Molecular characterization of sialophorin (CD43), the lymphocyte surface sialoglycoprotein defective in Wiskott-Aldrich syndrome

Sialophorin (CD43) of leukocytes and platelets is a surface sialoglycoprotein that is phenotypically defective on lymphocytes of patients with the X chromosome-linked immunodeficiency Wiskott-Aldrich syndrome. Previous studies with monoclonal antibodies indicate that sialophorin is a component of a T-lymphocyte activation pathway. Here we describe the cDNA cloning and derived amino acid sequence of human sialophorin. The sequence predicts an integral membrane polypeptide with an N-terminal hydrophobic signal region followed by a mucin-like 235-residue extracellular region with a uniform distribution of 46 serine, 47 threonine, and 24 proline residues. This is followed by a 23-residue transmembrane region and a 123-residue C-terminal intracellular region. These latter regions have been highly conserved during evolution; the intracellular region contains a number of potential phosphorylation sites that might mediate transduction of activation signals. The chromosomal location of the sialophorin gene was determined and the implications of this assignment for the pathogenesis of the Wiskott-Aldrich syndrome are discussed.

A deletion map of the WAGR region on chromosome 11

The WAGR (Wilms tumor, aniridia, genitourinary anomalies, and mental retardation) region has been assigned to chromosome 11p13 on the basis of overlapping constitutional deletions found in affected individuals. We have utilized 31 DNA probes which map to the WAGR deletion region, together with six reference loci and 13 WAGR-related deletions, to subdivide this area into 16 intervals. Specific intervals have been correlated with phenotypic features, leading to the identification of individual subregions for the aniridia and Wilms tumor loci. Delineation, by specific probes, of multiple intervals above and below the critical region and of five intervals within the overlap area provides a framework map for molecular characterization of WAGR gene loci and of deletion boundary regions.

Molecular mapping and cloning of the breakpoints of a chromosome 11p14.1-p13 deletion associated with the AGR syndrome

Chromosome 11p13 is frequently rearranged in individuals with the WAGR syndrome (Wilms tumor, aniridia, genitourinary anomalies, and mental retardation) or parts of this syndrome. To map the cytogenetic aberrations molecularly, we screened DNA from cell lines with known WAGR-related chromosome abnormalities for rearrangements with pulsed field gel (PFG) analysis using probes deleted from one chromosome 11 homolog of a WAGR patient. The first alteration was detected in a cell line from an individual with aniridia, genitourinary anomalies, mental retardation, and a deletion described as 11p14.1-p13. We have located one breakpoint close to probe HU11-164B and we have cloned both breakpoint sites as well as the junctional fragment. The breakpoints subdivide current intervals on the genetic map, and the probes for both sides will serve as important additional markers for a long-range restriction map of this region. Further characterization and sequencing of the breakpoints may yield insight into the mechanisms by which these deletions occur.

Isolation and characterization of a cDNA that encodes the peptide core of the secretory granule proteoglycan of human promyelocytic leukemia HL-60 cells

A cDNA that encodes the peptide core of the secretory granule proteoglycan of the human promyelocytic leukemic cell line, HL-60, has been isolated and analyzed. When human genomic DNA was digested and probed under conditions of low stringency with a rat cDNA that encodes a Mr = 18,600 serine/glycine-rich proteoglycan peptide core in L2 yolk sac tumor cells (Bourdon, M. A., Oldberg, A., Pierschbacher, M., and Ruoslahti, E. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 1321-1325) and basophilic leukemia-1 cells (Avraham, S., Stevens, R. L., Gartner, M. C., Austen, K. F., Lalley, P. A., and Weis, J. H. (1988) J. Biol. Chem. 263, 7292-7296), a number of DNA fragments were identified. A HL-60 cell-derived cDNA library was therefore screened under conditions of low stringency with the rat probe to identify and isolate a human homologue of this rat proteoglycan peptide core. Analysis of the resulting human cDNA clones indicated that the proteoglycan peptide core that is expressed in HL-60 cells is Mr = 17,600 and contains an 18-amino acid glycosaminoglycan attachment region that consists primarily of alternating serin and glycine. Northern blot analysis of total RNA probed with the human cDNA revealed that the major message for this proteoglycan peptide core in HL-60 cells is approximately 1.3 kilobase pairs in size. When a Southern blot of digested human genomic DNA was probed with the human cDNA, three bands of approximately 6, 9, and 12 kilobase pairs were detected. However, when the Southern blot was probed with the XmnI----3' fragment of this human cDNA, one prominent band was detected, indicating that a single gene encodes this protein in the human. Analysis of the DNA from human/mouse and human/hamster somatic cell hybrids probed with the human cDNA demonstrated that the gene that encodes this molecule resides on human chromosome 10. Because the proteoglycans that are present in the secretory granules of different types of rat and mouse mast cells possess small peptide cores that are rich in serine and glycine, we propose that this HL-60 cell-3 derived cDNA encodes the peptide core of the proteoglycan that is expressed in the secretory granules of this human promyelocytic cell.

Human profilin. Molecular cloning, sequence comparison, and chromosomal analysis

Profilin is an ubiquitous 12-15-kDa actin monomer-binding protein, the amino acid sequence of which was previously reported for the cow and Acanthamoeba. In the latter species, two isoforms of profilin have been identified. We have isolated full-length profilin cDNA clones from a human HepG2 library. All clones have the same nucleotide sequence, and Northern blot and RNase protection analyses of human tissues indicate that all tissues have the same approximately 850 base message, and provide no evidence of alternative message splicing. This result strongly implies a single profilin isoform in human cells, although differential post-translational modifications have not been excluded. Northern blot analysis extends the tissue distribution of profilin to include epithelial, muscle, and renal tissues. Comparison of the predicted human profilin amino acid sequence with that of published bovine profilin indicates 90% identity with a single 3-residue deletion in the human sequence. Southern blot analysis of somatic cell hybrid DNA indicates at least four dispersed genetic loci in the human genome hybridize with the profilin cDNA as well as untranslated region fragments, suggesting several of these loci represent pseudogenes of recent evolutionary origin. In addition, 5' and 3' untranslated regions are conserved between humans and rodents, implying a functional role for these regions of the profilin gene.

Human GAP-43: its deduced amino acid sequence and chromosomal localization in mouse and human

The growth-associated protein (GAP-43) is considered a crucial component of an effective regenerative response in the nervous system. Its phosphorylation by protein kinase C correlates with long-term potentiation. Sequence analysis of human cDNAs coding for this protein shows that the human GAP-43 gene is highly homologous to the rat gene; this homology extends into the 3'-untranslated region. However, the human protein contains a 10 amino acid insert. Somatic cell hybrids demonstrate localization of the GAP-43 gene to human chromosome 3 and to mouse chromosome 16.

Localization of gelsolin proximal to ABL on chromosome 9

Gelsolin is a plasma and cytoskeletal protein that severs actin filaments and is regulated by both Ca+2 and polyphosphoinositides. The two forms of gelsolin are encoded by a single gene and derived through alternative message splicing. By Southern blot analysis of somatic cell hybrids and in situ chromosomal localization, we demonstrate that the gelsolin gene is present on human chromosome 9 in bands q32-q34. In situ hybridization of gelsolin to cells containing a Philadelphia chromosome [(9;22)(q34;q11)], as well as Southern blot analysis of K562 cell DNA, indicates that gelsolin is centromeric to the ABL locus in 9q34. Southern blot analysis of NotI-digested, pulsed-field gel electrophoresis-separated DNA indicates the gelsolin gene is greater than or equal to 40 kb centromeric to ABL. These studies and standard Southern blot analysis of digested DNA also indicate that the NotI restriction site contained in the gelsolin gene is uncleavable in DNA from white blood cells and hematopoietic cell lines.

Human corticotropin releasing hormone gene is located on the long arm of chromosome 8

The chromosomal locus of the human corticotropin releasing hormone (hCRH) gene was assigned to chromosome 8 using Southern blot analysis of human x rodent cell hybrids and was localized to band 8q13 using in situ hybridization to metaphase chromosomes. The absence of secondary hybridization strongly suggests that hypothalamic and placental CRH are transcribed from the same gene.

Nature of recombination involved in excision and rearrangement of human repetitive DNA

An alphoid-like human repetitive DNA of the Sau3A family is present extrachromosomally and in the chromosomes. In the chromosomes, the DNA is located on chromosome 11 but related sequences are present in chromosome 17. We characterized the nature of the recombination involved in the excision of the extrachromosomal DNA from chromosome 11. The results show that the recombination occurs both between the homologous subunits and between the heterologous subunits with only a 70 to 80% sequence homology among them, suggesting that a DNA structure other than a sequence homology mediates the recombination process. The same type of recombination is responsible for the rearrangement of the related sequences in chromosome 17.

Human complement factor I: analysis of cDNA-derived primary structure and assignment of its gene to chromosome 4

Factor I is a serine proteinase of complement which together with one of several specific cofactors cleaves activation products of the third and fourth components of complement (C3b and C4b) and modulates the activity of C3 convertase. A heterodimer glycoprotein (Mr = 88,000), factor I is synthesized as a single-chain precursor, prepro-I, which undergoes intracellular proteolytic processing. The human hepatoma line HepG2, however, secretes predominantly the single-chain precursor pro-I. In order to determine the molecular basis for this apparent processing defect, factor I cDNA clones were isolated from a HepG2 mRNA-derived library. Sequencing of the largest insert, HI1971, revealed that it contains 14 base pairs of 5' untranslated region, the complete coding sequence for the 583-residue prepro-I (NH2-signal peptide-heavy chain-linking peptide-light chain-COOH), two polyadenylation signals within the 200-base pair 3' untranslated region, and a portion of poly(A) tail. Analysis of the derived protein structure 1) reveals a mosaic multidomain structure of the heavy chain; 2) demonstrates structural similarity between intracellular conversion of pro-I and activation of other serine proteinase zymogens; and 3) indicates that the light chain of factor I resembles most closely the active subunit of tissue plasminogen activator among all serine proteinases and factor D among complement proteinases. Furthermore, this protein sequence was compared to the sequences of factor I cDNA clones isolated from normal human liver libraries and found to be identical. By exclusion, this defines as cellular the basis for the inefficient processing of pro-I by the HepG2 line. Chromosomal localization by the somatic cell hybrid method maps the factor I gene to chromosome 4.

Localization of the ornithine aminotransferase gene and related sequences on two human chromosomes

We have used a full length cDNA clone to determine the chromosomal location of the gene encoding human ornithine aminotransferase (OAT), a mitochondrial matrix enzyme. Southern blot analysis of Sca I-digested DNA from 34 human-mouse somatic cell hybrids revealed 11 human fragments. Three fragments mapped to chromosome 10q23-10qter, confirming the previous provisional assignment of the functional gene to this autosome by analysis of OAT expression in somatic cell hybrids (O'Donnell et al. 1985). The remaining eight fragments were assigned to the X chromosome, and regionally assigned to Xp21-Xp11 by use of an X-chromosome mapping panel. These X chromosome sequences could represent pseudogenes, or related members of a multigene family. Two of the X chromosome fragments are alternate alleles of a restriction fragment length polymorphism (RFLP) making this OAT-related locus an excellent genetic marker. The RFLP may now be used to determine any possible relationship between this locus and several X-linked eye defects.

An anonymous DNA segment (II227) maps to the long arm of human chromosome 5 and identifies a BstXI polymorphism (D5S26)

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The gene encoding the epsilon subunit of the T3/T-cell receptor complex maps to chromosome 11 in humans and to chromosome 9 in mice

The T3 complex is composed of three polypeptide chains that are both structurally and functionally associated with the receptor for antigen on the surface of human T lymphocytes. In a series of experiments utilizing both somatic cell hybrids and chromosomal hybridization in situ, the genes encoding two members of the human T3 complex, T3-delta and T3-epsilon, were found to reside on the long arm of chromosome 11 in band q23. The murine T3-epsilon gene was localized to chromosome 9. The location of the T3-delta and T3-epsilon genes with respect to the Hu-ets-1 gene, which is also located in 11q23, is discussed. Recent assignments of several genes, preferentially expressed in human cells of hematopoietic and neuroectodermal origins, to band q23 of human chromosome 11 and the murine equivalents to murine chromosome 9 may define a conserved gene cluster important in cell proliferation and differentiation.

Amyloid beta protein gene: cDNA, mRNA distribution, and genetic linkage near the Alzheimer locus

The amyloid beta protein has been identified as an important component of both cerebrovascular amyloid and amyloid plaques of Alzheimer's disease and Down syndrome. A complementary DNA for the beta protein suggests that it derives from a larger protein expressed in a variety of tissues. Overexpression of the gene in brain tissue from fetuses with Down syndrome (trisomy 21) can be explained by dosage since the locus encoding the beta protein maps to chromosome 21. Regional localization of this gene by both physical and genetic mapping places it in the vicinity of the genetic defect causing the inherited form of Alzheimer's disease.

A somatic cell hybrid with a single human chromosome 22 corrects the defect in the CHO mutant (Ade-I) lacking adenylosuccinase activity

Adenine-requiring Chinese hamster ovary (CHO-K1) auxotrophs of the complementation group Ade-I were hybridized with various human cells, and hybrids were isolated under selective conditions in which retention of the complementing gene on the human chromosome is necessary for survival. Ade-I cells are deficient in adenylosuccinase activity. This enzyme carries out two independent, but similar, steps of purine biosynthesis: the removal of a fumarate from succinylaminoimidazole carboxamide ribotide to produce aminoimidazole carboxamide ribotide and the removal of fumarate from adenylosuccinate to produce AMP. These are the 9th and 13th steps of adenylate biosynthesis, respectively. Analysis of hybrids by cytogenetics and by Southern blot techniques using chromosome 22-specific DNA probes, one of which encodes an antigen expressed in human fetal brain, indicated that human chromosome 22 was 100% concordant for growth without adenine. One hybrid subclone, isolated after two successive rounds of subcloning, was found to be capable of growth without adenine; the only human chromosome present was 22. In addition, segregants that had lost the ability to grow in adenine-free media had also lost human chromosome 22. These results suggest that the human gene for adenylosuccinase resides on chromosome 22.

A complement receptor locus: genes encoding C3b/C4b receptor and C3d/Epstein-Barr virus receptor map to 1q32

The alternative or classical pathways for complement system component C3 may be triggered by microorganisms and antigen-antibody complexes. In particular, an activated fragment of C3, C3b, covalently attaches to microorganisms or antigen-antibody complexes, which in turn bind to the C3b receptor, also known as complement receptor 1. The genes encoding the proteins that constitute the C3-activating enzymes have been cloned and mapped to a "complement activation" locus in the major histocompatibility complex, and we demonstrate in this study such a locus on the long arm of chromosome 1 at band 1q32.

A complement receptor locus: genes encoding C3b/C4b receptor and C3d/Epstein-Barr virus receptor map to 1q32

The alternative or classical pathways for complement system component C3 may be triggered by microorganisms and antigen-antibody complexes. In particular, an activated fragment of C3, C3b, covalently attaches to microorganisms or antigen-antibody complexes, which in turn bind to the C3b receptor, also known as complement receptor 1. The genes encoding the proteins that constitute the C3-activating enzymes have been cloned and mapped to a "complement activation" locus in the major histocompatibility complex, and we demonstrate in this study such a locus on the long arm of chromosome 1 at band 1q32.

Localization of the LDHA gene to 11p14----11p15 by in situ hybridization of an LDHA cDNA probe to two translocations with breakpoints in 11p13

Lymphoblastoid cell lines established from two individuals with apparently balanced translocations involving 11p13 were used for LDHA regional localization. The karyotypes were 46,XY,t(4;11)(q21;p13) and 46,XY,t(1;11)(p22;p13). In situ hybridization of a human LDHA cDNA probe to chromosome preparations from these cell lines resulted in specific labeling over bands p14----p15 of the normal chromosomes 11 and over bands 11p14----11p15 of the derivative chromosomes 4 and 1. These results exclude LDHA from any region proximal to 11p13 and localize the gene to 11p14----11p15.

A polymorphic locus on the long arm of chromosome 20 defined by two probes from a single cosmid

Two probes from the random human cosmid c1-37 detect restriction fragment length polymorphisms in humans. The loci revealed by these probes are in linkage equilibrium and constitute a compound polymorphic locus with a polymorphism information content of 0.54. A somatic cell hybrid panel has been used to map the probes to chromosome 20; in situ hybridization studies confirm this localization and indicate that the locus is on 20q13. This is the first polymorphic locus to be assigned to the long arm of chromosome 20.

The beta-subunit of follicle-stimulating hormone is deleted in patients with aniridia and Wilms' tumour, allowing a further definition of the WAGR locus

One in 10,000 children develops Wilms' tumour, an embryonal malignancy of the kidney. Although most Wilms' tumours are sporadic, a genetic predisposition is associated with aniridia, genito-urinary malformations and mental retardation (the WAGR syndrome). Patients with this syndrome typically exhibit constitutional deletions involving band p13 of one chromosome 11 homologue. It is likely that these deletions overlap a cluster of separate but closely linked genes that control the development of the kidney, iris and urogenital tract (the WAGR complex). A discrete aniridia locus, in particular, has been defined within this chromosomal segment by a reciprocal translocation, transmitted through three generations, which interrupts 11p13. In addition, the specific loss of chromosome 11p alleles in sporadic Wilms' tumours has been demonstrated, suggesting that the WAGR complex includes a recessive oncogene, analogous to the retinoblastoma locus on chromosome 13. In WAGR patients, the inherited 11p deletion is thought to represent the first of two events required for the initiation of a Wilms' tumour, as suggested by Knudson from epidemiological data. We have now isolated the deleted chromosomes 11 from four WAGR patients in hamster-human somatic cell hybrids, and have tested genomic DNA from the hybrids with chromosome 11-specific probes. We show that 4 of 31 markers are deleted in at least one patient, but that of these markers, only the gene encoding the beta-subunit of follicle-stimulating hormone (FSHB) is deleted in all four patients. Our results demonstrate close physical linkage between FSHB and the WAGR locus, suggest a gene order for the four deleted markers and exclude other markers tested from this region. In hybrids prepared from a balanced translocation carrier with familial aniridia, the four markers segregate into proximal and distal groups. The translocation breakpoint, which identifies the position of the aniridia gene on 11p, is immediately proximal to FSHB, in the interval between FSHB and the catalase gene.