Chromosomal localization of 9 KOX zinc finger genes: physical linkages suggest clustering of KOX genes on chromosomes 12, 16, and 19

Nine KOX zinc finger genes were localized on four human chromosomes by in situ hybridization of cDNA probes to metaphase chromosomes. KOX1 (ZNF10), KOX11 (ZNF18), and KOX12 (ZNF19) were mapped to chromosome bands 12q24.33, 17p13-p12, and 16q22-q23, respectively. Six other KOX genes were localized on chromosome 19: KOX6 (ZNF14) and KOX13 (ZNF20) to 19p13.3-p13.2, KOX5 (ZNF13) and KOX22 (ZNF27) to 19q13.2-qter, and KOX24 (ZNF28) and KOX28 (ZNF30) to 19q13.4. Pulsed field gel electrophoresis experiments showed that the pairs of KOX genes found on the chromosome bands 12q24.33, 16q22-q23, 19p13.3-p13.2, or 19q13.3-qter lie within 200–300 kb DNA fragments. This suggests the existence of KOX gene clusters on these chromosomal bands.     

Regional Assignment of Conserved Reference Loci Anchors Unassigned Linkage and Syntenic Groups to Ovine Chromosomes

Seven loci that have been previously mapped to human and mouse chromosomes have now been regionally assigned to six sheep chromosomes. Nerve growth factor β (NGFB), antigen CD3 ζ polypeptide (CD3Z), inhibin β A (INHBA), estrogen receptor (ESR), rhodopsin (RHO), insulin-like growth factor 2 (IGF2), and myelin basic protein (MBP) were mapped by in situ hybridization to sheep chromosomes 1p24-p21, 1p14-p11, 4q26-q31, 8q25-q27, 19q23-qter, 21q21-qter, and 23q11-q12.3, respectively. ESR, RHO, IGF2, and MBP are the first markers to be assigned to their respective sheep chromosomes. These new data allow the previously unassigned sheep linkage groups H, J, K, and S to be provisionally assigned to chromosomes 21, 19, 4, and 8, respectively. The unassigned sheep syntenic groups U8 and U13 are provisionally assigned to sheep chromosomes 8 and 21, respectively. The new assignments support the emerging picture that there is extensive conservation of human chromosomal segments in the sheep and cattle genomes. The position of another evolutionary breakpoint on human chromosome 1q is suggested.     

Human chromosomal assignments for 14 argininosuccinate synthetase pseudogenes: cloned DNAs as reagents for cytogenetic analysis

There are multiple, processed, dispersed pseudogenes for human argininosuccinate synthetase. Chinese hamster X human somatic cell hybrids were used to map DNA fragment groups corresponding to the single expressed gene and 14 pseudogene loci. Each chromosomal assignment was confirmed using hybrids containing very few human chromosomes and/or by demonstrating monosomic or trisomic dosage in human cell lines with chromosomal abnormalities. Pseudogenes were mapped to chromosomes 2cen-p25, 3q12-qter, 4q21-qter, 5 (two loci), 6, 7, 9p13-q11, 9q11-q22, 11q, 12, Xp22-pter, Xq22-q26, and Ycen-q11. DNA fragments from the expressed gene were mapped to 9q34-qter in agreement with the previous assignment for enzyme activity. A high-frequency restriction fragment length polymorphism mapped to 9q11-q22. The analyses emphasized the feasibility of using chromosomally abnormal human cell lines for confirmation and regionalization of gene-mapping assignments made using somatic-cell hybrids. Conversely, cloned DNA probes, once mapped and characterized, can be very valuable for determining the chromosomal composition of interspecies hybrids and the dosage of loci in human cells. The argininosuccinate synthetase cDNA is a convenient reagent for dosage analysis of 15 human loci on 11 different chromosomes. Improved reagents could be designed that would simplify Southern blot patterns by eliminating overlapping DNA fragments and providing a single DNA fragment for each locus.     

Chromosomal assignment of retinoic acid receptor (RAR) genes in the human, mouse, and rat genomes.

The human genes encoding the alpha and beta forms of the retinoic acid receptor are known to be located on chromosomes 17 (band q21.1:RARA) and 3 (band p24:RARB). By in situ hybridization, we have now localized the gene for retinoic acid receptor gamma, RARG, on chromosome 12, band q13. We also mapped the three retinoic acid receptor genes in the mouse, by in situ hybridization, on chromosomes 11, band D (Rar-a); 14, band A (Rar-b); and 15, band F (Rar-g), respectively, and in the rat, using a panel of somatic cell hybrids that segregate rat chromosomes, on chromosomes 10 (RARA), 15 (RARB), and 7 (RARG), respectively. These assignments reveal a retention of tight linkage between RAR and HOX gene clusters. They also establish or confirm and extend the following homologies: (i) between human chromosome 17, mouse chromosome 11, and rat chromosome 10 (RARA); (ii) between human chromosome 3, mouse chromosome 14, and rat chromosome 15 (RARB); and (iii) between human chromosome 12, mouse chromosome 15, and rat chromosome 7 (RARG).     

Localization of the tumour protein, TP53, on porcine chromosome 12q12-q14

A human cDNA probe of the tumour protein p53 (TP53) was used to localize the homologous porcine gene by in situ hybridization. The gene was mapped to chromosome 12q12-q14. Together with already known mapping data, these results confirm the localization of an evolutionary conserved linkage group on porcine chromosome 12 which is localized in man on chromosome 17, in cattle on chromosome 19, and in mice on chromosome 11.     

Chromosomal localization of three human poly(A)-binding protein genes and four related pseudogenes

In humans, the poly(A)-binding proteins (PABPs) comprise a small nuclear isoform and a conserved gene family that displays at least three functional proteins: PABP1, inducible PABP (iPABP), and PABP3, plus four pseudogenes (1, 2, 3, and PABP4). In situ hybridization of PABP3 cDNA as the probe on metaphasic chromosomes have revealed five possible loci for this gene family at 2q21-q22, 13q11-q12, 12q13.3-q15, 8q22, and 3q24-q25. Amplifications of specific DNA fragments from a human-rodent somatic cell hybrid panel have allowed us to associate PABP1 and PABP3 with 8q22 and 13q11-q12, respectively. The iPABP gene has been assigned to chromosome 1. This result, compared with radiation hybrid database information, strengthens the location of this gene to 1p32-p36. The pseudogenes PABP4, 1, and 2 have been assigned to chromosomes 15, 4, and 14, respectively. Three loci detected on chromosome spreads are not associated with any amplified fragment. They might represent other related PABP genes not yet identified.     

A transcript map of an 800-kb region on human chromosome 11q13, part of the candidate region for SCA5 and BBS1

The exon-amplification method was used to identify putative transcribed sequences from an 800-kb region that includes the genes for phospholipase Cβ3 and PYGM on human chromosome 11q13. The clone contig consisted of ten cosmids, three bacterial artificial chromosomes, and one P1 artificial chromosome. A total of 83 exons were generated of which 23 were derived from known genes and expressed sequence tags (ESTs). Five different EST cDNA clones were identified and mapped on the contig. One is a homolog of the human p70S6 kinase (p70s6 k) gene whose function involves the translational regulation of ribosomal protein synthesis and thereby impacts on ribosomal biogenesis. The gene for p70s6 k is expressed universally, including within adipose cells and retina, and it could play a role in Bardet-Biedl syndrome type 1, which has been mapped to 11q13. Received: 22 July 1998 / Accepted: 24 August 1998     

Chromosomal localization of homeobox genes and associated markers on porcine Chromosomes 3, 5, 12, 15, 16 and 18: comparative mapping study with human and mouse

Four homeobox genes that belong to the four homeobox gene clusters known in mammals have been regionally assigned to four distinct porcine chromosomes in conserved regions between human and pig. HOXA11, HOXB6, HOXC8, and HOXD4 genes were mapped by radioactive in situ hybridization to porcine Chromosomes (Chrs) 18q21-24 (with a secondary signal in 16q14-21), 12p11-12, 5p11-12, and 15q22-23 respectively. Besides, we have also revealed the presence of a porcine homeobox (pig Hbx24) which, although showing DNA sequence homology with a mouse gene of HOXB cluster, was located on porcine Chr 3 (3p14-13) outside the Hox clusters. To support the identity of the homeobox gene clusters analyzed and in the light of the high sequence similarity among homeobox genes, we also localized markers known to be mapped near each Hox cluster in human. In this way, four genes were also mapped in pig: GAPD (5q12-21), GAD1 (15q21-22), INHBA (18q24), and IGFBP3 (18q24). Mapping of HOXA11, INHBA, and IGFBP3 on pig Chr 18 constitutes the first assignments of genes on this small chromosome. These new localizations extend the information on the conservation of four human chromosomal regions in the pig genome. Received: 7 August 1995 / Accepted: 16 October 1995     

Genome-wide scan and fine-mapping linkage study of androgenetic alopecia reveals a locus on chromosome 3q26

Androgenetic alopecia (AGA, male pattern baldness) is the most common form of hair loss. The origin of AGA is genetic, with the X chromosome located androgen receptor gene (AR) being the only risk gene identified to date. We present the results of a genome-wide linkage study of 95 families and linkage fine mapping of the 3q21-q29, 11q14-q25, 18p11-q23, and 19p13-q13 regions in an extended sample of 125 families of German descent. The locus with strongest evidence for linkage was mapped to 3q26 with a nonparametric linkage (NPL) score of 3.97 (empirical p value = 0.00055). This is the first step toward the identification of new susceptibility genes in AGA, a process which will provide important insights into the molecular and cellular basis of scalp hair loss.     

Ribonucleotide reductase M2 subunit sequences mapped to four different chromosomal sites in humans and mice: functional locus identified by its amplification in hydroxyurea-resistant cell lines

The sites of sequences homologous to a murine cDNA for ribonucleotide reductase (RR) subunit M2 were determined on human and murine chromosomes by Southern blot analysis of interspecies somatic cell hybrid lines and by in situ hybridization. In the human genome, four chromosomal sites carrying RRM2-related sequences were identified at 1p31----p33, 1q21----q23, 2p24----p25, and Xp11----p21. In the mouse, M2 sequences were found on chromosomes 4, 7, 12, and 13 by somatic cell hybrid studies. By Southern analysis of human hydroxyurea-resistant cells that overproduce M2 because of gene amplification, we have identified the amplified restriction fragments as those that map to chromosome 2. To further confirm the site of the functional RRM2 locus, two other cDNA clones, p5-8 and S7 (coding for ornithine decarboxylase; ODC), which are coamplified with RRM2 sequences in human and rodent hydroxyurea-resistant cell lines, were mapped by Southern and in situ hybridization. Their chromosomal map positions coincided with the region of human chromosome 2 (p24----p25) that also contains one of the four RRM2-like sequences. Since this RRM2 sequence and p5-8 and ODC are most likely part of the same amplification unit, the RRM2 structural gene can be assigned to human chromosome 2p24----p25. This region is homologous to a region of mouse chromosome 12 that also carries one of numerous ODC-like sequences. In an RRM2-overproducing mouse cell line, we found amplification of the chromosome 12-specific restriction fragments. Thus, we conclude that mouse chromosome 12 carries the functional locus for RRM2.     

Comparative mapping of mouse and rat chromosomes by fluorescence in situ hybridization

Comparative fluorescence in situ hybridization mapping using DNA libraries from flow-sorted mouse chromosomes and region-specific mouse BAC clones on rat chromosomes reveals chromosomal homologies between mouse (Mus musculus, MMU) and rat (Rattus norvegicus, RNO). Each of the MMU 2, 3, 4, 6, 7, 9, 12, 14, 15, 16, 18, 19, and X chromosomes paints only a single rat chromosome or chromosome segment and, thus, the chromosomes are largely conserved between the two species. In contrast, the painting probes for MMU chromosomes 1, 5, 8, 10, 11, 13, and 17 produce split hybridization signals in the rat, disclosing evolutionary chromosome rearrangements. Comparative mapping data delineate several large linkage groups on RNO 1, 2, 4, 7, and 14 that are conserved in human but diverged in the mouse. On the other hand, there are linkage groups in the mouse, i.e., on MMU 1, 8, 10, and 11, that are disrupted in both rat and human. In addition, we have hybridized probes for Nap2, p57, Igf2, H19, and Sh3d2c from MMU 7 to RNO 1q and found the orientation of the imprinting gene cluster and Sh3d2c to be the same in mouse and rat. Hybridization of rat genomic DNA shows blocks of (rat-specific) repetitive sequences in the pericentromeric region of RNO chromosomes 3-5, 7-13, and 20; on the short arms of RNO chromosomes 3, 12, and 13; and on the entire Y chromosome.     

Identification and localization of MEP1A-like sequences (MEP1AL1-4) in the human genome.

The human MEP1A gene encodes the meprin alpha subunit that consists of a protease domain conserved in the astacin family of metalloendopeptidases and several C-terminal interaction domains present in other proteins. Using the alpha subunit cDNA, we identified two clones from a human P1-derived artificial chromosome (PAC) library. Fluorescence in situ hybridization (FISH) mapped both PACs (1e12, 65a14) to chromosome 6p21, confirming the MEP1A location. FISH also mapped PAC 65a14 to chromosome 13cen, and to chromosome 9 in three different regions, 9p12-13, 9q21, and 9q22. Southern blot analysis showed that sequences of PAC 65a14 and MEP1A were similar in the 3' end but different in the 5' end, revealing for the first time that the human genome may encode multiple interaction domains highly similar to those of the meprin alpha subunit. The symbols of MEP1AL1, MEP1AL2, MEP1AL3, and MEP1AL4 have been designated for MEP1A-like sequences on 9p12-13, 9q21, 9q22, and 13cen, respectively.     

Confirmation of the localization of the human recombination activating gene 1 (RAG1) to chromosome 11p13

The human recombination activating gene 1 (RAG1) has previously been mapped to chromosomes 14q and 11p. Here we confirm the chromosome 11 assignment by two independent approaches: autoradiographic and fluorescence in situ hybridization to metaphase spreads and analysis of human-hamster somatic cell hybrid DNA by the polymerase chain reaction (PCR) and Southern blotting. Our results unequivocally localize RAG1 to 11p13.     

The human islet amyloid polypeptide (IAPP) gene. Organization, chromosomal localization and functional identification of a promoter region

We report the isolation and characterization of the human gene encoding islet amyloid polypeptide (IAPP). Previously characterized cDNA sequences correspond to three exons of which the first is noncoding. A functional promoter region was identified in the 5' flanking DNA; however, this was farther upstream than expected. Northern blot analysis of human insulinoma RNA revealed three IAPP mRNAs of sizes 1.2, 1.8 and 2.1 kb, in agreement with three polyadenylation signals present in the 3' end of the gene. In situ hybridization to metaphase chromosomes resulted in two distinct peaks on chromosome 12, at 12p12-p13 and 12q13-q14. Southern blot analysis of genomic DNA suggested a single IAPP locus but also indicated the presence of additional homologous sequences in human genomic DNA.     

Molecular cytogenetic analysis of follicular lymphoma (FL) provides detailed characterization of chromosomal instability associated with the t(14;18)(q32;q21) positive and negative subsets and histologic progression

We analyzed a cohort of 61 follicular lymphomas (FL) with an abnormal G-banded karyotype by spectral karyotyping (SKY) to better define the chromosome instability associated with the t(14;18)(q32;q21) positive and negative subsets of FL and histologic grade. In more than 70% of the patients, SKY provided additional cytogenetic information and up to 40% of the structural abnormalities were revised. The six most frequent breakpoints in both SKY and G-banding analyses were 14q32, 18q21, 3q27, 1q11-q21, 6q11-q15 and 1p36 (15-77%). SKY detected nine additional sites (1p11-p13, 2p11-p13, 6q21, 8q24, 6q21, 9p13, 10q22-q24, 12q11-q13 and 17q11-q21) at an incidence of >10%. In addition to the known recurring translocations, t(14;18)(q32;q21) [70%], t(3;14)(q27;q32) [10%], t(1;14)(q21;q32) [5%] and t(8;14)(q24;q32) [2%] and their variants, 125 non-IG gene translocations were identified of which four were recurrent within this series. In contrast to G-banding analysis, SKY revealed a greater degree of karyotypic instability in the t(14;18) (q32;q21) negative subset compared to the t(14;18)(q32;q21) positive subset. Translocations of 3q27 and gains of chromosome 1 were significantly more frequent in the former subset. SKY also allowed a better definition of chromosomal imbalances, thus 37% of the deletions detected by G-banding were shown to be unbalanced translocations leading to gain of genetic material. The majority of recurring (>10%) imbalances were detected at a greater (2-3 fold) incidence by SKY and several regions were narrowed down, notably at gain 2p13-p21, 2q11-q21, 2q31-q37, 12q12-q15, 17q21-q25 and 18q21. Chromosomal abnormalities among the different histologic grades were consistent with an evolution from low to high grade disease and breaks at 6q11-q15 and 8q24 and gain of 7/7q and 8/8q associated significantly with histologic progression. This study also indicates that in addition to gains and losses, non-IG gene translocations involving 1p11-p13, 1p36, 1q11-q21, 8q24, 9p13, and 17q11-q21 play an important role in the histologic progression of FL with t(14;18)(q32;q21) and t(3q27).     

Genomic organization, chromosomal localization, and independent expression of human cyclin D genes.

Murine cDNA clones for three cyclin D genes that are normally expressed during the G1 phase of the cell cycle were used to clone the cognate human genes. Bacteriophage and cosmid clones encompassing five independent genomic loci were partially sequenced and chromosomally assigned by an analysis of somatic cell hybrids containing different human chromosomes and by fluorescence in situ hybridization to metaphase spreads from normal peripheral blood lymphocytes. The human cyclin D1 gene (approved gene symbol, CCND1) was assigned to chromosome band 11q13, cyclin D2 (CCND2) to chromosome band 12p13, and cyclin D3 (CCND3) to chromosome band 6p21. Pseudogenes containing sequences related to cyclin D2 and cyclin D3 mapped to chromosome bands 11q13 and 6p21, respectively. Partial nucleotide sequence analysis of exons within each gene revealed that the authentic human cyclin D genes are more related to their mouse counterparts than to each other. These genes are ubiquitously transcribed in human tumor cell lines derived from different cell lineages, but are independently and, in many cases, redundantly expressed. The complex patterns of expression of individual cyclin D genes and their evolutionary conservation across species suggest that each family member may play a distinct role in cell cycle progression.     

An ultrahigh-sulphur keratin gene of the human hair cuticle is located at 11q13 and cross-hybridizes with sequences at 11p15

A human hair cuticle ultrahigh-sulphur keratin (UHSK) gene (KRN1) has been mapped by Southern analysis of a somatic cell hybrid panel and by in situ hybridization. A probe containing the coding region of this gene mapped to 11pter->11q21 using the hybrid cell panel and on in situ hybridization mapped to two regions on chromosome 11: the distal part of 11p15, most likely 11p15.5, and the distal part of 11q13, most likely 11q13.5. A probe from the 3 non-coding region of KRN1 mapped to 11q13.5 indicating that this was the map location of the cloned gene. The sequence of 11p15.5 is termed KRN1-like (KRN1L). The results reveal that the cuticle UHSK gene family is clustered in the human genome. Present address: The Institute of Molecular Medicine, John Radcliffe Hospital, Headington, Oxford, OX3, 9DU, United Kingdom.     

ZOO-FISH Suggests a Complete Homology between Human and Capuchin Monkey (Platyrrhini) Euchromatin

Chromosome comparisons usingin situhybridization of all human chromosome-specific libraries on Capuchin monkey (Cebus capucinus,Cebidae, Platyrrhini) metaphases were performed with a new technique simultaneously revealing a G-banding and chromosome “painting.” A complete homology between human (HSA) andC. capucinus(CCA) chromosomes was demonstrated, except for constitutive heterochromatin. ElevenC. capucinuschromosomes are homologous to 11 human chromosomes: CCA 2 = HSA 4; CCA 3 = HSA 6; CCA 12 = HSA 9; CCA 16 = HSA 11; CCA 10 = HSA 12; CCA 11 = HSA 13; CCA 20 = HSA 17; CCA 8 = HSA 19; CCA 23 = HSA 20; CCA 24 = HSA 22; and CCA X = HSA X. TenC. capucinuschromosomes are homologous to parts of human chromosomes: CCA 13 = HSA 8q; CCA 14 = HSA 2q; CCA 15 = HSA 1p + 1q proximal; CCA 17 = HSA 7 part; CCA 18 and 19 = HSA 3 part; CCA 21 and 22 = HSA 1q distal; CCA 25 = HSA 10p; and CCA 26 = HSA 15q part. SixC. capucinuschromosomes are homologous to parts of two human chromosomes: CCA 1 = HSA 5 + 7 part; CCA 4 = HSA 2p + q proximal + 16q; CCA 5 = HSA 10q + 16p; CCA 6 = HSA 14 + 15 part; CCA 7 = HSA 8p + 18; and CCA 9 = HSA 3 part + 21. Many previous banding comparisons were confirmed but several cryptic or complex rearrangements could be identified. With theC. capucinuskaryotype having been shown to be fairly ancestral, this comparison opens the possibility to compare human chromosomes to most Cebidae species.     

Eukaryotic translation termination factor gene (ETF1/eRF1) maps at D5S500 in a commonly deleted region of chromosome 5q31 in malignant myeloid diseases

The human genome contains four ETF1 (eukaryotic translation termination factor 1) homologous sequences, localized on chromosomes 5, 6, 7 and X, and corresponding to a functional gene on chromosome 5 and three processed pseudogenes on the other chromosomes. ETF1 genomic or cDNA probes were mapped by fluorescence in situ hybridization to 5q31, 6p21, 7q11 and Xp11.4-->p11.1. A microsatellite marker (D5S500) was identified in intron 7 of the functional ETF1 gene providing its exact position in the 5q31 band. Thus, the ETF1 gene is located in a 5q region which contains unidentified genes responsible for genetic or malignant disorders, and it might be considered as a candidate gene involved in the pathogenesis of these diseases.