A retrotransposon-derived gene, PEG10, is a novel imprinted gene located on human chromosome 7q21

A novel paternally expressed imprinted gene, PEG10 (Paternally Expressed 10), was identified on human chromosome 7q21. PEG10 is located near the SGCE (Sarcoglycan epsilon) gene, whose mouse homologue was recently shown to be imprinted. Therefore, it is highly possible that a new imprinted gene cluster exists on human chromosome 7q21. Analysis of two predicted open reading frames (ORF1 and ORF2) revealed that ORF1 and ORF2 have homology to the gag and pol proteins of some vertebrate retrotransposons, respectively. These data suggest that PEG10 is derived from a retrotransposon that was previously integrated into the mammalian genome. PEG10 is likely to be essential for understanding how exogenous genes become imprinted.     

The gene for human carbonic anhydrase II (CA2) is located at chromosome 8q22

The gene CA2 for the human carbonic anhydrase II isozyme is encoded in band q22 of chromosome 8. These data and supporting evidence predict that the genes for carbonic anhydrase I and III are also physically closely linked in this chromosomal region.     

The human dopamine D2 receptor gene is located on chromosome 11 at q22-q23 and identifies a TaqI RFLP.

Human dopaminergic neurons are involved in the control of hormone secretion, voluntary movement, and emotional behavior. Mediating these effects are the dopamine D1 and D2 receptors. These macromolecules belong to a large family of related sequences known as the G protein-coupled receptors. The D2 receptors have been of special interest because they bind, with high affinity and specificity, many of the commonly prescribed antipsychotic drugs. We previously isolated a full-length cDNA clone of the rat D2 receptor. When a chromosome mapping panel was probed with the rat D2 receptor cDNA a 15-kb EcoRI restriction fragment was identified and localized to human chromosome 11. The rat cDNA was also used to clone a human genomic fragment, lambda hD2G1, which contains the last coding exon of the D2 receptor gene (DRD2) and 16.5 kb of 3' flanking sequence. Hybridization of lambda hD2G1 to a chromosome 11 regional mapping panel localized DRD2 to 11q. In situ hybridization of lambda hD2G1 to metaphase chromosomes refined this assignment to the q22-q23 junction of chromosome 11. A search for RFLPs associated with D2DR identified a frequent two-allele TaqI RFLP.     

Characterization of the human NIPSNAP1 gene from 22q12: a member of a novel gene family

Rapid progress in sequencing of human and other genomes allows high-resolution analysis of their gene content on the basis of comparison between species. We have used a combined computer and biochemical approach to characterize 135 kb of human genomic sequence from 22q12 and discovered a new 10 exon gene, termed NIPSNAP1, located between the neurofibromatosis type 2 and the pK1.3 genes. The NIPSNAP1 gene spans 26 kb of genomic sequence and shows two large introns in the 5′-region. All exon–intron junctions contain the gt/ag consensus splice site. The putative promoter of the NIPSNAP1 gene is TATA-less and resides in a GC-rich island characteristic of housekeeping genes. The NIPSNAP1 mRNA is 2.1 kb, is expressed ubiquitously at variable levels, with the highest expression in liver, is terminated by an uncommon ATTAAA polyadenylation site, and is capable of encoding a 284-amino-acid protein. This NIPSNAP1 protein has a strong sequence similarity limited to the central portion of a hypothetical protein (acc. P34492) from chromosome III of C. elegans, in which the other portions resemble a 4-nitrophenylphosphatase domain and non-neuronal SNAP25-like protein. Thus, the NIPSNAP1 gene is a member of an evolutionarily well conserved, novel gene family with two members in human and mouse that have now been characterized, and one member in C. elegans. The second human gene, NIPSNAP2, is localized in the vicinity of marker D7S499 on chromosome 7. Although the function of the NIPSNAP protein family is unknown, clues about its role may reside in the co-expression of the C. elegans orthologue, within an operon encoding protein motifs known to be involved in vesicular transport.     

The PHD finger, a nuclear protein-interaction domain

The PHD finger is a common structural motif found in all eukaryotic genomes. It is a Zn(2+)-binding domain and its closest structural relative is the RING domain. Many RING fingers bind to E2 ligases to mediate the ubiquitination of proteins. Whether PHD fingers share a common function is unclear. Notably, many if not all PHD fingers are found in nuclear proteins whose substrate tends to be chromatin. Some PHD fingers bind to specific nuclear protein partners, apparently through the same surface that is used by RING domains to bind their cognate E2 ligases. New evidence also suggests that some PHD fingers bind to nucleosomes, raising the possibility that chromatin might be a common nuclear ligand of PHD fingers.     

High affinity human IFN-gamma-binding capacity is encoded by a single receptor gene located in proximity to c-ros on human chromosome region 6q16 to 6q22

We have used human-rodent somatic cell hybrids to investigate the regional localization of the IFN-gamma R gene on human chromosome 6 and studied functional and antigenic characteristics of the expressed IFN-gamma R by Scatchard analyses of 125I-IFN-gamma binding and binding of an anti-receptor mAb (A6C5). The data obtained revealed coordinate expression of IFN-gamma- and A6C5-binding capacity as well as competition in binding to chromosome 6-positive hybrids and normal cells, indicating that the A6C5-defined protein is by itself capable of high affinity IFN-gamma binding and, thus, is likely to constitute the major IFN-gamma R protein of distinct cell types. The receptor gene could be allocated to region 6q16 to 6q22, which also contains the c-ros oncogene. Genetic linkage of the IFN-gamma R gene to an oncogene located in a region of non-random chromosomal aberrations may have a causal relationship to the deregulated IFN-gamma R expression in several malignancies.     

The gene cluster for human U2 RNA is located on chromosome 17q21

The gene cluster for human U2 RNA has been mapped to chromosome 17q21 by in situ hybridization and hybridization analysis of DNA from mouse/human somatic cell hybrids.     

Human gene for torsion dystonia located on chromosome 9q32-q34

Torsion dystonia is a movement disorder of unknown etiology characterized by loss of control of voluntary movements appearing as sustained muscle contractions and/or abnormal postures. Dystonic movements can be caused by lesions in the basal ganglia, drugs, or gene defects. Several hereditary forms have been described, most of which have autosomal dominant transmission with variable expressivity. In the Ashkenazi Jewish population the defective gene frequency is about 1/10,000. Here, linkage analysis using polymorphic DNA and protein markers has been used to locate a gene responsible for susceptibility to dystonia in a large, non-Jewish kinship. Affected members of this family have a clinical syndrome similar to that found in the Jewish population. This dystonia gene (ITD1) shows tight linkage with the gene encoding gelsolin, an actin binding protein, and appears by multipoint linkage analysis to lie in the q32-q34 region of chromosome 9 between ABO and D9S26, a region that also contains the locus for dopamine-beta-hydroxylase.     

Characterization of human FSD1, a novel brain specific gene on chromosome 19 with paralogy to 9q31

We have characterized a novel human gene, FSD1, on chromosome 19. FSD1 has a BBC, FN3 and SPRY domain, it is distantly related to the midline 1 gene and is expressed only in the brain. We have established its exon-intron structure and we have identified the corresponding orthologous genes in other species. In addition, the identification of FSD1 has led us to identify a homologous counterpart sequence on chromosome 9.     

Chromosome 3q (22-ter) encodes the human transferrin receptor

The human transferrin receptor is an integral membrane glycoprotein of 180,000 molecular weight (mol. wt.) formed from two subunits of 90,000 mol. wt. A clone panel of Chinese hamster-human somatic cell hybrids was screened using a single cell plating cytotoxicity assay and rabbit antiserum raised to purified human transferrin receptor. Chromosome 3 displayed the highest rate of concordance with the presence of human transferrin receptor, as assayed by cytotoxicity. Antitransferrin receptor serum-resistant segregants of chromosome 3 positive, receptor-positive hybrids were selected, using antiserum and complement. The segregants consistently lost chromosome 3. 125I human transferrin binding studies confirmed synteny between the functional human transferrin receptor and chromosome 3. Examination of hybrids with either translocated or deleted chromosome 3's allows regional mapping to 3q(22-ter).