Identification of 10 murine homeobox genes.

In Drosophila a number of genes important in establishing segmentation patterns and in determining segment identities have been shown to carry the homeobox sequence. Over 30 murine homeobox genes have been cloned, many on the basis of sequence homology to Drosophila prototypes. Here we report the cloning and sequencing of 10 new and 6 previously known homeobox genes by screening a murine genomic library with a 768-fold degenerate oligonucleotide corresponding to the most conserved 8-amino acid motif in the recognition helix of the homeodomain. Eight of these new homeobox genes have been chromosomally mapped. Four genes do not belong to any of the known homeobox gene clusters but instead map to new locations on chromosome 1 (single gene) and chromosome 5 (three genes). Sequence comparisons indicate that two of these are very closely related and represent a distinct new category of homeobox genes. The remaining four mapped genes reside in previously established murine homeobox gene clusters. Specifically, two map to the cluster HOX-1 on chromosome 6 and one each to HOX-3 and HOX-4 on chromosome 15 and 2, respectively. The ratio of newly identified homeobox genes to the previously characterized murine homeobox genes suggests that there remain several uncharacterized homeobox genes in the murine genome.     

A novel human homeobox gene lies at the chromosome 10 breakpoint in lymphoid neoplasias with chromosomal translocation t(10;14).

The translocation t(10;14)(q24;q11) is an acquired change seen in 4% to 7% of T-cell acute lymphoblastic leukemias (T-ALL). We previously demonstrated that the translocation juxtaposes the T-cell receptor (TCR) delta-chain gene in chromosome 14q11 with a novel region in chromosome 10q24 and is likely catalyzed by recombinases normally involved in the generation of immunoglobulin and TCR diversity. We now present the sequence of a gene on chromosome 10 that lies immediately telomeric of the breakpoints in nine new ALL patients with acquired rearrangements in 10q24. The gene is a novel human homeobox gene and is expressed in leukemic cells from ALL patients with rearrangements in a defined chromosome 10 breakpoint cluster region, but not in other adult tissues or cell lines. This new gene has been designated HOX11. Our results strongly support a role for homeobox genes in oncogenesis and may represent the first example of a human cancer in which deregulated expression of an unaltered homeobox gene is involved in tumorigenesis.     

Detection of homeobox genes in development and evolution.

The homeobox genes encode a family of DNA-binding regulatory proteins whose function and genomic organization make them an important model system for the study of development and differentiation. Oligonucleotide primers corresponding to highly conserved regions of Antennapediaclass homeodomains were designed to detect and identify homeobox sequences in populations of DNA or RNA by means of the polymerase chain reaction (PCR). Here we present a survey of sequences detected by PCR using an initial set of primers (HoxA and HoxB) based on an early nucleotide consensus for vertebrate Antennapedia-class homeodomains. Several novel sequences are reported from both mouse genomic DNA and RNA from the developing mouse telencephalon. Forebrain-derived clones are similar to the chicken CHox7, Drosophila H2.0, and mouse Hlx genes. PCR also proved to be a rapid method for identifying homeobox sequences from diverse metazoan species. Cloning of three Antennapedia-related sequences from cnidarians provides evidence of ancient roles for homeobox genes early in metazoan evolution.     

Transcript encoded on the opposite strand of the human steroid 21-hydroxylase/complement component C4 gene locus

The gene encoding human adrenal steroid 21-hydroxylase (P450c21) and its highly similar pseudogene are duplicated in tandem with the two genes encoding the fourth component of human serum hemolytic complement (C4). This 60-kilobase gene complex, which lies within the major histocompatibility complex on the short arm of human chromosome 6, has been studied in considerable detail because genetic disorders in steroid 21-hydroxylation and in C4 are common. We have cloned a cDNA encoded by a previously unidentified gene in this region. This gene lies on the strand of DNA opposite from the strand containing the P450c21 and C4 genes, and it overlaps the last exon of P450c21. The newly identified gene encodes mRNAs of 3.5 and 1.8 kilobases that are expressed in the adrenal and in a Leydig cell tumor but are not expressed in nonsteroidogenic tissues. The sequence of the longest cDNA (2.7 kilobases) shows no similarity to known sequences available in two computerized data bases. The 5' end of this sequence is characterized by three repeats, each encoding about 100 amino acids flanked by potential sites for proteolytic cleavage. Although numerous studies have shown that gene deletions causing congenital adrenal hyperplasia occur in this region, none of these gene deletions extends into this newly identified gene, suggesting that it encodes an essential function.     

Cloning and characterization of two members of the vertebrate Dlx gene family.

A number of vertebrate genes of the Dlx gene family have been cloned in mouse, frog, and zebrafish. These genes contain a homeobox related to that of Distalless, a gene expressed in the developing head and limbs of Drosophila embryos. We cloned and studied the expression of two members of this family, which we named Dlx5 and Dlx6, in human and mouse. The two human genes, DLX5 and DLX6, are closely linked in an inverted convergent configuration in a region of chromosome 7, at 7q22. Similarly, the two human genes DLX1 and DLX2 are closely linked in a convergent configuration at 2q32, near the HOXD (previously HOX4) locus. In situ hybridization experiments in mouse embryos revealed expression of Dlx5 and Dlx6 mRNA in restricted regions of ventral diencephalon and basal telencephalon, with a distribution very similar to that reported for Dlx1 and Dlx2 mRNA. A surprising feature of Dlx5 and Dlx6 is that they are also expressed in all skeletal structures of midgestation embryos after the first cartilage formation. The expression pattern of these genes, together with their chromosome localization, may provide useful cues for the study of congenital disorders in which there is a combination of craniofacial and limb defects.     

cDNA cloning of a liver isoform of the phosphorylase kinase alpha subunit and mapping of the gene to Xp22.2-p22.1, the region of human X-linked liver glycogenosis.

We have cloned cDNA molecules encoding another isoform of the alpha subunit of phosphorylase kinase (ATP:phosphorylase-b phosphotransferase, EC 2.7.1.38). Sequence comparison with the previously characterized muscle isoform reveals a pattern of highly conserved and variable domains and demonstrates that the isoforms are the products of distinct genes. In contrast to the muscle isoform gene, PHKA1, the gene of this additional isoform, PHKA2, is predominantly expressed in liver and other nonmuscle tissues. It was mapped to the distal short arm of the human X chromosome (Xp22.2-p22.1), the same region to which human X-linked liver glycogenosis due to phosphorylase kinase deficiency has been mapped. Thus, X-linked liver glycogenosis is probably caused by mutations affecting PHKA2.     

Allelotyping of butadiene-induced lung and mammary adenocarcinomas of B6C3F1 mice: frequent losses of heterozygosity in regions homologous to human tumor-suppressor genes.

To identify the potential involvement of tumor-suppressor gene inactivation during neoplastic development in B6C3F1 mice, genetic losses were determined from allelotypes of butadiene-induced lung and mammary adenocarcinomas. By using length polymorphisms in restriction fragments and simple sequence repeats, or "microsatellites," markers on each autosome were analyzed for allele losses in tumor DNAs. Losses of heterozygosity on chromosome 11 were observed at several loci surrounding the p53 tumor-suppressor gene (Trp53) in 12 of 17 mammary tumors and 2 of 8 lung tumors. Although most of these alterations appeared to result from nondisjunction, at least two examples of somatic recombination or deletion were also observed. Southern analysis revealed a homozygous deletion of the remaining Trp53 allele of one of these mammary tumors. Losses of heterozygosity were also detected at the Rb-1 tumor-suppressor gene in 7 of 17 mammary tumors and 1 lung tumor. Finally, frequent allele losses were observed on chromosome 4 in lung tumors. Analysis of nine chromosome 4 loci defined an interstitial deletion containing the Ifa gene cluster in one of the lung tumors. A tumor-suppressor gene was previously mapped to this region of chromosome 4 in studies with somatic cell hybrids. In addition, homozygous deletions have been reported in a homologous region of human chromosome 9p for acute lymphocytic leukemias, glioblastomas, melanomas, and lung carcinomas. These findings suggest that the inactivation of tumor-suppressor genes including Trp53, Rb-1, and an unidentified gene on chromosome 4 plays a significant role during carcinogenesis in mice.     

Homez,a homeobox leucine zipper gene specific to the vertebrate lineage

This work describes a vertebrate homeobox gene, designated Homez (homeodomain leucine zipper-encoding gene), that encodes a protein with an unusual structural organization. There are several regions within Homez, including three atypical homeodomains, two leucine zipper-like motifs, and an acidic domain. The gene is ubiquitously expressed in human and murine tissues, although the expression pattern is more restricted during mouse development. Genomic analysis revealed that human and mouse genes are located at 14q11.2 and 14C, respectively, and are composed of two exons. The zebrafish and pufferfish homologs share high similarity to mammalian sequences, particularly within the homeodomain sequences. Based on homology of homeodomains and on the similarity in overall protein structure, we delineate Homez and members of ZHX family of zinc finger homeodomain factors as a subset within the superfamily of homeobox-containing proteins. The type and composition of homeodomains in the Homez subfamily are vertebrate-specific. Phylogenetic analysis indicates that Homez lineage was separated from related genes >400 million years ago before separation of ray- and lobe-finned fishes. We apply a duplication-degeneration-complementation model to explain how this family of genes has evolved.     

The gene for the alpha 4 subunit of the VLA-4 integrin maps to chromosome 2Q31-32

The VLA-4 integrin (CD49d/CD29), initially discovered on lymphoid cells, is actually known to be highly expressed on T cells, B cells, monocytes, and derived cell lines. Unlike other VLA integrins, mainly involved in cell-matrix adhesive interactions, VLA-4 has also been implicated in several cellular interactions. Based on the published alpha 4 cDNA sequence, a 1,142-bp alpha 4 cDNA fragment was amplified using the polymerase chain reaction. This fragment was used to isolate three overlapping genomic clones from a phage library. By Southern analysis with the cDNA probe, and using the polymerase chain reaction on DNA isolated from a panel of human/mouse somatic cell hybrids, the alpha 4 gene was mapped to chromosome 2. Fluorescence in situ hybridization confirmed this assignment and allowed a more precise mapping to chromosome 2q31-32.     

Mapping of four simple sequence repeat (SSR) markers on rat chromosome 4.

We previously reported that several markers on rat chromosome (Chr) 4 cosegregated with the occurrence of cerebral stroke and brain edema in stroke-prone spontaneously hypertensive rats (SHRSP). To obtain insights into the positional candidate genes for stroke susceptibility in this region, we mapped four genes, Taurine transporter (Tau), tumor necrosis factor receptor (Tnfr), GABA transporter (Gat1) and glucose transporter-3 (Glut3) genes, using newly developed simple sequence repeat (SSR) markers on rat Chr 4. We isolated the SSRs for the genes either by screening a rat genomic library or by searching the GenBank database. By linkage analysis using two sets of backcrosses, Gat1 and Tnfr were mapped in the region associated with stroke, while Taut was located distant from the region. The Glut3 locus was also assigned to rat Chr 4 using a rat x mouse hybrid clone panel. These results indicated that the Tnfr, Gat1 and Glut3 genes were good positional candidates for the stroke susceptibility in SHRSP, suggesting that further evaluation of these genes by functional studies could prove useful.     

Human thrombopoietin: gene structure, cDNA sequence, expression, and chromosomal localization.

Thrombopoietin (TPO), a lineage-specific cytokine affecting the proliferation and maturation of megakaryocytes from committed progenitor cells, is believed to be the major physiological regulator of circulating platelet levels. Recently we have isolated a cDNA encoding a ligand for the murine c-mpl protooncogene and shown it to be TPO. By employing a murine cDNA probe, we have isolated a gene encoding human TPO from a human genomic library. The TPO locus spans over 6 kb and has a structure similar to that of the erythropoietin gene (EPO). Southern blot analysis of human genomic DNA reveals a hybridization pattern consistent with a single gene locus. The locus was mapped by in situ hybridization of metaphase chromosome preparations to chromosome 3q26-27, a site where a number of chromosomal abnormalities associated with thrombocythemia in cases of acute myeloid leukemia have been mapped. A human TPO cDNA was isolated by PCR from kidney mRNA. The cDNA encodes a protein with 80% identity to previously described murine TPO and is capable of initiating a proliferative signal to murine interleukin 3-dependent BaF3 cells expressing the murine or human TPO receptor.     

Assignment of the gene coding for the T3-delta subunit of the T3-T-cell receptor complex to the long arm of human chromosome 11 and to mouse chromosome 9.

The gene encoding the 20-kDa glycoprotein of the T3-T-cell receptor complex (T3-delta chain) has been mapped to human chromosome 11 by hybridization of a T3-delta cDNA clone (pPGBC#9) to DNA from a panel of human-rodent somatic cell hybrids. In Southern blotting experiments with DNAs of somatic cell hybrids that contained segments of chromosome 11, we were able to assign the T3-delta gene to the distal portion of the long arm of human chromosome 11 (11q23-11qter). By use of a newly developed cDNA clone (pPEM-T3 delta) that codes for the murine T3-delta chain, the mouse T3-delta gene was mapped on chromosome 9. The importance of the T3-delta map position and its relationship to the other genes on the long arm of human chromosome 11 and to those on mouse chromosome 9 is discussed.