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Published online before print
July 15, 2004, 10.1101/gr.2340804 Genome Res. 14:1483-1492, 2004 ©2004 by Cold Spring Harbor Laboratory Press; ISSN 1088-9051/04 $5.00
Letter Segmental Duplications Flank the Multiple Sclerosis Locus on Chromosome 17q1 Department of Human Genetics, David Geffen School of Medicine at UCLA, University of California, Los Angeles, California 90095, USA 2 Department of Pathology, David Geffen School of Medicine at UCLA, University of California, Los Angeles, California 90095, USA 3 Department of Molecular Medicine, National Public Health Institute, 00290 Helsinki, Finland 4 Department of Medical Genetics, University of Helsinki, 00290 Helsinki, Finland 5 Department of Clinical Chemistry, University of Helsinki, 00290 Helsinki, Finland 6 The Finnish Genome Center, University of Helsinki, 00290 Helsinki, Finland 7 Research Program in Molecular Medicine at Biomedicum, 00290 Helsinki, Finland 8 Department of Genetics, Center for Computational Genomics, and the Center for Human Genetics, Case Western Reserve University School of Medicine and University Hospitals of Cleveland, Cleveland, Ohio 44106, USA 9 Department of Laboratory Diagnostics, Helsinki University Central Hospital, 00290 Helsinki, Finland
Large chromosomal rearrangements, duplications, and inversions are relatively common in mammalian genomes. Here we report interesting features of DNA strands flanking a Multiple Sclerosis (MS) susceptibility locus on Chromosome 17q24. During the positional cloning process of this 3-Mb locus, several markers showed a radiation hybrid clone retention rate above the average (1.8-fold), suggestive for the existence of duplicated sequences in this region. FISH studies demonstrated multiple signals with three of the tested regional BACs, and 24 BACs out of 187 showed evidence for duplication in shotgun sequence comparisons of the 17q22–q24 region. Specifically, the MS haplotype region proved to be flanked by palindromic sequence stretches and by long segmental intrachromosomal duplications in which highly homologous DNA sequences (>96% identity) are present at both ends of the haplotype. Moreover, the 3-Mb DNA segment, flanked by the duplications, is inverted in the mouse genome when compared with the orientation in human and chimp. The segmental duplication architecture surrounding the MS locus raises the possibility that a nonallelic homologous recombination between duplications could affect the biological activity of the regional genes, perhaps even contributing to the genetic background of MS.
The emerging information on the structure of the human genome has provided an entirely new view to the genome landscape. Large structural repeats, inversions, and other type of rearrangements add a new level of complexity to the genome structure and set new challenges for detailed understanding of the normal and disease-associated abnormal functions of individual genes and genome regions (Subramanian et al. 2001  ; Eichler and Sankoff 2003).
We have applied mapping and positional cloning strategy to identify genetic loci for multiple (MS) sclerosis using the study samples collected nationwide from the isolated population of Finland. Population isolates generally possess certain advantages in genetic studies of human diseases, even of those with a complex, polygenic background (Peltonen et al. 2000
For fine mapping and positional cloning of the 17q MS locus, we confirmed the physical map of the region using radiation (RH) panels and observed a significant variation of the number of positive clones for each marker. We interpreted this as suggestive for duplicated sequence structures. This hypothesis stimulated more extensive physical mapping of the region, including FISH and sequence comparison of different databases. It became evident that this particular region of the genome contained an abundance of interchromosomal and intrachromosomal segmental duplications, also known as duplicons or low-copy repeat sequences (Saarela et al. 2002 In this study we have used several physical and genetic mapping techniques as well as tools of computational analysis to refine more precisely the genomic structure of the 17q22–q24 region as a part of the process aiming to characterize the molecular pathogenesis of MS. The obtained data exemplify the complexity of the landscape of the human genome as well as position the critical MS region between two long-range rearrangements raising an interesting possibility that the particular chromosomal architecture may contribute to the pathogenesis of MS.
RH Retention Number Provides Evidence for Duplicated/Rearranged Region The routine ordering of markers used for the fine mapping of 17q22–24 using RH panels indicated in a significant variation in the observed number of clones PCR-positive for tested markers (Table 1). On multiple occasions, two closely located STS markers had a very different number of positive clones in both Stanford G3 and TNG4 RH panels. For instance, SHGC-52535 and SHGC-32453 are two STS markers located only 200 kb apart on the same BAC clone (AC003663 [GenBank] ). The distance of 200 kb corresponds to  8 crays on a radiation hybrid G3 map after conversion. Two markers this close to each other should have a very similar pattern of PCR positive clones on the RH panel. However, PCR using primers for SHGC-52535 picked up 20 clones (retention rate 24.2%), whereas primers for SHGC-32453 detected only 13 positive clones (retention rate 15.6%). A likely explanation for such a difference would be that an exceptionally high number of positive clones results from signals of two genome regions, the original and the duplicated position.
To further investigate the possibility of using the RH retention number as a means to detect potential genome duplication, we queried the database of all the potential RH markers positioned on Chromosome 17q22–q24. Subsequently, seven STS markers with radiation hybrid G3 data were found to map to the duplicated area as determined by in silico analysis. These markers have an average of 27.1% positive clone retention rate. In contrast, the average retention rate for STS markers with radiation hybrid G3 data is only 15.1% on Chromosome 17 (200 markers tested). The difference would imply that the RH retention number could potentially be used to detect genome duplications and that RH mapping data based on unusually high retention ratios should be approached with considerable caution.
Copy Number of Target Sequences Determined by FISH
Segmental Duplication Analysis Using Sequence Representation in Different Databases To further elucidate the genomic landscape of this region, we implemented methods developed by Bailey et al. (2002a ) to interrogate both the genome assembly (April and July 2003 freezes, UCSC Human Genome Map database) sequences and the underlying BAC sequences spanning this portion of 17q22–24. According to the April 2003 freeze of the UCSC Human Genome Map, this region is represented by 187 BAC clones spanning >18.24 Mb and containing two major sequencing contigs. The whole-genome shotgun sequence detection (WSSD) method by Bailey and coworkers determines areas of potential genome duplications by analyzing each BAC clone for overrepresentation within a whole-genome shotgun sequence. A stretch of sequence within a BAC clone is defined as being duplicated if the overrepresentation of the whole-genome shotgun sequence exceeds 2 standard deviations beyond the mean coverage based on an analysis of WGS depth of coverage within unique regions of the genome. At least five overlapping windows (5 kb in size) are required before a region is scored as duplicated (Bailey et al. 2002a). Among the 187 BAC clones analyzed, 24 BACs show evidence of duplications. Our analysis shows that these correspond to the largest and most homologous segmental duplications (alignments showing >96% sequence identity and >15 kb in size). All three BACs that showed evidence for duplication by FISH were also represented by duplicated sequences by the depth-of-coverage method, whereas the five BACs with regular, single signals in the FISH hybridization showed no evidence for duplications in the bioinformatics-based analysis. We compared this pattern of segmental duplication to that based on a whole-genome assembly comparison of the finished human genome for this region (Bailey et al. 2002a). We observed an excellent correspondence between these two methods validating the enrichment of segmental duplications within this portion of 17q22–q24 (Fig. 2). Our combined analysis shows that 6.05% of the 19.57-Mb sequences are duplicated (>1 kb, >90% identity). The majority of the duplications (80.8%; 957 kb of nonoverlapping duplicated bases) belong to Chromosome 17 intrachromosomal alignments (Fig. 2). Moreover, the majority of the duplications are a large part of duplication blocks that are >10 kb in length. These properties may predispose this portion of Chromosome 17 to significant rearrangements.
Comparison of Physical Versus Genetics Maps To assess if intrachromosomal segmental duplications would have an effect on the meiotic recombination, we compared the physical map of Chromosome 17q22–24 (July 2003 freeze of the UCSC genome map) with the deCODE genetic map (Fig. 3). The 19.67-Mb physical map of this region is flanked by two multiallelic markers (D17S956 and D171304) and covers a sex average distance of 25.44 cM, which translates to an overall 1.29 cM/1 Mb sex average conversion in this area, with an average intermarker distance of 0.71 cM and 0.55 Mb. This interval, covered by 166 BAC clones, contains 21 large (>10 kb) and >100 small (1–10 kb) DNA segments, which are duplicated within Chromosome 17 or in other chromosomes (Fig. 3). None of the 37 markers mapping to the interval maps to duplicated regions per se. The ratio of genetic and physical distance seemed not to be dramatically affected by the intra- or interchromosomal duplications: The average recombination rate for pairs of subsequent markers not separated by duplication was 1.09 cM/Mb (varying between 0 and 4.10, SD = 1.18), whereas the average recombination rate for marker pairs separated by duplicated sequence(s) was slightly higher, 1.24 cM/Mb (varying between 0 and 2.83, SD = 0.96).
Number of SNPs in the Duplicated and Nonduplicated Regions While searching the databases for SNP markers mapping on the 17q region, it became evident that significantly more SNPs were mapped to the duplicated than nonduplicated regions. To pursue this observation further, we counted the total number of SNPs assigned to sequences shown to be duplicated according to the SDD database and compared that with the number of SNPs on unique regions. Currently, the SNPs in the UCSC Genome Browser are divided into two groups according to the method used for their identification. The clone overlap method of SNP discovery finds an average of 0.25 SNPs/kb on nonduplicated regions, whereas the SNP density was fourfold in the duplicated sequences, being 1.0 SNPs/kb. In contrast, there is no significant difference in the SNP density between the duplicated and unique sequences when the random clone method is used for SNP identification (0.40 SNPs in duplicated regions, 0.31 SNPs/kb in nonduplicated regions). This indicates that a large proportion of SNPs reported for the duplicated region are not true SNPs but paralogous sequence variants (PSVs; Estivill et al. 2002 ). Among the 120 SNPs designed to be genotyped in our attempted fine mapping of the MS locus, six SNPs mapped to BAC clones that are shown to be duplicated in this study, but seemed unique when the SNP sequence was aligned with the publicly available human genome sequence and thus represent PSVs. None of these SNPs produced good, high-quality genotypes and were systematically excluded from the large-scale genotyping effort in the MS study sample.
Distribution of Short Palindromic Sequences
Evolution of the Duplicated 17q Region To obtain some evolutionary view to this complex chromosomal region, we compared the structure of human 17q23.3–q24.2, harboring the critical MS locus, to the syntenic region of mouse Chromosome 11 by monitoring the order and organization of the genes. The region contains 26 genes, five of which partially overlap with duplicated sequence segments: HT008, PECAM1, CACNG5, CACNG4, and PITNPC1. There are both exonic and intronic fragments overlapping with the duplications and all but one short sequence (1.4 kb) are repeated within the same locus on Chromosome 17q23–q24. The overall map order and the orientation of the genes are conserved between human and mouse chromosomes, except for a 3-Mb segment flanked by genes LOC90799and SLC16A6, which is inverted on the human chromosome when compared with mouse (Fig. 5). This "inverted" segment contains 13 known genes and includes the critical MS locus. Interestingly, according to the UCSC July freeze, there is a predicted/hypothetical gene MGC40489 which maps with >90% homology to the sequences before and after the inverted region, as well as to 17q21.31. Two other hypothetical proteins, AK091625 [GenBank] and KIAA0563, map just before the inverted region and to two or more locations on 17q21.31–q21.32. The syntenic mouse region on Chromosome 11 did not contain MGC40489and AK091625 [GenBank] gene sequences; neither could they be located anywhere else in the mouse genome, whereas KIAA0563 was also located on several locations on mouse Chromosome 11 (February 2003 freeze). This could, however, be caused by the more incomplete stage of the mouse sequence assembly. Interestingly, the two palindrome-rich areas identified in the human 17q are located in syntenic regions of the mouse Chromosome 11 flanking the particular region of the mouse map, which is inverted when compared with the human sequence. Potential duplications in the mouse genome have not yet been analyzed using the method by Bailey and coworkers, and it thus remains unclear if similar duplicated structures that are observed in the human chromosome would exist in mouse Chromosome 11.
To study whether entire coding regions of genes located in this region are duplicated, mRNA sequences of these 24 genes were BLASTed to human, mouse, and chimp genomes. Five genes (psmd12, pitpnc1, dkfzp586l0724, KPNA2, SLC16A6) had at least two hits in the human genome (overlap >1 kb of the gene, >85% identity; Fig. 5). Two of these genes (SLC16A6 and KPNA2) had two hits on Chromosome 17, and the other three genes had homologous sequences on Chromosomes 1, 3, and X. Interestingly, none of these five coding sequences showed evidence for duplication in the mouse genome; only one hit on the mouse Chromosome 11 was detected. However, all of these five genes had more than one hit also in the chimp genome sequence (UCSC November 2003 assembly).
The Position of the MS Locus We wanted to explore whether the complex structure of Chromosome 17 and its possible instability could result in a false-positive transmission distortion. A potential transmission distortion to unaffected MS family members was analyzed in 22 families where genotypes for both affected and nonaffected family members were available. In two-point linkage analysis, no hint of linkage was observed with any of the 18 multiallelic markers located in the region to nonaffected family members (Max lod score ranging from 0.00–0.98). In the corresponding test, the linkage to MS was clearly significant (Max lod score 4.48, with marker D17S1825; 14 markers gave an lod score >1.0). The position of the MS locus is indicated in Figures 2, 3, 4 and is flanked by markers D17S1792 and ATA43A10 and covered by a minimal tailing path of 23 unique BACs.
The comprehensive DNA sequence information has provided new tools to study the geography of the complete human genome. One of the intriguing questions is the association of large chromosomal rearrangements with disease susceptibility. Such rearrangements are well demonstrated in somatic mutations associated with malignant transformation and monogenic chromosome anomalies (Kolomietz et al. 2002 ). Their potential role in the susceptibility of complex traits has only lately been suggested for regions like 8p inversion, polymorphic at the population level (Stankiewicz and Lupski 2002). Here we demonstrate that both experimental and biocomputational tools provide comparable information on the large-scale rearrangements of 17q. This genome region is of special interest because it contains a locus linked to the susceptibility of MS, and its complexity severely hampered the efforts of locus restriction. The structural complexity results in several technical challenges, for example, PSVs and the high retention rate of clones in the radiation hybrid analysis. Interestingly, none of the polymorphic multisatellite markers in the region resulted in ambiguous results, which is likely to reflect a selection bias of the markers: the problematic ones have been excluded from the currently available marker sets.
It has previously been shown that 17q is rich in both inter- and intrachromosomal duplications (Dorr et al. 2001
One could speculate that this complex genomic structure of the 17q22–24 area would affect the rate of meiotic recombination and thus affect the observed genetic distances in the region. However, no striking differences between the genetic and physical maps were observed between duplicated and nonduplicated regions. We observed a trend toward meiotic recombinations potentially being slightly more frequent in the areas containing duplicated sequences, but the observed difference is so small that it does not merit any definitive conclusions. However, it is interesting to speculate that accurate recombination might be different in an area containing multiple copies of the same sequence compared with a regular two-copy situation (Selker 1999
Here we show an interesting trend between breakpoints of conserved synteny between man and mouse and the position of segmental duplications. Associations between segmental duplications and chromosomal rearrangement breakpoints have been noted before (Valero et al. 2000
The association of palindromes to genomic plasticity has been well described in prokaryotes (Leach 1994
Radiation Hybrid Mapping For radiation hybrid mapping, 29 STS (sequence tagged site) markers on Chromosome 17q23–24 were selected. PCR primers for each STS marker were either obtained directly from the Stanford Radiation Hybrid Web site (http://www-shgc.stanford.edu/Mapping/rh/RH_poster/) or designed using the MIT Primer3 software (http://www.broad.mit.edu/cgi-bin/primer/primer3.cgi). Conditions for individual STSs were applied as described in http://wwwshgc.stanford.edu/Mapping/rh/procedure/rhassaynew.html. The PCR reactions were performed on 83 radiation hybrid (RH) clones from the Stanford RH G3 panel (Research Genetics). The retention number of each RH marker is the percentage of the total positive clones over all 83 clones. To determine the average retention number in Chromosome 17, we used all the G3 markers mapped on the Stanford Radiation Hybrid backbone. However, G3 markers close to thymidine kinase gene (TK1) on Chromosome 17q25.1 were omitted from this calculation because it is the selection marker for the radiation hybrid fusion cells and every clone contains the gene.
Fluorescence in Situ Hybridization (FISH)
Segmental Duplication Analysis Using Sequence Representation in Different Databases
HGP and Celera Genome Map Comparison at Chromosome 17q23–24
Comparison of Genetic Versus Physical Map
SNP Position
Linkage Calculations
Analysis of Palindromic Sequences
The work was supported in part by grants from NIH, RO1 NS 43559; the National MS Foundation NMSS: RG 3050-B-2; Helsinki University Central Hospital Research Funds, TYH 2313; and the Finnish National Multiple Sclerosis Society. Marlena Schoenberg Fejo and Mervi Eeva are acknowledged for technical assistance in FISH experiments. York Marahrens is acknowledged for valuable comments in preparing the manuscript. Our special thanks go to the multiple sclerosis families and to the collaborating physicians. The publication costs of this article were defrayed in part by payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 USC section 1734 solely to indicate this fact.
Article and publication are at http://www.genome.org/cgi/doi/10.1101/gr.2340804. Article published online ahead of print in July 2004.
10 These authors contributed equally to this work.
11 Corresponding author.
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ABSTRACT
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