Structure and expression of the C3 gene

Representational difference analysis of a committed myeloid progenitor cell line reveals evidence for bilineage potential

In this study we have sought to characterize a committed myeloid progenitor cell line in an attempt to isolate general factors that may promote differentiation. We used cDNA representational difference analysis (RDA), which allows analysis of differential gene expression, to compare EML and EPRO cells. We have isolated nine differentially expressed cDNA fragments as confirmed by slot blot, Northern, and PCR analysis. Three of nine sequences appear to be novel whereas the identity of the remaining fragments suggested that the EPRO cell line is multipotent. Among the isolated sequences were eosinophilic, monocytic, and neutrophilic specific genes. Therefore, we tested the ability of EPRO cells to differentiate along multiple myeloid lineages and found that EPRO cells exhibited morphologic maturation into either monocyte/macrophages or neutrophils, but not eosinophils. Furthermore, when EPRO cells were exposed to ATRA, neutrophil specific genes were induced, whereas monocytic markers were induced by phorbol ester treatment. This study highlights the use of cDNA RDA in conjunction with the EML/EPRO cell line to isolate markers associated with macrophage and neutrophil differentiation and establishes the usefulness of this system in the search for factors involved in myeloid commitment.

Long-term biosynthesis of complement component C3 and alpha-1 acid glycoprotein by adult rat hepatocytes in a co-culture system with an epithelial liver cell-type

We used a system of co-culture of adult rat hepatocytes with another epithelial cell type from rat liver to study the synthesis of two acute-phase reactants, alpha-1 acid glycoprotein (alpha 1AGP) and the third component of complement (C3), and we have obtained long-term secretion of these two proteins. After a period of adaptation corresponding to the first 2-4 days of the co-culture, hepatocytes secreted C3 and alpha 1AGP for at least 2 weeks at a mean level higher than that observed in the first days of a pure culture of hepatocytes. When pulse-chase analysis was performed on day 6 of co-culture, kinetics of synthesis of alpha 1AGP and C3 were the same as those observed on day 1 of a conventional culture of pure hepatocytes. Furthermore, intracellular and extracellular alpha 1AGP had Mr values respectively of 39,000 and of 42,000-52,000, identical with those observed in pure cultures of hepatocytes. Similarly, the molecular size and subunit structures of C3 were the same in co-culture and in cultures, indicating an identical processing of this protein. C3 produced in co-culture was also haemolytically active. Therefore, the system of adult hepatocytes co-cultured with this liver epithelial cell provides a physiological system in vitro which permits long-term synthesis of the two acute-phase reactants C3 and alpha 1AGP. This model opens the possibility to study the modulation of the synthesis of these two proteins during a long period by inflammatory agents or by hormones.

Nucleotide sequence of cDNA encoding human alpha 2-macroglobulin and assignment of the chromosomal locus

Six alpha 2-macroglobulin (alpha 2M) cDNA clones were isolated from a human liver cDNA library by using synthetic oligonucleotides as hybridization probes. One of these, p alpha 2M1, carries a 4.6 kilobase-pair insert, which was sequenced. The insert contains the coding sequences for the mature alpha 2M polypeptide (1451 amino acids) and for a 23-amino acid signal peptide at the NH2 terminus of the precursor pro-alpha 2M. At the 3' end of the insert a poly(A) addition signal A-A-T-A-A-A and part of the poly(A) tail of the messenger RNA were found. The protein sequence deduced from the nucleotide sequence agrees with the published alpha 2M amino acid sequence for all except three residues. The alpha 2M locus was assigned to human chromosome 12 by Southern blot analysis with DNA from a panel of mouse/human somatic cell hybrids, using alpha 2M cDNA as a hybridization probe.

Biosynthesis of the human C3b/C4b receptor during differentiation of the HL-60 cell line. Identification and characterization of a precursor molecule

The C3b receptor (C3bR) of the human promyelocytic leukemia cell line (HL-60) was induced by incubating these cells with dimethylsulfoxide (DMSO) or retinoic acid. A majority of differentiated (DMSO- or retinoic acid-treated) but not undifferentiated cells formed rosettes with C3b-coated erythrocytes and were morphologically mature granulocytes. HL-60 cells were surface- or biosynthetically labeled and then solubilized in 1% Nonidet P-40 in the presence of multiple protease inhibitors. The C3bR was isolated either by immunoprecipitation with anti-C3bR antibodies or by affinity chromatography with hemolytically inactive components in which the internal thioester bond within the alpha-chain was cleaved (iC3)- or iC4-Sepharose. Autoradiographs of NaDodSO4-polyacrylamide gels indicated that the surface-labeled C3bR on the differentiated cells had an Mr of 210,000 (nonreduced) or 240,000 (reducing conditions). The bulk (approximately 85%) of the radiolabeled material that was isolated from biosynthetically labeled cells co-migrated with the surface-labeled band. A small fraction (approximately 15%) of the biosynthetically labeled material that was isolated by affinity chromatography or immunoprecipitation had an Mr of 188,000, which did not correspond to any surface-labeled band. This putative precursor molecule was characterized by pulse-chase experiments and by analysis of its carbohydrate. In pulse-chase (15-min pulse) studies of differentiated cells, only the 188,000-mol wt molecule was detected at 0 h. By 2 h, greater than 80% of counts had chased from the 188,000 to the 210,000-mol wt molecule. Treatment of these two molecules with endoglycosidases indicated that the 188,000-mol wt molecule possessed high mannose oligosaccharides, while the mature C3bR had complex oligosaccharides. We conclude from these data that the 188,000-mol wt molecule is a precursor of the C3b receptor of HL-60 cells. Other experiments indicated that the half-maximal time for newly synthesized receptor to attain an Mr of 210,000 was 45 min, and that the t1/2 for the disappearance of the receptor on the surface of differentiated HL-60 cells in tissue culture was approximately 10 h. The ability to observe the induction of the C3b receptor as the HL-60 cell line differentiates is an instructive model system to study the biosynthesis of a human integral membrane receptor glycoprotein.

Structure and function of the anaphylatoxins

Chemical and physical characterization of the anaphylatoxin molecules have provided a reasonably clear description of the architecture of these bioactive proteins. The primary structures of C3a, C4a, and C5a from man and from a number of animal species have been elucidated, and it is apparent that the three anaphylatoxins are genetically related. The anaphylatoxin protein chains very in length from 74 to 78 residues and no fewer than 30% of the residues are homologous when comparing C3a, C4a, and C5a within or between species. Synthetic peptide studies have been instrumental in identifying molecular features essential for the function of anaphylatoxins. Information gleaned from the structure-function studies with synthetic analogue peptides of the anaphylatoxins define putative "active sites" in these effector molecules. Linear sequences at the carboxy-terminus of C3a and C4a fulfill all of the criteria of an "active site," in that synthetic peptides of an identical sequence can mimic the biologic actions of the natural factors. In the case of human C3a, a crystallographic analysis has been performed and a three-dimensional structure was elucidated at the 3.2 A level. The crystalline structure of C3a provides valuable new information regarding the alpha helical regions and identifies the arrangement of intra-chain disulfide linkages. Taken together, the structural data now accumulated for anaphylatoxins permit molecular modelling of these proteins, designates favored conformational arrangements of the native structures, and specifically localizes the effector sites. Furthermore, elements at the essential active site have been defined with such precision that models are proposed detailing the exact nature of ligand interactions between anaphylatoxins and specific cellular receptors. Biologic characterization of the anaphylatoxins continues at a rapid pace and each advance provides a clearer view of the role of these humoral mediators in host defense. A variety of responses to anaphylatoxins are known to occur at the cellular level and are mediated in a hormone-like fashion. Diversity of action for these factors at the tissue level is readily explained by the numerous cell types stimulated by the anaphylatoxins. Cellular responses to the anaphylatoxins are perhaps the most easily defined and studied; however, tissue and systemic effects more accurately reflect the physiologic role of anaphylatoxins. Considerable progress has been made in understanding the mechanisms whereby anaphylatoxins mediate two major tissue effects, namely enhancement of vascular permeability and induction of smooth muscle contraction.(ABSTRACT TRUNCATED AT 400 WORDS)