Defining the Proximal Border of the Huntington Disease Candidate Region by Multipoint Recombination Analyses

The candidate region for the Huntington disease (HD) gene has been narrowed down to a 2.2-Mb region between D4S10 and D4S98 on the short arm of chromosome 4. To map the HD gene within this candidate region 65 Dutch HD families were studied. In total 338 informative meioses were analyzed and 11 multiple informative crossovers were detected. Assuming a minimum number of recombinations and no double recombinations, our multiple informative crossovers are consistent with one specific genetic order for 12 loci: D4S10-(D4S81, D4S126)-D4S125-(D4S127, D4S95)-D4S43-(D4S115, D4S96, D4S111, D4S90, D4S141). This is in agreement with the known data derived from similar and other methods. The loci between brackets could not be mapped relative to each other. In our family material, two informative three-point marker recombination events were detected in the proximal HD candidate region, which are also informative for HD. Both recombination events map the HD gene distal to D4S81 and most likely distal to D4S125, narrowing down the HD candidate region to a 1.7-Mb region between D4S125 and D4S98.     

Complex patterns of linkage disequilibrium in the Huntington disease region.

The genetic defect causing Huntington disease (HD) has been mapped to 4p16.3 by linkage analysis using DNA markers. Two apparently contradictory classes of recombination events in HD kindreds preclude precise targeting of efforts to clone the disease gene. Here, we report a new recombination event that increases support for an internal candidate region of 2.5 Mb between D4S10 and D4S168. Analysis of 23 DNA polymorphisms in 4p16.3 revealed a complex pattern of association with the disease gene that failed to narrow the size of the candidate region. The degree of linkage disequilibrium did not show a continuous increase across the physical map, nor was a region of extreme disequilibrium identified. Markers displaying no association with the disorder were interspersed with and, in many cases, close to markers displaying significant disequilibrium. Comparison of closely spaced marker pairs on normal and HD chromosomes, as well as analysis of haplotypes across the HD region, suggest that simple recombination subsequent to a single original HD mutation cannot easily explain the pool of HD chromosomes seen today. A number of different mechanisms could contribute to the diversity of haplotypes observed on HD chromosomes, but it is likely that there has been more than one and possibly several independent origins of the HD mutation.     

Increased recombination adjacent to the Huntington disease-linked D4S10 marker.

Huntington disease (HD) is caused by a genetic defect distal to the anonymous DNA marker D4S10 in the terminal cytogenetic subband of the short arm of chromosome 4 (4p16.3). The effort to identify new markers linked to HD has concentrated on the use of somatic cell hybrid panels that split 4p16.3 into proximal and distal portions. Here we report two new polymorphic markers in the proximal portion of 4p16.3, distal to D4S10. Both loci, D4S126 and D4S127, are defined by cosmids isolated from a library enriched for sequences in the 4pter-4p15.1 region. Physical mapping by pulsed-field gel electrophoresis places D4S126 200 kb telomeric to D4S10, while D4S127 is located near the more distal marker D4S95. Typing of a reference pedigree for D4S126 and D4S127 and for the recently described VNTR marker D4S125 has firmly placed these loci on the existing linkage map of 4p16.3. This genetic analysis has revealed that the region immediately distal to D4S10 shows a dramatically higher rate of recombination than would be expected based on its physical size. D4S10-D4S126-D4S125 span 3.5 cM, but only 300-400 kb of DNA. Consequently, this small region accounts for most of the reported genetic distance between D4S10 and HD. By contrast, it was not possible to connect D4S127 to D4S125 by physical mapping, although they are only 0.3 cM apart. A more detailed analysis of recombination sites within the immediate vicinity of D4S10 could potentially reveal the molecular basis for this phenomenon; however, it is clear that the rate of recombination is not continuously increased with progress toward the telomere of 4p.     

Recombination events suggest potential sites for the Huntington's disease gene

The Huntington's disease gene (HD) maps distal to the D4S10 marker in the terminal 4p16.3 subband of chromosome 4. Directed cloning has provided several DNA segments that have been grouped into three clusters on a physical map of approximately 5 X 10(6) bp in 4p16.3. We have typed RFLPs in both reference and HD pedigrees to produce a fine-structure genetic map that establishes the relative order of the clusters and further narrows the target area containing the HD gene. Despite the large number of meiotic events examined, the HD gene cannot be positioned relative to the most distal cluster. One recombination event with HD suggests that the terminal-most markers flank the disease gene; two others favor a telomeric location for the defect. Efforts to isolate the HD gene must be divided between these two distinct intervals until additional genetic data resolve the apparent contradiction in localization.     

Sequence-tagged sites (STSs) spanning 4p16.3 and the Huntington disease candidate region.

The generation of sequence-tagged sites (STSs) has been proposed as a unifying approach to correlating the disparate results generated by genetic and various physical techniques being used to map the human genome. We have developed an STS map to complement the existing physical and genetic maps of 4p16.3, the region containing the Huntington disease gene. A total of 18 STSs span over 4 Mb of 4p16.3, with an average spacing of about 250 kb. Eleven of the STSs are located within the primary candidate HD region of 2.5 Mb between D4S126 and D4S168. The availability of STSs makes the corresponding loci accessibility to the general community without the need for distribution of cloned DNA. These STSs should also provide the means to isolate yeast artificial chromosome clones spanning the HD candidate region.     

A recombination event that redefines the Huntington disease region

We report both a recombination event that places the Huntington disease gene proximal to the marker D4S98 and an extended linkage-disequilibrium study that uses this marker and confirms the existence of disequilibrium between it and the HD locus. We also report the cloning of other sequences in the region around D4S98, including a new polymorphic marker R10 and conserved sequences that identify a gene in the region of interest.     

Localization of the Huntington's disease gene to a small segment of chromosome 4 flanked by D4S10 and the telomere

Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder of late onset, characterized by progressive motor disturbance, psychological manifestations, and intellectual deterioration. The HD gene has been genetically mapped by linkage to the DNA marker D4S10, but the exact physical location of the HD defect has remained uncertain. To delineate critical recombination events revealing the physical position of the HD gene, we have identified restriction fragment length polymorphisms for two recently mapped chromosome 4 loci, RAF2 and D4S62, and determined the pattern of segregation of these markers in both reference and HD pedigrees. Multipoint linkage analysis of the new markers with D4S10 and HD establishes that the HD gene is located in a very small physical region at the tip of the chromosome, bordered by D4S10 and the telomere. A crossover within the D4S10 locus orients this segment on the chromosome, providing the necessary information for efficient application of directional cloning strategies for progressing toward, and eventually isolating, the HD gene.     

Identification of multiple CpG islands and associated conserved sequences in a candidate region for the Huntington disease gene

The HD locus has been assigned to 4p16.3 distal to the DNA segment D4S10. However, the precise location of this gene is still unknown. At least three regions, together encompassing more than 3.5 Mb of DNA, can still be considered as candidate regions for the HD gene. Our efforts are directed toward the cloning and the complete characterization of one of these regions. Thus far we have cloned 460 kb of DNA in contiguously overlapping cosmids distal to D4S111 and have developed a detailed long-range restriction map orienting the contig within the terminal region of 4p16.3. We characterized 15 CpG-rich islands defined by tightly clustered rare cutter restriction sites for the enzymes NotI, BssHII, EagI, NruI, and SacII. In addition, we show that the sequences associated with the CpG-rich islands detect cross-species conservation. The detailed genetic analysis of the 460-kb contig provides a framework for the identification of genes, which can be assessed for the characteristics expected for the HD gene.     

Mapping of D4S98/S114/S113 confines the Huntington''s defect to a reduced physical region at the telomere of chromosome 4.

The dominant gene defect in Huntington's disease (HD) is linked to the DNA marker D4S10, near the telomere of the chromosome 4 short arm. Two other markers, D4S43 and D4S95, are closer, but still proximal to the HD gene in 4p16.3. We have characterized a new locus, D4S114, identified by cloning the end of a NotI fragment resolved by pulsed-field gel electrophoresis. D4S114 was localized distal to D4S43 and D4S95 by both physical and genetic mapping techniques. The "end"-clone overlaps a previously isolated NotI "linking" clone, and is within 150 kb of a second "linking" clone defining D4S113. Restriction fragment length polymorphisms for D4S113 and D4S114, one of which is identical to a SacI polymorphism detected by the anonymous probe pBS731B-C (D4S98), were typed for key crossovers in HD and reference pedigrees. The data support the locus order D4S10-(D4S43, D4S95)-D4S98/S114/S113-HD-telomere. The D4S98/S114/S113 cluster therefore represents the nearest cloned sequences to HD, and provides a valuable new point for launching directional cloning strategies to isolate and characterize this disease gene.     

A new DNA marker (D4S90) is located terminally on the short arm of chromosome 4, close to the Huntington disease gene

Genetic linkage studies have mapped Huntington's disease (HD) to the distal portion of the short arm of chromosome 4 (4p16.3), 4 cM distal to D4S10 (G8). To date, no definite flanking marker has been identified. A new DNA marker, D4S90 (D5); which maps to the distal region of 4p16.3, is described. The marker was used in a genetic linkage study in the CEPH reference families with seven other markers at 4p16. The study, together with knowledge of the physical map of the region, places D4S90 as the most distal marker, 6 cM from D4S10. A provisional linkage study with HD gave a maximum lod score of 2.14 at a theta of 0.00 and no evidence of linkage disequilibrium. As D4S90 appears to be located terminally, it should play an important role in the accurate mapping and cloning of the HD gene.     

Recombination of 4p16 DNA markers in an unusual family with Huntington disease

The Huntington disease (HD) mutation has been localized to human chromosome 4p16, in a 6-Mb region between the D4S10 locus and the 4p telomere. In a report by Robbins et al., a family was identified in which an affected individual failed to inherit three alleles within the 6-Mb region originating from the parental HD chromosome. To explain these results, it was suggested that the HD locus (HD) lies close to the telomere and that a recombination event took place between HD and the most telomeric marker examined, D4S90. As a test of this telomere hypothesis, we examined six members of this family, five of whom are affected with HD, for the segregation of 12 polymorphic markers from 4p16, including D4S169, which lies within 80 kb of the 4p telomere. We separated, in somatic cell hybrids, the chromosomes 4 from each family member, to determine the phase of marker alleles on each chromosome. We excluded nonpaternity by performing DNA fingerprint analyses on all six family members, and we found no evidence for chromosomal rearrangements when we used high-resolution karyotype analysis. We found that two affected siblings, including one of the patients originally described by Robbins et al., inherited alleles from the non-HD chromosome 4 of their affected parents, throughout the 6-Mb region. We found that a third affected sibling, also studied by Robbins et al., inherited alleles from the HD chromosome 4 of the affected parent, throughout the 6-Mb region. Finally, we found that a fourth sibling, who is likely affected with HD, has both a recombination event within the 6-Mb region and an additional recombination event in a more centromeric region of the short arm of chromosome 4. Our results argue against a telomeric location for HD and suggest that the HD mutation in this family is either associated with DNA predisposed to double recombination and/or gene conversion within the 6-Mb region or is in a gene that is outside this region and that is different from that mutated in most other families with HD.     

Physical Mapping of a Commonly Deleted Region, the Site of a Candidate Tumor Suppressor Gene, at 12q22 in Human Male Germ Cell Tumors

A candidate tumor suppressor gene (TSG) site at 12q22 characterized by a high frequency of loss of heterozygosity (LOH) and a homozygous deletion has previously been reported in human male germ cell tumors (GCTs). In a detailed deletion mapping analysis of 67 normal-tumor DNAs utilizing 20 polymorphic markers mapped to 12q22–q24, we identified the limits of the minimal region of deletion at 12q22 between D12S377 (proximal) and D12S296 (distal). We have constructed a YAC contig map of a 3-cM region of this band between the proximal marker D12S101 and the distal marker D12S346, which contained the minimal region of deletion in GCTs. The map is composed of 53 overlapping YACs and 3 cosmids onto which 25 polymorphic and nonpolymorphic sequence-tagged sites (STSs) were placed in a unique order. The size of the minimal region of deletion was approximately 2 Mb from overlapping, nonchimeric YACs that spanned the region. We also developed a radiation hybrid (RH) map of the region between D12S101 and D12S346 containing 17 loci. The consensus order developed by RH mapping is in good agreement with the YAC STS-content map order. The RH map estimated the distance between D12S101 and D12S346 to be 246 cR₈₀₀₀and the minimal region of deletion to be 141 cR₈₀₀₀. In addition, four genes that were previously mapped to 12q22 have been excluded as candidate genes. The leads gained from the deletion mapping and physical maps should expedite the isolation and characterization of the TSG at 12q22.     

Autistic disorder and chromosome 15q11-q13: construction and analysis of a BAC/PAC contig

Autistic disorder (AD) is a neurodevelopmental disorder that affects approximately 2-10/10,000 individuals. Chromosome 15q11-q13 has been implicated in the genetic etiology of AD based on (1) cytogenetic abnormalities; (2) increased recombination frequency in this region in AD versus non-AD families; (3) suggested linkage with markers D15S156, D15S219, and D15S217; and (4) evidence for significant association with polymorphisms in the gamma-aminobutyric acid receptor subunit B3 gene (GABRB3). To isolate the putative 15q11-q13 candidate AD gene, a genomic contig and physical map of the approximately 1.2-Mb region from the GABA receptor gene cluster to the OCA2 locus was generated. Twenty-one bacterial artificial chromosome (BAC) clones, 32 P1-derived artificial chromosome (PAC) clones, and 2 P1 clones have been isolated using the markers D15S540, GABRB3, GABRA5, GABRG3, D15S822, and D15S217, as well as 34 novel markers developed from the end sequences of BAC/PAC clones. In contrast to previous findings, the markers D15S822 and D15S975 have been localized within the GABRG3 gene, which we have shown to be approximately 250 kb in size. NotI and numerous EagI restriction enzyme cut sites were identified in this region. The BAC/PAC genomic contig can be utilized for the study of genomic structure and the identification and characterization of genes and their methylation status in this autism candidate gene region on human chromosome 15q11-q13.     

Nonrandom association between Huntington disease and two loci separated by about 3 Mb on 4p16.3.

The gene for Huntington disease (HD) has been localized close to the telomere on the short arm of chromosome 4. However, refined mapping using recombinant HD chromosomes has resulted in conflicting findings and mutually exclusive candidate regions. Previously reported significant nonrandom allelic association between D4S95 and HD provided support for a more proximal location for the defective gene. In this paper, we have analyzed 17 markers, spanning approximately 6 Mb of DNA distal to locus D4S62, for nonrandom association to HD. We confirm the previous findings of nonrandom allelic association between D4S95 and HD. In addition, we provide new data showing significant nonrandom association between HD and 3 markers at D4S133 and D4S228, which are approximately 3 Mb telomeric to D4S95.     

Synteny on mouse chromosome 5 of homologs for human DNA loci linked to the Huntington disease gene

Comparative mapping in man and mouse has revealed frequent conservation of chromosomal segments, offering a potential approach to human disease genes via their murine homologs. Using DNA markers near the Huntington disease gene on the short arm of chromosome 4, we defined a conserved linkage group on mouse chromosome 5. Linkage analyses using recombinant inbred strains, a standard outcross, and an interspecific backcross were used to assign homologs for five human loci, D4S43, D4S62, QDPR, D4S76, and D4S80, to chromosome 5 and to determine their relationships with previously mapped markers for this autosome. The relative order of the conserved loci was preserved in a linkage group that spanned 13% recombination in the interspecific backcross analysis. The most proximal of the conserved markers on the mouse map, D4S43h, showed no recombination with Emv-1, an endogenous ecotropic virus, in 84 outcross progeny and 19 recombinant inbred strains. Hx, a dominant mutation that causes deformities in limb development, maps approximately 2 cM proximal to Emv-1. Since the human D4S43 locus is less than 1 cM proximal to HD near the telomere of chromosome 4, the murine counterpart of the HD gene might lie between Hx and Emv-1 or D4S43h. Cloning of the region between these markers could generate new probes for conserved human sequences in the vicinity of the HD gene or possibly candidates for the murine counterpart of this human disease locus.     

Mapping of recombinants near the Huntington disease locus by using G8 (D4S10) and newly isolated markers in the D4S10 region.

Genetic linkage between the marker G8 (D4S10) and Huntington disease (HD) was studied in six Dutch pedigrees. The informativeness of the D4S10 locus was increased by isolation of a cosmid, C5.5, with a G8 subclone used as probe. We present a restriction map of 70 kb in the D4S10 region. Two subclones of C5.5, H5.52 and F5.53, detect MspI and SinI RFLPs, respectively. These probes increase the informativeness of D4S10 in the Dutch HD population from 55% to 95%. Seven recombinations were found in 124 informative meioses in which multipoint segregation of D4S10 haplotypes and the HD locus was studied. Two of the recombinations occurred within the D4S10 region. The other five recombinations are highly valuable for the mapping of present and future markers relative to each other and to the HD gene. In addition, several recombinations between markers in meioses from unaffected parents were noted, which will also be useful in ordering new markers. On the basis of our three-point recombination data, the orientation of the D4S10 region relative to HD is HD-H5.52-G8-F5.53, which independently confirms the previously derived polarity for D4S10.     

Presymptomatic testing for Huntington's disease

Summary Presymptomatic testing for Huntington's disease (HD) is possible through the use of restriction fragment length polymorphisms (RFLPs) at the closely linked D4S10 locus. Recombination between the HD and D4S10 loci will occur in 4%–5% of meioses, and is a well-recognised complication of predictive testing. Recombination between RFLPs within the D4S10 locus is a rare event and can usually be ignored. We report a case where such an intra-locus recombination frustrated attempts to predict the chance of a high-risk individual inheriting the HD gene.     

High-resolution meiotic and physical mapping of the best vitelliform macular dystrophy (VMD2) locus to pericentromeric chromosome 11.

Best vitelliform macular dystrophy (VMD2) has previously been linked to several microsatellite markers from chromosome 11. Subsequently, additional genetic studies have refined the Best disease region to a 3.7-cM interval flanked by markers at D11S903 and PYGM. To further narrow the interval containing the Best disease gene and to obtain an estimate of the physical size of the minimal candidate region, we used a combination of high-resolution PCR hybrid mapping and analysis of recombinant Best disease chromosomes. We identified six markers from within the D11S903-PYGM interval that show no recombination with the defective gene in three multigeneration Best disease pedigrees. Our hybrid panel localizes these markers on either side of the centromere on chromosome 11. The closest markers flanking the disease gene are at D11S986 in band p12-11.22 on the short arm and at D11S480 in band q13.2-13.3 on the proximal long arm. This study demonstrates that the physical size of the Best disease region is exceedingly larger than previously estimated from the genetic data, because of the proximity of the defective gene to the centromere of chromosome 11.     

Significant linkage disequilibrium between the Huntington disease gene and the loci D4S10 and D4S95 in the Dutch population.

Significant linkage disequilibrium has been found between the Huntington disease (HD) gene and DNA markers located around D4S95 and D4S98. The linkage-disequilibrium studies favor the proximal location of the HD gene, in contrast to the conflicting results of recombination analyses. We have analyzed 45 Dutch HD families with 19 DNA markers and have calculated the strength of linkage disequilibrium. Highly significant linkage disequilibrium has been detected with D4S95, consistent with the studies in other populations. In contrast with most other studies, however, the area of linkage disequilibrium extends from D4S10 proximally to D4S95, covering 1,100 kb. These results confirm that the HD gene most likely maps near D4S95.