Mapping the Treacher Collins syndrome locus to 5q31.3----q33.3.

Treacher Collins syndrome is an autosomal dominant disorder of abnormal craniofacial development. Linkage analysis was performed in Treacher Collins families with restriction fragment length or microsatellite polymorphisms associated with eight loci previously mapped to 5q31----qter. Positive lod scores were obtained for four loci, D5S119, D5S207, D5S209, and D5S210, which map to 5q31.3----q33.3. The Treacher Collins syndrome locus was linked closest to locus D5S210, which is associated with microsatellite polymorphisms, with a maximum lod score of 8.65 at theta = 0.02. The Treacher Collins syndrome locus was excluded from locus ADRB2R, which maps to 5q31----q32, and loci D5S22, D5S61, and D5S43, which map to 5q34----qter. There was no evidence for genetic heterogeneity among eight families with variable expression of the condition.     

Molecular analyses of 17p11.2 deletions in 62 Smith-Magenis syndrome patients.

Smith-Magenis syndrome (SMS) is a clinically recognizable, multiple congenital anomalies/mental retardation syndrome caused by an interstitial deletion involving band p11.2 of chromosome 17. Toward the molecular definition of the interval defining this microdeletion syndrome, 62 unrelated SMS patients in conjunction with 70 available unaffected parents were molecularly analyzed with respect to the presence or absence of 14 loci in the proximal region of the short arm of chromosome 17. A multifaceted approach was used to determine deletion status at the various loci that combined (i) FISH analysis, (ii)PCR and Southern analysis of somatic cell hybrids retaining the deleted chromosome 17 from selected patients, and (iii) genotype determination of patients for whom a parent(s) was available at four microsatellite marker loci and at four loci with associated RFLPs. The relative order of two novel anonymous markers and a new microsatellite marker was determined in 17p11.2. The results confirmed that the proximal deletion breakpoint in the majority of SMS patients is located between markers D17S58 (EW301) and D17S446 (FG1) within the 17p11.1-17p11.2 region. The common distal breakpoint was mapped between markers cCI17-638, which lies distal to D17S71, and cCI17-498, which lies proximal to the Charcot Marie-Tooth disease type 1A locus. The locus D17S258 was found to be deleted in all 62 patients, and probes from this region can be used for diagnosis of the SMS deletion by FISH. Ten patients demonstrated molecularly distinct deletions; of these, two patients had smaller deletions and will enable the definition of the critical interval for SMS.     

An unusually proximal deletion on the short arm of chromosome 3 in a patient with small cell lung cancer.

The tumors of patients with small cell lung carcinoma (SCLC) frequently exhibit the loss of alleles at polymorphic loci on the short arm of chromosome 3. We report the genotype analysis of six SCLC patients obtained using 15 chromosome 3 probes that identified 19 restriction fragment length polymorphisms (RFLPs). Five of the six patients were reduced to homozygosity in the tumor DNA at every informative 3p locus, and thus did not serve to delineate the deletion. However, the RFLP analysis of the tumor DNA of the sixth patient demonstrated both heterozygous and hemizygous loci on 3p and allowed the definition of an interstitial deletion that extends proximal to the D3S2 locus at 3p14.2-p21 to include at least 3p13-p14. The exclusion of the D3F15S2 locus from the deleted region, observed in this patient, is an uncharacteristic feature of SCLC deletions. This deletion includes the location of D3S30 and D3S4, and thus serves to map these loci within the proximal half of chromosome 3.     

Somatic cell hybrids, sequence-tagged sites, simple repeat polymorphisms, and yeast artificial chromosomes for physical and genetic mapping of proximal 17p.

Somatic cell hybrids retaining the deleted chromosome 17 from 15 unrelated Smith-Magenis syndrome (SMS) [del(17)(p11.2p11.2)] patients were obtained by fusion of patient lymphoblasts with thymidine kinase-deficient rodent cell lines. Seventeen sequence-tagged sites (STSs) were developed from anonymous markers and cloned genes mapping to the short arm of chromosome 17. The STSs were used to determine the deletion status of these loci in these and four previously described human chromosome 17-retaining hybrids. Ten STSs were used to identify 28 yeast artificial chromosomes (YACs) from the St. Louis human genomic YAC library. Four of the 17 STSs identified simple repeat polymorphisms. The order and location of deletion breakpoints were confirmed and refined, and the regional assignment of several probes and cloned genes were determined. The cytogenetic band locations and relative order of six markers on 17p were established by fluorescence in situ hybridization mapping to metaphase chromosomes. The latter data confirmed and supplemented the somatic cell hybrid results. Most of the hybrids derived from [del(17)(p11.2p11.2)] patients demonstrated a similar pattern of deletion for the marker loci and were deleted for D17S446, D17S258, D17S29, D17S71, and D17S445. However, one of them demonstrated a unique pattern of deletion. This patient is deleted for several markers known to recognize a large DNA duplication associated with Charcot-Marie-Tooth (CMT) disease type 1A. These data suggest that the proximal junction of the CMT1A duplication is close to the distal breakpoint in [del(17)(p-11.2p11.2)] patients.     

Molecular analysis of 4p deletion associated with Wolf-Hirschhorn syndrome moving the “critical segment” towards the telomere

Summary We report molecular studies in 2 patients with Wolf-Hirschhorn syndrome, probing genomic DNA from the patients and their parents with markers that have been mapped to 4p16.3. One of the patients was heterozygous for alleles detected by probe F5.53, which maps to the centromeric end of the D4S10 locus, but hemizygous for loci located more distally. The region in common, which was deleted in both these patients, is within 4p16.3. This observation suggests that the gene(s) for Wolf syndrome may be contained within this region, and that the critical segment is located more distally than previous cytogenetic observations have suggested. Furthermore, we found that the deletion was of maternal origin in one patient, and of paternal origin in the other.     

A Physical Map of 15 Loci on Human Chromosome 5q23-q33 by Two-Color Fluorescence in Situ Hybridization

The q23-q33 region of human chromosome 5 encodes a large number of growth factors, growth factor receptors, and hormone/neurotransmitter receptors. This is also the general region into which several disease genes have been mapped, including diastrophic dysplasia, Treacher Collins syndrome, hereditary startle disease, the myeloid disorders that are associated with the 5q-syndrome, autosomal-dominant forms of hereditary deafness, and limb girdle muscular dystrophy. We have developed a framework physical map of this region using cosmid clones isolated from the Los Alamos arrayed chromosome 5-specific library. Entry points into this library included 14 probes to genes within this interval and one anonymous polymorphic marker locus. A physical map has been constructed using fluorescence in situ hybridization of these cosmids on metaphase and interphase chromosomes, and this is in good agreement with the radiation hybrid map of the region. The derived order of loci across the region is cen-IL4-IL5-IRF1-IL3-IL9-EGR1-CD14-FGFA-GRL-D5S207-ADRB2-SPARC-RPS14-CSF1R-ADRA1, and the total distance spanned by these loci is approximately 15 Mb. The framework map, genomic clones, and contig expansion within 5q23-q33 should provide valuable resources for the eventual isolation of the clinically relevant loci that reside in this region.     

Molecular analysis redefines three human chromosome 14 deletions

We have used a panel of 13 DNA markers in the distal region of chromosome 14q to characterize deletions in three patients determined cytogenetically to have a ring or terminally deleted chromosome 14. We have characterized one patient with a ring chromosome 14 [r (14) (p13q32.33)] and two with terminal deletions [del (14) (pterq32.3:)]. The two patients with cytogenetically identical terminal deletions of chromosome 14 were found to differ markedly when characterized with molecular markers. In one patient, none of the markers tested were deleted, indicating that the apparent terminal deletion is actually due to either an undetected interstitial deletion or a cryptic translocation event. In the other patient, the deletion was consistent with the cytogenetic observations. The deleted chromosome was shown to be of paternal origin. The long-arm breakpoint of the ring chromosome was mapped to within a 350-kb region of the immunoglobulin heavy chain gene cluster (IGH). This breakpoint was used to localize markers D14S20 and D14S23, previously thought to lie distal to IGH, to a more proximal location. The ring chromosome represents the smallest region of distal monosomy 14q yet reported.     

Assignment of 35 single-copy and 17 repetitive sequence DNA probes to human chromosome 3: high-resolution physical mapping of 7 DNA probes by in situ hybridization

Thirty-five single-copy and 17 repetitive sequence DNA probes specific for human chromosome 3 were isolated from human chromosome 3-derived genomic libraries. Seven DNA clones, including three that are polymorphic for BglII or MspI, were mapped by in situ hybridization. Four probes were mapped to 3p subregions and 3 were mapped to 3q subregions. Three of the DNA sequences map to regions overlapping a segment of chromosome 3 (3p14-23) frequently deleted in small cell lung cancer cells. By Southern blot analysis on a deletion hybrid panel, we previously mapped 6 of these probes to three distinct chromosome 3 subregions. Our in situ data support these assignments and more precisely determine the localization of each clone to the following regions: D3S34 (3p14-21), D3S35 (3p21), D3S39 (3p21), D3S40 (3p12-13), D3S37 (3q21-23), and D3S36 (3q21). Clone pL84c, a low repeat sequence clone (approximately 30 copies), was mapped to the 3q21-29 subregion. These DNA clones mapped by in situ hybridization can provide useful landmarks for the ordering and localization of other clones.     

Determination of genomic breakpoints in an epileptic patient using genotyping array

Recent advances in DNA microarray technology have enabled the identification of small alterations throughout the genome. We used standard karyotype analysis, followed by DNA microarray analysis and PCR to precisely map the chromosomal 4p deletion and determine the deletion breakpoints in the genome of an epileptic patient. The karyotype of the patient was 46,XY,del(4)(p15.2p15.3) as determined by G-banding analysis. We used a high-density oligonucleotide genotyping array to estimate the size of the deletion (4.5 Mb) and to locate the breakpoints within a 9-kb region on one side of the deletion and a 100-kb region on the other side. We amplified by PCR and sequenced the genomic region encompassing the breakpoints, and mapped the deletion to regions extending from 21648457 to 26164287 and from 26164505 to 26167493, respectively (chromosome 4 of NCBI Homo sapiens Genome Build 35.1). The deletion involves 18 genes, one of which (CCKAR) is partially deleted.     

Chromosome Breakage Hotspots and Delineation of the Critical Region for the 9p-Deletion Syndrome

The clinical features of the 9p-deletion syndrome include dysmorphic facial features (trigonocephaly, midface hypoplasia, upward-slanting palpebral fissures, and a long philtrum) and mental retardation. The majority of these patients appear to have similar cytogenetic breakpoints in 9p22, but some cases show phenotypic heterogeneity. To define the breakpoints of the deleted chromosomes, we studied 24 patients with a deletion of 9p, by high-resolution cytogenetics, FISH with 19 YACs, and PCR using 25 different sequence-tagged sites. Of 10 different breakpoints identified, 9 were localized within an approximately 5-Mb region, in 9p22-p23, that encompasses the interval between D9S1869 (telomeric) and D9S162 (centromeric). Eight unrelated patients had a breakpoint (group 1) in the same interval, between D9S274 (948h1) and D9S285 (767f2), suggesting a chromosome-breakage hotspot. Among 12 patients, seven different breakpoints (groups 3-9) were localized to a 2-Mb genomic region between D9S1709 and D9S162, which identified a breakpoint-cluster region. The critical region for the 9p-deletion syndrome maps to a 4-6-Mb region in 9p22-p23. The results from this study have provided insight into both the heterogeneous nature of the breakage in this deletion syndrome and the resultant phenotype-karyotype correlations.     

Molecular analysis of 24 Alagille syndrome families identifies a single submicroscopic deletion and further localizes the Alagille region within 20p12.

Alagille syndrome (AGS) is a clinically defined disorder characterized by cholestatic liver disease with bile duct paucity, peculiar facies, structural heart defects, vertebral anomalies, and ocular abnormalities. Multiple patients with various cytogenetic abnormalities involving 20p12 have been identified, allowing the assignment of AGS to this region. The presence of interstitial deletions of varying size led to the hypothesis that AGS is a contiguous gene deletion syndrome. This molecular analysis of cytogenetically normal AGS patients was performed in order to test this hypothesis and to refine the localization of the known AGS region. Investigation of inheritance of simple tandem repeat polymorphism alleles in 67 members of 24 cytogenetically normal Alagille families led to the identification of a single submicroscopic deletion. The deletion included loci D20S61, D20S41, D20S186, and D20S188 and presumably intervening uninformative loci D20S189 and D20S27. The six deleted loci are contained in a single YAC of 1.9 Mb. The additional finding of multiple unrelated probands who are heterozygous at each locus demonstrates that microdeletions at known loci within the AGS region are rare in cytogenetically normal patients with this disorder. This suggests that the majority of cases of AGS may be the result of a single gene defect rather than a contiguous gene deletion syndrome.     

Detection of submicroscopic deletions in band 17p13 in patients with the Miller-Dieker syndrome

The Miller-Dieker syndrome (MDS), a syndrome with lissencephaly, distinctive craniofacial features, growth impairment, and profound developmental failure, has been associated with a deletion of the distal part of chromosome band 17p13. A minority of patients with the syndrome do not have a deletion detectable with current cytogenetic techniques. Using three highly polymorphic DNA probes (pYNZ22, pYNH37.3, and p144D6) we have detected microdeletions in three MDS patients, two of whom had no visible abnormalities of chromosome 17. Loci defined by two of the DNA probes, pYNZ22 and pYNH37.3, were deleted in all three patients. The most distal locus, defined by p144D6, was present in one MDS patient, possibly defining the distal limits of the MDS region in band 17p13.3. None of these loci were absent in one case of lissencephaly without MDS.     

Evidence That the Saethre-Chotzen Syndrome Locus Lies between D7S664 and D7S507, by Genetic Analysis and Detection of a Microdeletion in a Patient

The locus for Saethre-Chotzen syndrome, a common autosomal dominant disorder of craniosynostosis and digital anomalies, was previously mapped to chromosome 7p between D7S513 and D7S516. We used linkage and haplotype analyses to narrow the disease locus to an 8-cM region between D7S664 and D7S507. The tightest linkage was to locus D7S664 ( = 7.16, θ = .00). Chromosomes from a Saethre-Chotzen syndrome patient with t(2;7) (p23;p22) were used for in situ hybridization with YAC clones containing D7S664 and D7S507. The D7S664 locus was found to lie distal to the 7p22 breakpoint, and the D7S507 locus was deleted from the translocation chromosomes. These genetic and physical mapping data independently show that the disease locus resides in this interval.     

A familial "balanced" 3;9 translocation with cryptic 8q insertion leading to deletion and duplication of 9p23 loci in siblings.

A child with phenotypic features of the 9p- syndrome, including metopic craniosynostosis, small ears, abdominal wall defect, and mental retardation, as well as hypopigmentation, was found to have a cytogenetically balanced 3;9 translocation, with breakpoints at 3p11 and 9p23, inherited from his phenotypically normal father. Molecular analysis showed heterozygous deletion of the TYRP (tyrosinase-related protein) locus, as well as loci D9S157, D9S274, D9S268, and D9S267, in the child but in neither parent. FISH analysis of the proband''s father indicated that loci deleted in his son, including TYRP, were present on neither the der(3) nor the der(9) translocation products but had been inserted into the long arm of chromosome 8. Therefore, the apparent deletion of these loci in the proband was the result of meiotic segregation of the father''s 3;9 translocation chromosomes together with his normal chromosome 8 (not bearing the insertion from 9p23). Neither the deletion of these 9p23 loci from the translocation chromosomes nor their insertion into 8q was detectable by standard chromosome banding techniques. The proband''s sister exhibited speech delay, mild facial dysmorphism, and renal malformation, and her karyotype was 46,XX. Molecular analysis showed that she had inherited normal chromosomes 3 and 9, as well as the chromosome 8 with the insertion of 9p23 material, from her father.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular detection of microscopic and submicroscopic deletions associated with Miller-Dieker syndrome.

Miller-Dieker syndrome (MDS), a disorder manifesting the severe brain malformation lissencephaly ("smooth brain"), is caused, in the majority of cases, by a chromosomal microdeletion of the distal short arm of chromosome 17. Using human chromosome 17-specific DNA probes, we have begun a molecular dissection of the critical region for MDS. To localize cloned DNA sequences to the MDS critical region, a human-rodent somatic cell hybrid panel was constructed which includes hybrids containing the abnormal chromosome 17 from three MDS patients with deletions of various sizes. Three genes (myosin heavy chain 2, tumor antigen p53, and RNA polymerase II) previously mapped to 17p were excluded from the MDS deletion region and therefore are unlikely to play a role in its pathogenesis. In contrast, three highly polymorphic anonymous probes, YNZ22.1 (D17S5), YNH37.3 (D17S28), and 144-D6 (D17S34), were deleted in each of four patients with visible deletions, including one with a ring chromosome 17 that is deleted for a portion of the single telomeric prometaphase subband p13.3. In two MDS patients with normal chromosomes, a combination of somatic cell hybrid, RFLP, and densitometric studies demonstrated deletion for YNZ22.1 and YNH37.3 in the paternally derived 17's of both patients, one of whom is also deleted for 144-D6. The results indicate that MDS can be caused by submicroscopic deletion and raises the possibility that all MDS patients will prove to have deletions at a molecular level. The two probes lie within a critical region of less than 3,000 kb and constitute potential starting points in the isolation of genes implicated in the severe brain maldevelopment in MDS.     

Deleted Chromosome 20 from a patient with Alagille syndrome isolated in a cell hybrid through leucine transport selection: study of three candidate genes

Alagille syndrome (AGS) is a well-defined genetic entity assigned to the short arm of Chromosome (Chr) 20 by a series of observations of AGS patients associated with microdeletions in this region. By fusing lymphoblastoid cells of an AGS patient that exhibited a microdeletion in the short arm of Chr 20 encompassing bands p11.23 to p12.3 with rodent thermosensitive mutant cells (CHOtsH1-l) deficient in-leucyl-tRNA synthetase, we isolated a somatic cell hybrid segregating the deleted human Chr 20. This hybrid clone, designated NR2, was characterized by several methods, including PCR, with eight pairs of oligonucleotides mapped to Chr 20: D20S5, D20S41, D20S42, D20S56, D20S57, D20S58, adenosine deaminase (ADA), and Prion protein (PRIP); Restriction Fragment Length Polymorphism (RFLP) analyses with four genomic anonymous probes (D20S5, cD3H12, D20S17, D20S18); and fluorescent in situ hybridization (FISH) with total human DNA and D20Z1, a sequence specific to the human Chr 20 centromere, as probes.The NR2 hybrid allowed us to exclude three candidate genes for AGS: hepatic nuclear factor 3 (HNF3), paired box 1 (PAX1), and cystatin C (CST3) as shown by their localization outside of the deletion. The NR2 hybrid is a powerful tool for the mapping of new probes of this region, as well as for obtaining new informative probes specific for the deletion by subtractive cloning of the region. Such markers will be useful for linkage analysis and screening of cDNA libraries.     

Molecular studies of DiGeorge syndrome.

DiGeorge Syndrome (DGS) is often associated with loss of a portion of the proximal long arm of chromosome 22. Using a probe for the D22S9 locus, we have examined DNA from eight DGS cell lines and from one balanced-translocation carrier parent of a DGS proband. The D22S9 locus is deleted in four DGS patients, with deletion of 22pter----q11 because of unbalanced translocation. The locus is not deleted from three DGS probands with normal chromosomes or from two DGS probands with interstitial deletions of 22q11. The interstitial deletion DGS probands are also heterozygous for D22S43, another proximal 22q11 locus. This suggests that D22S9 and D22S43 are in a flanking but not critical region for DGS. One of the interstitial deletion DGS probands is monosomic for BCRL2 but has two copies of the flanking BCRL4 and BCR loci. Thus, the region critical to DGS (DGCR) may be in proximity to the BCRL2 locus.     

The same molecular mechanism at the maternal meiosis I produces mono- and dicentric 8p duplications.

We studied 16 cases of 8p duplications, with a karyotype 46,XX or XY,dup(8p), associated with mental retardation, facial dysmorphisms, and brain defects. We demonstrate that these 8p rearrangements can be either dicentric (6 cases) with the second centromere at the tip of the short arm or monocentric (10 cases). The distal 8p23 region, from D8S349 to the telomere, including the defensin 1 locus, is deleted in all the cases. The region spanning from D8S252 to D8S265, at the proximal 8p23 region, is present in single copy, and the remaining part of the abnormal 8 short arm is duplicated in the dicentric cases and partially duplicated in the monocentric ones. The distal edge of the duplication always spans up to D8S552 (8p23.1), while its proximal edge includes the centromere in the dicentric cases and varies from case to case in the monocentric ones. The analysis of DNA polymorphisms indicates that the rearrangement is consistently of maternal origin. In the deleted region, only paternal alleles were present in the patient. In the duplicated region, besides one paternal allele, some loci showed two different maternal alleles, while others, which were duplicated by FISH analysis, showed only one maternal allele. We hypothesize that, at maternal meiosis I, there was abnormal pairing of chromosomes 8 followed by anomalous crossover at the regions delimited by D8S552 and D8S35 and by D8S252 and D8S349, which presumably contain inverted repeated sequences. The resulting dicentric chromosome, 8qter-8p23.1(D8S552)::8p23.1-(D8S35)-8q ter, due to the presence of two centromeres, breaks at anaphase I, generating an inverted duplicated 8p, dicentric if the breakage occurs at the centromere or monocentric if it occurs between centromeres.     

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.