neurofibromatosis (NF1) in association with a balanced translocation between chromosome 17 and 22 [46,XX,t(17;22)(q11.2;q11.2)]. The breakpoint in chromosome 17 is cytogenetically identical to a previously reported case of NF1 associated with a 1;17 balanced translocation and suggests that the translocation events disrupt the NF1 gene. This precisely maps the NF1 gene to 17q11.2 and provides a physical reference point for strategies to clone the breakpoint and therefore the NF1 gene. A human-mouse somatic cell hybrid was constructed from patient lymphoblasts which retained the derivative chromosome 22 (22pter----22q11.2::17q11.2----17qter) but not the derivative 17q or normal 17. Southern blot analysis with genes and anonymous probes known to be in proximal 17q showed ErbA1, ErbB2, and granulocyte colony-stimulating factor (CSF3) to be present in the hybrid and therefore distal to the breakpoint, while pHHH202 (D17S33) and beta crystallin (CRYB1) were absent in the hybrid and therefore proximal to the breakpoint. The gene cluster including ErbA1 is known to be flanked by the constitutional 15;17 translocation breakpoint in hybrid SP3 and by the acute promyelocytic leukemia (APL) breakpoint, which provides the following gene and breakpoint order: cen-SP3-(D17S33,CRYB1)-NF1-(CSF3,ERBA1, ERBB2)-APL-tel. The flanking breakpoints of SP3 and API are therefore useful for rapidly localizing new markers to the neurofibromatosis critical region, while the breakpoints of the two translocation patients provide unique opportunities for reverse genetic strategies to clone the NF1 gene.     

Identification of Neurofibromatosis 1 (NF1) Homologous Loci by Direct Sequencing, Fluorescence in Situ Hybridization, and PCR Amplification of Somatic Cell Hybrids

Using fluorescence in situ hybridization (FISH), we have identified seven NF1-related loci, two separate loci on chromosome 2, at bands 2q21 and 2q33-q34, and one locus each on five other chromosomes at bands 14q11.2, 15q11.2, 18p11.2, 21q11.2-q21, and 22q11.2. Application of PCR using NF1 primer pairs and genomic DNA from somatic cell hybrids confirmed the above loci, identified additional loci on chromosomes 12 and 15, and showed that the various loci do not share homology beyond NF1 exon 27b. Sequenced PCR products representing segments corresponding to NF1 exons from these loci demonstrated greater than 95% sequence identity with the NF1 locus. We used sequence differences between bona fide NF1 and NF1 -homologous loci to strategically design primer sets to specifically amplify 30 of 36 exons within the 5′ end of the NF1 gene. These developments have facilitated mutation analysis at the NF1 locus using genomic DNA as template.     

Two independent chromosomal rearrangements, a very small (550 kb) duplication of the 7q subtelomeric region and an atypical 17q11.2 (NF1) microdeletion, in a girl with neurofibromatosis

Most patients with neurofibromatosis (NF1) are endowed with heterozygous mutations in the NF1 gene. Approximately 5% show an interstitial deletion of chromosome 17q11.2 (including NF1) and in most cases also a more severe phenotype. Here we report on a 7-year-old girl with classical NF1 signs, and in addition mild overgrowth (97th percentile), relatively low OFC (10th-25th percentile), facial dysmorphy, hoarse voice, and developmental delay. FISH analysis revealed a 17q11.2 microdeletion as well as an unbalanced 7p;13q translocation leading to trisomy of the 7q36.3 subtelomeric region. The patient's mother and grandmother who were phenotypically normal carried the same unbalanced translocation. The 17q11.2 microdeletion had arisen de novo. Array comparative genomic hybridization (CGH) demonstrated gain of a 550-kb segment from 7qter and loss of 2.5 Mb from 17q11.2 (an atypical NF1 microdeletion). We conclude that the patient's phenotype is caused by the atypical NF1 deletion, whereas 7q36.3 trisomy represents a subtelomeric copy number variation without phenotypic consequences. To our knowledge this is the first report that a duplication of the subtelomeric region of chromosome 7q containing functional genes (FAM62B, WDR60, and VIPR2) can be tolerated without phenotypic consequences. The 17q11.2 microdeletion (containing nine more genes than the common NF1 microdeletions) and the 7qter duplication were not accompanied by unexpected clinical features. Most likely the 7qter trisomy and the 17q11.2 microdeletion coincide by chance in our patient.     

Regional mapping panel for human chromosome 17: Application to neurofibromatosis type 1

A somatic cell hybrid mapping panel was constructed to localize cloned DNA sequences to any of 15 potentially different regions of human chromosome 17. Relatively high-resolution mapping is possible for 50% of the chromosome length in which 12 breakpoints are distributed over approximately 45 megabases, with an average spacing estimated at 1 breakpoint every 2-7 megabases. This high-resolution capability includes the pericentromeric region of 17 to which von Recklinghausen neurofibromatosis (NF1) has recently been mapped. Using 20 cloned genes and anonymous probes, we have tested the expected order and location of panel breakpoints and confirmed, refined, or corrected the regional assignment of several cloned genes and anonymous probes. Four markers with varying degrees of linkage to NF1 have been physically localized and ordered by the panel: the loosely linked markers myosin heavy chain 2 (25 cM) to p12----13.105 and nerve growth factor receptor (14 cM) to q21.1----q23; the more closely linked pABL10-41 (D17S71, 5 cM) to p11.2; and the tightly linked pHHH202 (D17S33) to q11.2-q12. Thus, physical mapping of linked markers confirms a pericentromeric location of NF1 and, along with other data, suggests the most likely localization is proximal 17q.     

Intron loss in the SART1 genes of Fugu rubripes and Tetraodon nigroviridis.

The human SART1 gene was initially identified in a screen for proteins recognised by IgE, which may be implicated in atopic disease. We have examined the genomic structure and cDNA sequence of the SART1 gene in the compact genomes of the pufferfish Fugu rubripes and Tetraodon nigroviridis. The entire coding regions of both the Fugu and Tetraodon SART1 genes are contained within single exons. The Fugu gene contains only one intron located in the 5' untranslated region. Southern blot hybridisation of Fugu genomic DNA confirmed the SART1 gene to be single copy. Partial genomic structures were also determined for the human, mouse, Drosophila and C. elegans SART1 homologues. The human and mouse genes both contain many introns in the coding region, the human gene possessing at least 20 exons. The Drosophila and C. elegans homologues contain 6 and 12 exons, respectively. This is only the second time such a difference in the organization of homologous Fugu and human genes has been reported. The Fugu and Tetraodon SART1 genes encode putative proteins of 772 and 774 aa, respectively, each having 65% amino acid identity to human SART1. Leucine zipper and basic motifs are conserved in the predicted Fugu and Tetraodon proteins.     

The neurofibromatosis type 1 gene encodes a protein related to GAP

cDNA walking and sequencing have extended the open reading frame for the neurofibromatosis type 1 gene (NF1). The new sequence now predicts 2485 amino acids of the NF1 peptide. A 360 residue region of the new peptide shows significant similarity to the known catalytic domains of both human and bovine GAP (GTPase activating protein). A much broader region, centered around this same 360 amino acid sequence, is strikingly similar to the yeast IRA1 product, which has a similar amino acid sequence and functional homology to mammalian GAP. This evidence suggests that NF1 encodes a cytoplasmic GAP-like protein that may be involved in the control of cell growth by interacting with proteins such as the RAS gene product. Mapping of the cDNA clones has confirmed that NF1 spans a t(1;17) translocation mutation and that three active genes lie within an intron of NF1, but in opposite orientation.     

The structure of the human apolipoprotein C-II gene. Electron microscopic analysis of RNA:DNA hybrids, complete nucleotide sequence, and identification of 5' homologous sequences among apolipoprotein genes

Cloned human apo-C-II cDNA was used as a hybridization probe to identify the human apo-C-II gene in a genomic library constructed in our laboratory. The isolated apo-C-II DNA was studied both by electron microscopy and by direct sequence analysis. Ultrastructural morphological analysis of RNA-DNA hybrids revealed that the apo-C-II gene had complex structures because of regions of inverted complementary sequences in and around the gene forming stem-and-loop structures which interfere with the formation of stable RNA:DNA hybrids. Extensive morphological analysis revealed a minimum of 3 intervening sequences (IVS), and their lengths were measured. Direct sequence analysis of the cloned gene confirmed the presence of 3 IVS. There are 4 Alu type sequences in IVS-I. We sequenced 4340 nucleotides which include 545 nucleotides in the 5' flanking region, the entire gene which spans 3320 nucleotides, and 475 nucleotides in the 3' flanking region which also encompasses an additional Alu sequence. The 5' end of the gene was identified by primer extension and sequencing of the primer extended cDNA. Apo-C-II mRNA structure was deduced from the cDNA sequence, the primer extension experiments, and the genomic sequence. It is 494 nucleotides in length. Its sequence differs from previously published sequences in that there are 7 additional nucleotides before the polyadenylate tail. In the 5' flanking region, nucleotides -234 to -213 encompass a GC-rich region which exhibits high homology (greater than 70%) to the 5' flanking regions of the genes of all the apolipoproteins published to date, namely, apo-A-II (-497 to -471), apo-A-I (approximately -196 to -179), apo-E (-409 to -391), and apo-C-III (approximately -116 to -103). This highly conserved region might represent some evolutionarily conserved sequences from these related genes and/or might represent a region with regulatory function.     

Molecular cloning and sequence analysis of the mouse kallikrein-binding protein gene.

A genomic clone (MKBP-10) encoding the mouse kallikrein-binding protein (MKBP) was isolated from a mouse genomic DNA library by screening with a rat kallikrein-binding protein (RKBP) cDNA probe. The total sequenced region of the MKBP gene spans 8615 base pairs. The exon and intron locations of the RKBP gene were identified by similarity with the RKBP gene. The MKBP gene encodes a prepeptide of 417 amino acid residues which exhibits 71% homology with RKBP. A TATA box sequence was located in the 5' flanking region of the MKBP gene by similarity with the consensus sequence TATAAAA.