Differential effects of subunit interactions on protein kinase A- and C-mediated phosphorylation of L-type calcium channels.

We have expressed the pore-forming alpha1S (skeletal muscle isoform) and alpha1C (cardiac/brain isoform) subunits, as well as the accessory beta2a (cardiac/brain isoform) and alpha2/delta subunits of the L-type, dihydropyridine-sensitive calcium (Ca) channels in Spodoptera frugiperda insect cells (Sf9 cells) by infection with recombinant baculoviruses in order to facilitate biochemical studies of these rare, heteromultimeric membrane proteins. Since the L-type channels are believed to be regulated by protein phosphorylation, this expression system allowed us to investigate which subunits could act as substrates for protein kinase A and C (PKA and PKC) and to determine the potential role of subunit interactions in phosphorylation of the channel proteins. Using purified protein kinases in vitro, the membrane-associated alpha1S, alpha1C, and beta2a subunits were demonstrated to be phosphorylated stoichiometrically by PKA. The extent of phosphorylation of these subunits by PKA was similar whether the subunits were expressed alone or in combination. In addition, the alpha1C and beta2a subunits were phosphorylated stoichiometrically by PKC when expressed individually. In contrast, the alpha1S subunit, when expressed alone, was a poor substrate for PKC, despite the fact that this subunit has been shown to be an excellent substrate for PKC in native skeletal muscle membranes. Interestingly, co-expression of alpha1S with the beta2a subunit restored the ability of the alpha1S subunit to serve as a substrate for PKC. These results strongly suggests that subunit interactions play an important and potentially differential role in channel regulation by PKC, whereas phosphorylation of the same subunit by PKA occurs independent of subunit interaction. Furthermore, our results provide biochemical evidence that, when co-expressed, the alpha1C, alpha1S, and beta2a subunits of L-type Ca2+ channels are excellent substrates for PKA and PKC and support the hypothesis that phosphorylation of each of these subunits may participate in channel regulation by these kinases.

Human papillomavirus (HPV) type distribution and serological response to HPV type 6 virus-like particles in patients with genital warts.

Thirty-nine patients with condylomas (12 women and 27 men) attending a dermatology clinic were tested for genital human papillomavirus (HPV) DNA and for seroprevalence to HPV type 6 (HPV6) L1 virus-like particles. The L1 consensus PCR system (with primers MY09 and MY11) was used to determine the presence and types of HPV in sample specimens. All 37 (100%) patients with sufficient DNA specimens were positive for HPV DNA, and 35 (94%) had HPV6 DNA detected at the wart site. Three patients (8%) had HPV11 detected at the wart site, and one patient had both HPV6 and -11 detected at the wart site. Thirteen additional HPV types were detected among the patients; the most frequent were HPV54 (8%) and HPV58 (8%). Baculovirus-expressed HPV6 L1 virus-like particles were used in enzyme-linked immunosorbent assays to determine seroprevalence among the patients with warts. Seronegativity was defined by a control group of 21 women who were consistently PCR negative for HPV DNA. Seroprevalence was also determined for reference groups that included cytologically normal women who had detectable DNA from either HPV6 or HPV16 and women with HPV16-associated cervical intraepithelial neoplasia. Among the asymptomatic women with HPV6, only 2 of 9 (22%) were seropositive, compared with 12 of 12 (100%) female patients with warts. A similar trend in increased HPV6 seropositivity with increased grade of disease was found with the HPV16 DNA-positive women, whose seroprevalence increased from 1 in 11 (9%) in cytologically normal women to 6 in 15 (40%) among women with cervical intraepithelial neoplasia 1 or 3. However, only 4 of 25 (16%) male patients were seropositive. No factors examined, such as age, sexual behavior, or a history of warts, were found to definitively account for the gender difference in seroresponse.

Differential expression of M-CSF, G-CSF, and GM-CSF by human monocytes.

The colony-stimulating factors (CSF) belong to a group of proteins which regulate blood cell production. Human monocytes allowed to adhere express high levels of M-CSF transcripts and secreted protein at 24 h in the presence but not in the absence of indomethacin (Indo), an inhibitor of prostaglandin E (PGE) production. When induced with lipopolysaccharide (LPS), adherent monocytes express M-CSF, G-CSF, and GM-CSF transcripts and secrete these proteins and TNF. M-CSF and GM-CSF messages increase in LPS-induced monocytes by the addition of Indo, while G-CSF mRNA appears to decrease. Exogenous addition of PGE-2 to LPS-induced monocytes down-modulates the expression of M-CSF and GM-CSF transcripts. G-CSF message is elevated, suggesting an alternate pathway to G-CSF regulation. PGE-2 inhibits the secretion of CSFs and TNF. In contrast, LPS-induced monocytes held 24 h in nonadherent culture express G- and GM-CSF but not M-CSF. Monocytes that are adhered for 24 h and then treated with LPS for an additional 24 h express only M-CSF message and secrete M-CSF and TNF. PGE-2 added with LPS during the 24-48 h induction blocks M-CSF and TNF production, but appears to enhance M-CSF message expression, in contrast to its effect on 0 h inductions. These results suggest that adherence alone induces M-CSF gene expression, but low levels of PGE or other arachidonic acid metabolites limit this expression. Other events in 1 d-cultured monocytes block the ability to induce G-CSF and GM-CSF expression with LPS, and block the suppressive effect of PGE-2 on M-CSF expression at the RNA level.

Molecular biology of macrophage colony-stimulating factor.

In this chapter we have described one of the more complex hemopoietic factors, M-CSF. The single-copy M-CSF gene is almost 21 kb in length and is arranged into 10 exons and 9 introns. Expression of the gene at the RNA level is heterogeneous, and several species of M-CSF mRNA have been found in human and murine cells and tissues. In human cells the different mRNAs arise from alternative splicing of the nuclear RNA precursor in both coding and noncoding regions. This results in mRNAs encoding two distinct M-CSF proteins, 256 and 554 amino acids in length. In murine cells only a 552-amino-acid form has been found thus far. All forms of M-CSF have a 32-amino-acid signal peptide and a 23-amino-acid hydrophobic region near the carboxy-terminus, which resembles a transmembrane domain. A large portion of the carboxy-terminal end, including the hydrophobic region, is not found in the mature protein. Thus, the primary translation product of M-CSF is a prepropolypeptide, with processing occurring at both amino- and carboxy-terminal ends. The exact size of the mature protein is still somewhat in doubt, but deletion mutagenesis from the carboxy-terminal end indicates that the protein may be as small as 150 amino acids and still be functional. Site-directed mutagenesis has also shown that the first seven cysteines in the mature molecule are probably necessary for biological activity, whereas the next two cysteine residues are not. In spite of the heavy glycosylation found in the native protein, removal of the N-linked glycosylation signals does not seem to affect activity to any great degree. The M-CSF gene and its receptor, C-FMS, are tightly linked on the long arm of chromosome 5, a unique finding in the ligand/receptor field. This region also contains the genes for GM-CSF, IL-3, ECGF, and the receptor for PDGF. A similar situation may exist on chromosome 11 of the mouse. The close linkage of these factors and receptors is the probable cause for the disorders of hemopoiesis that arise when deletions occur in this area. The preceding discussion has shown how quickly the area of M-CSF molecular biology has advanced in the past 2-3 years. A great deal of effort is now being directed toward expressing M-CSF at high levels in a variety of prokaryotic and eukaryotic systems.(ABSTRACT TRUNCATED AT 400 WORDS)

cDNA cloning and expression of murine macrophage colony-stimulating factor from L929 cells.

A 4-kilobase and a 2-kilobase cDNA clone encoding a murine macrophage colony-stimulating factor have been isolated. Except for 2 amino acid residue differences, these two clones encode the same 520 amino acid residue protein, which is preceded by a 32-amino acid residue signal peptide. The two clones, whose molecular masses correspond to the two transcripts observed in murine L929 fibroblasts, contain 3' untranslated regions that are markedly different in sequence and length. Both clones can be expressed in COS cells and the recombinant protein is active in a mouse bone marrow colony assay.

Apparent role of the macrophage growth factor, CSF-1, in placental development.

Colony stimulating factor-1 (CSF-1) is a glycoprotein growth factor required for the proliferation and differentiation of mononuclear phagocytic cells (reviewed in ref. 1). A 10,000-fold elevation of mouse uterine CSF-1 during pregnancy, suggested by studies of the bone marrow colony stimulating activity of uterine extracts, was recently demonstrated by radioimmunoassay (RIA). This increase and the observations that placenta and choriocarcinoma cell lines express c-fms messenger RNA and the c-fms proto oncogene product (CSF-1 receptor) respectively, suggest an additional role for CSF-1 in pregnancy. We now show that uterine CSF-1 concentration is regulated by the synergistic action of female sex steroids, oestradiol-17 beta (E2) and progesterone (P) and that the elevation in CSF-1 concentration can be attributed to the preferential expression of an alternatively spliced CSF-1 mRNA by uterine glandular epithelial cells. These findings indicate that CSF-1, under hormonal influence, plays a role in placental development and function and that steroid hormones may regulate developmental processes via their effects on the expression of tissue-specific growth factors.

Human CSF-1: gene structure and alternative splicing of mRNA precursors.

Bone marrow progenitor cells differentiate into mononuclear phagocytes in the presence of colony stimulating factor-1 (CSF-1). Characterization of the human CSF-1 gene shows that it contains 10 exons and 9 introns, which span 20 kb. Analysis of multiple CSF-1 transcripts demonstrates that alternate use of exon 6 splice acceptor sites and 3' noncoding sequence exons occurs. These alternatively spliced transcripts can encode either a 224 or a 522 amino acid CSF-1. Implications of differential splicing for the production and function of CSF-1 are discussed.

Biological properties and molecular biology of the human macrophage growth factor, CSF-1.

CSF-1 is a growth and differentiation factor for the production of mononuclear phagocytes from undifferentiated bone marrow progenitors. In addition to previously described effects on mature cells, we show here that CSF-1 stimulates the production by monocytes of interferon, tumor necrosis factor, and myeloid CSF that produces mainly mixed neutrophil-macrophage colonies in bone marrow culture. Pretreatment with CSF-1 also promotes resistance to viral infection and tumor cytotoxicity in murine peritoneal macrophages. Based on amino acid sequence data of purified human urinary and murine L cell CSF-1, we have cloned the complementary DNA (cDNA) from messenger RNA (mRNA) of the human CSF-1 producing MIA PaCa cell line. The cDNA specifies a 32 amino acid signal peptide followed by a protein of 224 amino acids. Several facts suggest, however, that one-third of the molecule at the C-terminal end is processed off intracellularly to derive the secreted growth factor. The gene is about 18 kilobases (kb) in length and contains 9 exons. Although there appears to be a single copy gene for CSF-1, cells expressing the factor contain several mRNA species, suggesting that the gene may have several functions or levels of regulation. High level expression of the recombinant protein will allow preclinical testing in several disease models for therapeutic efficacy that has been suggested from in vitro and in vivo biological properties of CSF-1.

Molecular cloning of a complementary DNA encoding human macrophage-specific colony-stimulating factor (CSF-1).

Complementary DNA (cDNA) clones encoding human macrophage-specific specific colony-stimulating factor (CSF-1) were isolated. One cDNA clone codes for a mature polypeptide of 224 amino acids and a putative leader of 32 amino acids. This cDNA, which was cloned in the Okayama-Berg expression vector, specifies the synthesis of biologically active CSF-1 in COS cells, as determined by a specific radioreceptor assay, macrophage bone marrow colony formation, and antibody neutralization. Most of the cDNA isolates contain part of an intron sequence that changes the reading frame, resulting in an abrupt termination of translation; these cDNA's were inactive in COS cells. The CSF-1 appears to be encoded by a single-copy gene, but its expression results in the synthesis of several messenger RNA species, ranging in size from about 1.5 to 4.5 kilobases.

Molecular cloning of the complementary DNA for human tumor necrosis factor.

Tumor necrosis factor (TNF) is a soluble protein that causes damage to tumor cells but has no effect on normal cells. Human TNF was purified to apparent homogeneity as a 17.3-kilodalton protein from HL-60 leukemia cells and showed cytotoxic and cytostatic activities against various human tumor cell lines. The amino acid sequence was determined for the amino terminal end of the purified protein, and oligodeoxyribonucleotide probes were synthesized on the basis of this sequence. Complementary DNA (cDNA) encoding human TNF was cloned from induced HL-60 messenger RNA and was confirmed by hybrid-selection assay, direct expression in COS-7 cells, and nucleotide sequence analysis. The human TNF cDNA is 1585 base pairs in length and encodes a protein of 233 amino acids. The mature protein begins at residue 77, leaving a long leader sequence of 76 amino acids. Expression of high levels of human TNF in Escherichia coli was accomplished under control of the bacteriophage lambda PL promoter and gene N ribosome binding site.