Molecular cloning and nucleotide sequence of a human renin cDNA fragment.

We have studied human renin messenger RNA by hybridization with the mouse submaxillary gland (SMG) renin cDNA probe. The human kidney messenger RNA is about 1.6 kilobase (kb) long, similarly to the mouse SMG renin mRNA. A kidney renin cDNA clone of 1.1 kb length was obtained. A comparison of nucleotide sequences of mouse and human cDNA clones reveals conservation of residues involved in catalytic mechanisms and a potential glycosylation site. The human renin molecular probe allowed us to study renin expression in human chorionic tissue. The chorionic and kidney renin messenger RNAs are similar in length. The Southern blot analysis reveals the presence of a single renin gene in human DNA.     

Isolation and characterization of a gene coding for glyceraldehyde-3-phosphate dehydrogenase from Saccharomyces cerevisiae.

A yeast glyceraldehyde-3-phosphate dehydrogenase gene has been isolated from a collection of Escherichia coli transformants containing randomly sheared segments of yeast genomic DNA. Complementary DNA, synthesized from partially purified glyceraldehyde-3-phosphate dehydrogenase messenger RNA, was used as a hybridization probe for cloning this gene. The isolated hybrid plasmid DNA has been mapped with restriction endonucleases and the location of the glyceraldehyde-3-phosphate dehydrogenase gene within the cloned segment of yeast DNA has been established. There are approximately 4.5 kilobase pairs of DNA sequence flanking either side of the glyceraldehyde-3-phosphate dehydrogenase gene in the cloned segment of yeast DNA. The isolated hybrid plasmid DNA has been used to selectively hybridize glyceraldehyde-3-phosphate dehydrogenase messenger RNA from unfractionated yeast poly(adenylic acid)-containing messenger RNA. The nucleotide sequence of a portion of the isolated hybrid plasmid DNA has been determined. This nucleotide sequence encodes 29 amino acids which are at the COOH terminus of the known amino acid sequence of yeast glyceraldehyde-3-phosphate dehydrogenase.     

A stably transfected c-myc cat hybrid gene is not regulated by serum in NIH3T3 cells

A plasmid containing the CAT (chloramphenicolacetyltransferase) gene fused to the 5' adjacent sequences and first exon of the human c-myc gene was stably transfected into NIH3T3 cells. Single cell clones were grown and CAT activity was measured after serum starvation and stimulation. CAT activity of the hybrid construct remained unchanged in serum-deprived and serum-stimulated cells. In contrast the steady-state RNA level of the endogenous mouse c-myc gene was strongly elevated upon serum stimulation. The bona fide usage of the human c-myc promoter P1/P2 in mouse cells carrying the hybrid gene was revealed by S1 analysis.     

Identification of functional murine adenosine deaminase cDNA clones by complementation in Escherichia coli

Total poly(A+) RNA derived from a mouse cell line with amplified adenosine deaminase genes was used as template to synthesize double-stranded cDNA. The cDNAs were inserted into the PstI site of the beta-lactamase gene in plasmid pBR322 following G-C tailing. After transformation into adenosine deaminase-deficient Escherichia coli hosts, recombinant plasmids containing functional murine adenosine deaminase cDNAs were identified by selecting for functional complementation. Analysis of plasmids containing functional adenosine deaminase cDNA sequences strongly suggested that adenosine deaminase expression resulted mainly from beta-lactamase/adenosine deaminase fusion proteins even when the adenosine deaminase codons were out-of-frame with respect to the beta-lactamase gene codons upstream. The nucleotide sequence of a 1.65-kilobase pair cDNA insert in one of the functional recombinant clones was determined and found to contain a 1056-nucleotide open reading frame. When this 1056-nucleotide open reading frame was inserted into a mammalian expression vector and introduced into monkey kidney cells, a high level of authentic mouse adenosine deaminase was produced. Nucleic acid blot analysis using a full-length adenosine deaminase cDNA clone as probe revealed that the mouse adenosine deaminase structural gene was at least 21 kilobase pairs in size and encoded three polyadenylated mRNAs. Analysis of the cDNA library from which the functional clones were isolated suggested that this approach of cloning functional mammalian adenosine deaminase cDNA clones by genetic complementation of enzyme-deficient bacteria could be accomplished even if the abundance of the adenosine deaminase mRNA sequences were as low as approximately 0.001%.     

Molecular cloning of genomic DNA segments partially coding for human thymidylate synthase from the mouse cell transformant

Mouse cells deficient in the enzyme thymidylate synthase [TS; EC 2.1.1.45] were serially transformed with human DNA to yield primary and secondary transformants which produced human TS [Ayusawa, D., Shimizu, K., Koyama, H., Takeishi, K., & Seno, T. (1983) J. Biol. Chem. 258, 48-53]. Southern blot hybridization of their genomic DNA showed that six secondary transformants examined contained in common a 5.5 kb EcoRI fragment hybridized with a human Alu sequence. From the secondary transformant genomic library constructed with phage lambda Charon 4A, two recombinant phage clones carrying Alu sequences were isolated. Restriction endonuclease mapping revealed that the insert DNAs of the two phage clones overlapped and covered a region of 19 kb in total. Within this region at least six Alu sequences were located. A 2.0 kb DNA fragment, prepared from an EcoRI fragment subcloned in plasmid pBR322 and free of Alu sequences, hybridized to a single band on RNA blots of primary and secondary transformant poly(A)+ RNA, but not to RNA of mouse wild-type and recipient cell lines. The relative amount of the presumed human TS mRNA was linearly correlated with the relative activity of human TS in various types of mouse transformant cells. These results indicate that these two phage clones contain genomic DNA sequences encoding human TS.     

Construction and identification of a cDNA clone for human type II procollagen mRNA.

Double-stranded cDNA was constructed for poly(A)-containing RNA isolated from foetal human articular cartilage known to contain small amounts of pro alpha 1 (II) collagen mRNA. A 585 base pair PstI-EcoRI cDNA fragment was isolated and cloned into plasmid pBR322. A resulting recombinant plasmid pHCAR1 was shown to hybridize specifically to a 5.4 kilobase mRNA in cartilage but not in calvarial RNA. Definite identification of clone pHCAR1 was based on sequence analysis; marked homology with the corresponding chick gene and complete agreement with the human gene sequences available were observed.     

Amplification and molecular cloning of murine adenosine deaminase gene sequences

A previously isolated mouse Cl-1D derived cell line (B-1/25) overproduces adenosine deaminase (EC 3.5.4.4) by 3200-fold. The present studies were undertaken to determine the molecular basis of this phenomenon. Rabbit reticulocyte lysate and Xenopus oocyte translation studies indicated that the B-1/25 cells also overproduced adenosine deaminase mRNA. Total poly(A+) RNA derived from B-1/25 was used to construct a cDNA library. After prehybridization with excess parental Cl-1D RNA to selectively prehybridize nonamplified sequences, 32P-labeled cDNA probe synthesized from B-1/25 total poly(A+) RNA was used to identify recombinant colonies containing amplified mRNA sequences. Positive clones containing adenosine deaminase gene sequences were identified by blot hybridization analysis and hybridization-selected translation in both rabbit reticulocyte lysate and Xenopus oocyte translation systems. Adenosine deaminase cDNA clones hybridized with three poly(A+) RNA species of 1.5, 1.7, and 5.2 kilobases in length, all of which were overproduced in the B-1/25 cell line. Dot blot hybridization analysis using an adenosine deaminase cDNA clone showed that the elevated adenosine deaminase level in the B-1/25 cells was fully accounted for by an increase in adenosine deaminase gene copy number. The adenosine deaminase cDNA probes and the cell lines with amplified adenosine deaminase genes should prove extremely useful in studying the structure and regulation of the adenosine deaminase gene.     

Molecular analysis of the human interferon-alpha gene family

Fifteen DNA clones containing sequences related to human interferon-alpha cDNA were isolated from a human chromosomal gene bank (Nagata et al., Nature 287 (1980) 401-408) and characterized by restriction mapping, R-loop and heteroduplex analysis. Nine distinct DNA segments hybridized strongly with interferon-alpha 1 cDNA and formed R-loops with poly(A) RNA from interferon-producing human leukocytes; most if not all of these segments represent functional interferon genes. Five segments hybridized weakly with the probe and did not form R-loops with the poly(A) RNA; one of these was characterized as an interferon-alpha pseudogene. Several DNA segments overlap and define a region of 36 kilobase pairs (kb) that contains three strongly and three weakly hybridizing sequences. From our data and those of Goeddel et al. (Nature 290 (1981) 20-25) we conclude that there exist at least 11 distinct genes of gene-like sequences of the interferon-alpha type in the human genome, of which most likely represents an allelic variant, and at least five pseudogenes distantly related to the interferon-alpha genes.     

Identification and procaryotic expression of the gene coding for the highly immunogenic 28-kilodalton structural phosphoprotein (pp28) of human cytomegalovirus.

Human cytomegalovirus contains a structural polypeptide that is 28 kilodaltons in apparent molecular size and is reactive in Western blot (immunoblot) analysis with the majority of human sera. The gene coding for this polypeptide was mapped on the genome of human cytomegalovirus strain AD169. A monoclonal antibody specific for the 28-kilodalton polypeptide was used to screen a cDNA library constructed from poly(A)+ RNA of human cytomegalovirus-infected cells in the procaryotic expression vector lambda gt11. Hybridization of cDNA with cosmid and plasmid clones mapped the gene to the HindIII R fragment. The gene was transcribed into a late 1.3-kilobase RNA. The nucleotide sequence of the coding region was determined. Parts of the 28-kilodalton polypeptide were expressed in Escherichia coli as hybrid proteins fused to beta-galactosidase. In Western blots these proteins were recognized by human sera. Antibodies raised against the hybrid proteins reacted specifically with the viral antigen in immunoprecipitations and Western blots. In vitro phosphorylation of HCMV virions and immunoprecipitation showed that the 28-kilodalton polypeptide was phosphorylated.     

Sequence organization of cloned intracisternal A particle genes

Seven recombinant DNA clones containing mouse intracisternal A particle genes were isolated and analyzed by restriction enzyme digestion, Southern blot analysis and heteroduplex mapping. The sequence organization of the individual genes was found to differ, with one end of the gene region being most variable, while a central segment of 1.8 kb was missing from two of the clones. A third region, common to all the clones and containing the 3' end of the gene, is present in about 1800 copies per haploid genome, but the central portion is found in only 650 copies. The same reiteration frequency is found in both myeloma tumor and mouse liver DNA. The most abundant intracisternal A particle RNA in two different myeloma lines was found to be 3.5 kb, and RNA/DNA hybrids show that the RNA is homologous to all but a small internal segment of one of the clones.     

A human T-cell antigen receptor beta chain gene maps to chromosome 7.

cDNA clones which encode the human and mouse T cell antigen receptor beta chain gene have previously been isolated. We have used a mouse cDNA clone to map the chromosomal position of a human beta chain gene. Southern blot analysis of DNA prepared from somatic cell hybrids has assigned this gene to chromosome 7. The use of a hybrid containing a chromosome 7 translocation has further localised this gene to the region 7q22-qter.     

Cloning of cDNA for argininosuccinate synthetase mRNA and study of enzyme overproduction in a human cell line

Previous studies of the human cell line RPMI-2650 (wild type) and its canavanine-resistant variants have demonstrated differences in argininosuccinate synthetase activity as follows: canavanine-resistant much greater than wild type grown in citrulline greater than wild type grown in arginine (Su, T.-S., Beaudet, A. L., and O'Brien, W. E. (1981) Biochemistry 20, 2956-2960). A recombinant plasmid containing a 1.55-kilobase insert complementary to the mRNA for human argininosuccinate synthetase was isolated by the combined use of differential colony hybridization and immunoprecipitation of the products of plasmid-selected mRNA translation. Both blot and dot hybridization analysis of polyadenylated RNA indicated a major mRNA species of 1.67 kilobase in all cells, and the levels of mRNA correlated well with the levels of enzyme activity: canavanine-resistant, 180; wild type grown in citrulline, 7; and wild type grown in arginine, 1. One major mRNA species of 1.67 kilobase and one minor species of 2.68 kilobase were observed in wild type and canavanine-resistant cell lines. Reassociation kinetics of pAS1 with genomic DNA from human liver, canavanine-resistant cells, and wild type cells were not significantly different. Blot hybridization of genomic DNA revealed no detectable differences between wild type cells, canavanine-resistant cells, and human leukocytes. The data demonstrated that there were multiple copies, perhaps 10 or more, of argininosuccinate synthetase-like sequences in human DNA and that the canavanine-resistant phenotype was not due to gene amplification.     

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.