A 3-Mb Contig from D11S987 to MLK3, a Gene-Rich Region in 11q13

We have combined genetic, radiation-reduced somatic cell hybrid (RRH), fluorescent in situ hybridization (FISH), and physical mapping methods to generate a contig of overlapping YAC, PAC, and cosmid clones corresponding to >3 continuous Mb in 11q13. A total of 15 STSs [7 genes (GSTP1, ACTN, PC, MLK3, FRA1, SEA, HNP36), 4 polymorphic loci (D11S807, D11S987, GSTP1, D11S913), 3 ESTs (D11S1956E, D11S951E, and WI-12191), and 1 anonymous STS (D11S703)], mapping to three independent RRH segregation groups, identified 26 YAC, 7 PAC, and 16 cosmid clones from the CGM, Roswell Park, CEPH Mark I, and CEPH MegaYAC YAC libraries, a 5 genome equivalent PAC library, and a chromosome 11-specific cosmid library. Thirty-six Alu–PCR products derived from 10 anonymous bacteriophage λ clones, a cosmid containing the polymorphic marker D11S460, or STS-positive YAC or cosmid clones were identified and used to screen selected libraries by hybridization, resulting in the identification of 19 additional clones. The integrity and relative position of a subset of clones was confirmed by FISH and were found to be consistent with the physical and RRH mapping results. The combination of STS and Alu–PCR-based approaches has proven to be successful in attaining contiguous cloned coverage in this very GC-rich region, thereby establishing for the first time the absolute order and distance between the markers: CEN–MLK3–(D11S1956E/D11S951E/WI-12191)–FRA1–D11S460–SEA–HNP36/D11S913–ACTN–PCD11S703–GSTP1–D11S987–TEL.     

Mapping of a new MAP kinase activated protein kinase gene (3PK) to human chromosome band 3p21.2 and ordering of 3PK and two cosmid markers in the 3p22–p21 tumour-suppressor region by two-colour fluorescencein situ hybridization

ANotl-linking clone NL1-210 (D3S1656) that contains the human MAP kinase activated protein kinase (3PK) gene was localized to 3p21.2 on DAPI-banded and propidium iodide (R-bands)-stained chromosomes by fluorescencein situ hybridization (FISH). For more precise localization of 3PK, two cosmid probes were used as a frame. In order to establish this frame, twoNotl-linking clones, NL2-008 (D3S1648) and NL3-003 (D3S3872) were used to screen the cosmid library for locus extension. They mapped to 3p21 and were found to belong to two separate contigs ofNotl-jumping and linking clones. Using FISH on DAPI-banded metaphase chromosomes, we have determined the precise localization of cosNL2-008 and cosNL3-003 to 3p21.2–p21.1 and 3p22–p21.3 respectively. The 3PK gene was localized to the 3p21.2 region within this frame by two-colour FISH. The orientation of the probes are tel-D3S3872-3PK-D3S1648-cen.accepted for publication by G. Sutherland     

Finding new human minisatellite sequences in the vicinity of long CA-rich sequences.

Microsatellites and minisatellites are two classes of tandem repeat sequences differing in their size, mutation processes, and chromosomal distribution. The boundary between the two classes is not defined. We have developed a convenient, hybridization-based human library screening procedure able to detect long CA-rich sequences. Analysis of cosmid clones derived from a chromosome 1 library show that cross-hybridizing sequences tested are imperfect CA-rich sequences, some of them showing a minisatellite organization. All but one of the 13 positive chromosome 1 clones studied are localized in chromosomal bands to which minisatellites have previously been assigned, such as the 1pter cluster. To test the applicability of the procedure to minisatellite detection on a larger scale, we then used a large-insert whole-genome PAC library. Altogether, 22 new minisatellites have been identified in positive PAC and cosmid clones and 20 of them are telomeric. Among the 42 positive PAC clones localized within the human genome by FISH and/or linkage analysis, 25 (60%) are assigned to a terminal band of the karyotype, 4 (9%) are juxtacentromeric, and 13 (31%) are interstitial. The localization of at least two of the interstitial PAC clones corresponds to previously characterized minisatellite-containing regions and/or ancestrally telomeric bands, in agreement with this minisatellite-like distribution. The data obtained are in close agreement with the parallel investigation of human genome sequence data and suggest that long human (CA)s are imperfect CA repeats belonging to the minisatellite class of sequences. This approach provides a new tool to efficiently target genomic clones originating from subtelomeric domains, from which minisatellite sequences can readily be obtained. [The sequence data described in this paper have been submitted to the EMBL data library under accession nos. AJ000377-AJ000383.]     

HOXA gene cluster rearrangement in a t(7;9)(p15;q34) in a child with MDS

We describe the molecular characterization of a t(7;9)(p15;q34) found in a 15-month-old female patient, diagnosed with refractory anemia with excess blasts in transformation (RAEBt), in progression to acute myeloid leukemia (AML) M7. Molecular characterization of the 7p15 breakpoint showed that this was localized within a fully sequenced PAC clone RP1-170O19 containing the HOXA4 to HOXA13 genes and the EVX1 gene. The 9q34 breakpoint was mapped distal to ABL1 and proximal to NOTCH1 excluding their involvement as fusion gene partners. Our findings suggest a causal role for HOXA genes in childhood myelodysplasia and warrant investigation of this locus in a larger series of patients.     

A high resolution physical map of 2.5 Mbp of the Down syndrome region on chromosome 21

The region surrounding D21S55 in band 21q22 of human chromosome21 has been implicated in the etiology of Down syndrome (DS).In this paper, we report the construction of a high resolutionmap of a 2.5 Mb region around the marker D21S55. Characterizationof YAC clones by accurate size determination, end isolationand marker assignment was used to build a refined YAC-basedmap. The YAC clones were then used to isolate 284 cosmid clones,covering 2.3 Mb, from a chromosome 21-specific cosmid library.The cosmid clones were ordered into overlapping groups and arestriction map of each group was determined. The groups ofcosmids were then ordered and oriented with respect to the YAC-basedmap. This high resolution map provides the framework for furtheranalysis of the region by transcribed sequence mapping and sequencedetermination.     

Physical map of a 1.5 mb region on 12p11.2 harbouring a synpolydactyly associated chromosomal breakpoint

Synpolydactyly (SPD) is a rare malformation of the distal limbs known to be caused by mutations in HOXD13. We have previously described a complex form of SPD associated with synostoses in three members of a Belgian family, which co-segregates with a t(12;22)(p11.2;q13.3) chromosomal translocation. The chromosome 12 breakpoint of this translocation maps to 12p11.2 between markers D12S1034 and D12S1596. Here we show that a mutation in the HOXD13 gene is not responsible for the phenotype, and present a physical map of the region around the 12p11.2 breakpoint. Starting from D12S1034 and D12S1596, we have established a contig approximately 1.5 Mb in length, containing 13 YAC clones, 16 BAC clones, and 11 cosmid clones. FISH analysis shows that cosmid LL12NCO1-149H4 maps across the breakpoint, and Southern blot experiments using fragments of this cosmid as probes identify a rearranged BamHI fragment in the patients carrying the translocation. A search for expressed sequences within the contig have so far revealed one CpG island, seven anonymous ESTs and three previously characterised genes, DAD-R, KRAG and HT21, all of which were found not to be directly disrupted by the translocation. The gene represented by EST R72964 was found to be disrupted by the translocation. These findings lay the groundwork for further efforts to characterise a gene critical for normal distal limb development that is perturbed by this translocation.     

The isolation of a yeast artificial chromosome (YAC) contig extending for 2 megabases in the vicinity of the Von Hippel Lindau disease gene

Von Hippel LIndau disease (VHL) is a rare autosomal dominantdisease associated with tumors and cysts in multiple organ systems.The VHL disease gene is tightly linked to the polymorphic DNAmarker 233E2 (D3S720) and flanked by 479H4 (D3S719) on its telomericand RAF1 on its centromeric side. Two additional markers, D3S1038and D3S601, have also been identified, and these markers, likeD3S720, are very tightly linked to VHL. Previously 93 cosmidclones were mapped to the larger region, 3p24.2 - pter, surroundingthe VHL disease gene (1). Using a Southern-based screening strategyon pools of YAC clones we have Isolated a contig of overlappingYAC clones that extends about 0.7 megabase centromeric, andabout 1.3 megabases telomeric of D3S720 and contains all threetightly linked VHL markers. Individual YACs In this contig werehybridized to grids containing cosmids localized between 3p24.2-pterand to several cosmids localized by fluorescent in situ hybridization(FISH) to 3p25. A total of 28 cosmids were positioned on thiscontig of overlapping YAC clones. We have also identified homologousYAC clones to many additional cosmid clones localized between3p24.2–p25, although these have not yet been preciselylocalized relative to the contig of YAC clones. This contigof YAC clones probably contains the VHL disease gene and shouldfacilitate the isolation and characterization of this gene.     

Characterization of the human HOX 7 cDNA and identification of polymorphic markers.

cDNA clones for a human HOX 7 gene obtained with homologous clones of Drosophila were used in human gene mapping studies. The human cDNA clone was isolated from a library constructed from human embryonic craniofacial material. The sequence of the cDNA demonstrates significant homology with mouse HOX 7. A search for RFLPs identified MboII and BstEII variants. A CA dinucleotide repeat with 5 alleles was also identified and allowed placement of HOX 7 into a defined linkage map. Evidence for linkage disequilibrium was found with markers tested. These results place the human HOX 7 gene in a defined position on 4p.     

Mapping of the breakpoints on the short arm of chromosome 17 in neoplasms with an i(17q).

Isochromosomes are monocentric or dicentric chromosomes with homologous arms that are attached in a reverse configuration as mirror images. With an incidence of 3-4%, the i(17q) represents the most frequent isochromosome in human cancer. It is found in a variety of tumors, particularly in blast crisis of chronic myeloid leukemia (CML-BC), acute myeloid leukemia (AML), non-Hodgkin's lymphoma (NHL), and medulloblastoma (MB), and indicates a poor prognosis. To determine the breakpoints on the molecular genetic level, we analyzed 18 neoplasms (six CML, four AML, one NHL, and seven MB) with an i(17q) and two MB with a pure del(17p) applying fluorescence in situ hybridization (FISH) with yeast artificial chromosome (YAC) clones, P1-artificial chromosome (PAC) clones, and cosmids from a well-characterized contig covering more than 6 Mb of genomic DNA. We identified four different breakpoint cluster regions. One is located close to or within the centromere of chromosome 17 and a second in the Charcot-Marie-Tooth (CMT1A) region at 17(p11.2). A third breakpoint was found telomeric to the CMT1A region. The fourth, most common breakpoint was detected in MB, AML, and in CML-BC specimens and was bordered by two adjacent cosmid clones (clones D14149 and M0140) within the Smith-Magenis syndrome (SMS) region. These results indicate that the low copy number repeat gene clusters which are present in the CMT and SMS regions may be one of the factors for the increased instability that may trigger the formation of an i(17q).     

Linkage of blepharophimosis syndrome in a large Indian pedigree to chromosome 7p

Blepharophimosis syndrome (BPES) is an autosomal dominant disorder involving abnormal eyelid development. Cytogenetic and linkage analyses have previously implicated the chromosome 3q23 region in multiple cases of this syndrome. However, in a few cases cytogenetic analyses have implicated other chromosomal regions in this condition. Here we report linkage of BPES in a large Indian pedigree to chromosome 7p13-p21; affected only two-point and multipoint analyses using D7S488, D7S2551 and D7S2562 both showed peak lod scores of 3.61 coincident with D7S2562. Recombinations in affected individuals placed the critical region between D7S488 and D7S629. When both affected and unaffected individuals were considered, a maximum two-point lod score of 3.38 at theta = 0.08 was obtained with D7S2551 while a peak multipoint lod score of 3.64 was obtained between D7S488 and D7S2551. Segregation analysis revealed two unaffected individuals carrying the affected haplotype accounted for the difference in peak, relative to the affected only analysis. The chromosome 7p candidate genes inhibin beta A and epidermal growth factor receptor map outside this region whereas the HOX1 gene cluster may map inside this region. Although BPES is sometimes associated with female infertility due to premature ovarian failure, in the current family affected females were fertile. The current finding together with the previous evidence implicating chromosome 3q2 provides strong evidence that BPES involves locus heterogeneity; this point should be considered when counselling affected families.      

Craniosynostosis and hemizygosity for D7S135 caused by a de novo and apparently balanced t(6;7) translocation

Craniosynostosis (CRS) is frequently seen in the del(7p) syndrome, and the gene for this cranial anomaly (CRS1) has been assigned to 7p21. We present a 3-year-old boy with CRS involving the sagittal and coronal sutures, who had a de novo and apparently balanced translocation, t(6;7)(q16.2;p15.3). Southern blot analysis of several loci on 7p14 → pter showed that the patient was heterozygous for HOX1I and IL6, possibly homozygous for D7S149, but hemizygous for D7S135 with a loss of the paternal allele. These findings suggest the localization of a candidate gene for CRS1 to be on 7p15.3 in the close proximity to the D7S135 locus. © 1994 Wiley-Liss, Inc.     

HOXA10 controls proliferation,migration and invasion in oral squamous cell carcinoma

Although HOX genes are best known for acting in the regulation of important events during embryogenesis, including proliferation, differentiation and migration, alterations in their expression patterns have been frequently described in cancers. In previous studies we analyzed the expression profile of the members of the HOX family of homeobox genes in oral samples of normal mucosa and squamous cell carcinoma (OSCC) and identified differently expressed genes such as HOXA10. The present study aimed to validate the increased expression of HOXA10 in OSCCs, and to investigate the effects arising from its knockdown in OSCC cells. The levels of HOXA10 mRNA were determined in human OSCC samples and cell lines by quantitative PCR, and HOXA10-mediated effects on proliferation, apoptosis, adhesion, epithelial-mesenchymal transition (EMT), migration and invasion were studied in HSC-3 tongue carcinoma cells by using retrovirus-mediated RNA interference. Higher expression of HOXA10 mRNA was observed in OSCC cell lines and in tumor tissues compared to normal controls. HOXA10 knockdown significantly reduced the proliferation of the tumor cells which was accompanied by increased levels of p21. HOXA10 silencing also significantly induced the expression of EMT markers and enhanced the adhesion, migration and invasion of HSC-3 cells. No effects on cell death were observed after HOXA10 knockdown. The results of the current study confirm the overexpression of HOXA10 in OSCCs, and further demonstrate that its expression is functionally associated with several important biological processes related to oral tumorigenesis, such as proliferation, migration and invasion.