The role of individual cysteine residues in the processing, structure, and function of human macrophage colony-stimulating factor.

The shortest form of human macrophage colony-stimulating factor (M-CSF alpha, CSF-1(256) is expressed on the cell surface as a homodimeric type I transmembrane glycoprotein. The seven cysteine residues in CSF-1(256) form three intrachain disulfide bonds (Cys7-Cys90, Cys48-Cys139, and Cys 102-Cys146), and one interchain disulfide bond (Cys31-Cys31). To examine the role of the seven cysteine residues in CSF-1(256), we replaced each half-cystine by a serine using site-directed mutagenesis, and stably expressed the mutated genes in mouse NIH 3T3 cells. We showed that each of the seven cysteines of CSF-1(256) is essential for its biological activity. Our data further show that substitution of Cys48 or Cys139 totally blocked dimer formation and cell surface expression of CSF-1(256), and that substitution of Cys102 and Cys146 severely impaired CSF-1 dimer formation and cell surface expression. In contrast, substitution of Cys7 or Cys90 affected CSF-1 dimer formation to a lesser degree but did not significantly affect cell surface expression of CSF-1. Furthermore, disruption of the interchain disulfide bond led to efficient cell surface expression of monomeric CSF-1. All of the cell surface expressed mutant CSF-1 proteins, either dimeric or monomeric, still underwent efficient ectodomain cleavage. The electrophoretic mobilities of the cleaved dimeric ectodomains of these mutant CSF-1 proteins on SDS-PAGE exhibited distinctly different patterns as compared with the wild type. Substitution of either Cys7 or Cys90 produced the same shift, while substitution of either Cys102 or Cys146 resulted in a shift distinct from that caused by substitution of Cys7 or Cys90. These data suggest that replacement of either of a pair of intrachain half-cystine residues results in similar conformational changes, and may provide a novel method for mapping intrachain disulfide bonds in dimeric proteins.

Structural requirements for the ectodomain cleavage of human cell surface macrophage colony-stimulating factor.

One form of human macrophage colony-stimulating factor (CSF-1(256), M-CSFalpha) is a member of a restricted set of cell surface transmembrane proteins, which is selected to undergo proteolytic ectodomain cleavage. To determine the substrate requirements for this cleavage, we have constructed a series of mutations in the cytoplasmic tail, transmembrane domain, and juxtamembrane region of CSF-1(256) and stably expressed the mutated genes in NIH 3T3 cells. Our results demonstrate that membrane association of the CSF-1 precursor is required for cleavage of its growth factor ectodomain and furthermore that the juxtamembrane region Pro161-Gln162-Leu163-Gln164-Glu165 (PQLQE) (residues 161-165 of the ectodomain) is an essential determinant of cell surface CSF-1(256) cleavage and that the cleavage site is partially sequence-specific. Furthermore, a mechanism of steric hindrance, which likely involves interference with protease accessibility, is postulated to explain the observed decreases in the cleavage efficiency in certain CSF-1 mutants. Finally, our results strongly suggest that the CSF-1 ectodomain is cleaved at or very near the cell surface by a membrane-associated proteolytic system.

Establishment and characterization of a human mixed-lineage, T-lymphoid/myeloid cell line (USP-91).

We report the establishment of a novel cell line from a pediatric patient with recurrent non-Hodgkin's lymphoma. This cell line, termed USP-91, showed both T-lymphoid cell as well as myeloid (ie, nonlymphoid) cell characteristics using a comprehensive multiparameter approach. The initial growth of this cell line was dependent on the presence of the murine stromal cell line, 14F1.1. Subsequently, a phenotypically stable, stroma-independent cell line was established. Although the recurrent biopsy material and the derivative cell line, USP-91, were clonally-derived from T-lineage lymphoid cells, as evidenced by the same rearrangement of the T-cell receptor-beta locus, USP-91 coexpressed both the T-cell antigens CD7, CD3, and CD4, and the myeloid antigens CD13, CD33, CD11b, and CD34. The myeloid features of USP-91 were most consistent with monocytic differentiation as these cells expressed alpha-napthol acetate esterase, lysozyme, alpha-1-antitrypsin, alpha-1-antichymotrypsin, as well as the cell surface receptor for macrophage colony-stimulating factor. In addition, incubation in the presence of phorbol esters induced USP-91 to exhibit morphologic and functional properties of mature mononuclear phagocytes. The expression of this bilineage phenotype suggests that USP-91 represents the malignant transformation of a progenitor cell capable of either myelomonocytic or T-lymphoid differentiation.

Proteolytic processing of a plasma membrane-bound precursor to human macrophage colony-stimulating factor (CSF-1) is accelerated by phorbol ester.

A transmembrane precursor to human macrophage colony-stimulating factor (M-CSF, CSF-1) is stably expressed at the cell surface where it is slowly and inefficiently cleaved to yield a soluble form of the growth factor. Incubation in the presence of phorbol ester resulted in rapid cleavage of the plasma membrane-bound precursor and release of soluble CSF-1. Within 60 min after phorbol treatment the quantity of growth factor recovered in the medium was more than 30-fold greater than that observed in the absence of the agent. The growth factor released in the presence of phorbol was biologically active and exhibited the same electrophoretic mobility as that obtained in the absence of the drug. Phorbol ester-accelerated processing of the cell surface CSF-1 precursor was abrogated by long-term exposure to phorbol, but was not inhibited by pretreatment with cycloheximide or incubation in serum-free medium. These results suggest that the enhanced post-translational processing of the CSF-1 precursor resulted from activation of a pre-existing cellular protease via a mechanism involving phorbol ester-mediated stimulation of protein kinase C.

Direct stimulation of cells expressing receptors for macrophage colony-stimulating factor (CSF-1) by a plasma membrane-bound precursor of human CSF-1.

Secreted forms of macrophage colony-stimulating factor (M-CSF or CSF-1) are generated by proteolytic cleavage of membrane-bound glycoprotein precursors. Alternatively spliced transcripts of the human CSF-1 gene encode at least two different transmembrane precursors that are differentially processed in mammalian expression systems. The larger precursor rapidly undergoes proteolysis to yield the secreted growth factor and does not give rise to forms of CSF-1 detected on the cell surface. By contrast, the smaller human CSF-1 precursor is stably expressed on the plasma membrane where it is inefficiently cleaved to release a soluble molecule. To determine whether the smaller precursor is biologically active on the cell surface, mouse NIH-3T3 fibroblasts expressing the different forms of human CSF-1 were killed by chemical fixation and tested for their ability to support the proliferation of cells that require this growth factor. Only fixed cells expressing human CSF-1 precursors on their surface stimulated the growth in vitro of a murine macrophage cell line or normal mouse bone marrow-derived mononuclear phagocytes. The ability of these nonviable fibroblasts to induce the proliferation of CSF-1-dependent cells was not mediated by release of soluble growth factor, required direct contact with the target cells, and was blocked by neutralizing antiserum to CSF-1. These results demonstrate that the cell surface form of the human CSF-1 precursor is biologically active and indicate that plasma membrane-bound growth factors can functionally interact with receptor-bearing targets by direct cell-cell contact.

Prostaglandin E2 inhibition of growth in a colony-stimulating factor 1-dependent macrophage cell line.

The effects of prostaglandin E2 (PGE2) were examined in a murine macrophage cell line (BAC1.2F5) that was completely dependent on colony-stimulating factor-1 (CSF-1) for both growth and survival. The addition of PGE2 to cultures of BAC1.2F5 cells resulted in the inhibition of CSF-1-induced [3H]thymidine incorporation and cell proliferation. The inhibitory effects of PGE2 were mimicked by the addition of dibutyryl-cyclic AMP, and the effectiveness of PGE2 was markedly potentiated by 1-methyl-3-isobutylxanthine, a potent inhibitor of cyclic nucleotide phosphodiesterase activity. PGE2 caused a 10-fold elevation of the intracellular cyclic AMP concentration, whereas CSF-1 neither increased cyclic AMP levels nor attenuated the rise in cyclic AMP promoted by PGE2. However, CSF-1 may indirectly regulate cyclic AMP levels since in the absence of CSF-1, BAC1.2F5 cells actively synthesized PGE2, whereas PGE2 production was abruptly terminated by the addition of CSF-1. In BAC1.2F5 cells, PGE2 increases the intracellular cyclic AMP concentration, thereby blocking cell proliferation, but does not down-regulate the CSF-1 receptor or abrogate the functions of CSF-1 necessary for cell survival.

The mononuclear phagocyte colony-stimulating factor (CSF-1, M-CSF).

The macrophage colony-stimulating factor-1 (CSF-1, M-CSF) induces the proliferation and supports the survival of mononuclear phagocytes and mediates its pleiotropic actions by binding to cell surface receptors encoded by the c-fms proto-oncogene. The structure, biologic activities, and therapeutic potential of CSF-1 and the role of its receptor in signal transduction in normal and transformed cells are discussed.

A point mutation in the extracellular domain of the human CSF-1 receptor (c-fms proto-oncogene product) activates its transforming potential.

A human CSF-1 receptor containing an "activating" mutation in its extracellular domain (serine for leucine 301) induced morphologic transformation, anchorage-independent growth, and tumorigenicity in mouse NIH 3T3 cells. A second regulatory mutation within the receptor's intracytoplasmic carboxy-terminal tail (phenylalanine for tyrosine 969) augmented transforming efficiency but was itself insufficient to induce transformation. Like the v-fms oncogene product, receptors bearing the activating mutation retained high-affinity binding sites for CSF-1 but were retarded in transport to the cell surface and were phosphorylated on tyrosine in the absence of ligand. Although the activating mutation does not affect the CSF-1 binding site in the receptor extracellular domain, it must induce a conformational change that mimics the effect of ligand binding, resulting in CSF-1-independent signals for cell growth.

Differential processing of colony-stimulating factor 1 precursors encoded by two human cDNAs.

The biosynthesis of macrophage colony-stimulating factor 1 (CSF-1) was examined in mouse NIH-3T3 fibroblasts transfected with a retroviral vector expressing the 554-amino-acid product of a human 4-kilobase (kb) CSF-1 cDNA. Similar to results previously obtained with a 1.6-kb human cDNA that codes for a 256-amino-acid CSF-1 precursor, the results of the present study showed that NIH-3T3 cells expressing the product of the 4-kb clone produced biologically active human CSF-1 and were transformed by an autocrine mechanism when cotransfected with a vector containing a human c-fms (CSF-1 receptor) cDNA. The 4-kb CSF-1 cDNA product was synthesized as an integral transmembrane glycoprotein that was assembled into disulfide-linked dimers and rapidly underwent proteolytic cleavage to generate a soluble growth factor. Although the smaller CSF-1 precursor specified by the 1.6-kb human cDNA was stably expressed as a membrane-bound glycoprotein at the cell surface and was slowly cleaved to release the extracellular growth factor, the cell-associated product of the 4-kb clone was efficiently processed to the secreted form and was not detected on the plasma membrane. Digestion with glycosidic enzymes indicated that soluble CSF-1 encoded by the 4-kb cDNA contained both asparagine(N)-linked and O-linked carbohydrate chains, whereas the product of the 1.6-kb clone had only N-linked oligosaccharides. Removal of the carbohydrate indicated that the polypeptide chain of the secreted 4-kb cDNA product was longer than that of the corresponding form encoded by the smaller clone. These differences in posttranslational processing may reflect diverse physiological roles for the products of the two CSF-1 precursors in vivo.

Colony-stimulating factor-1 receptor (c-fms).

The macrophage colony-stimulating factor, CSF-1 (M-CSF), is a homodimeric glycoprotein required for the lineage-specific growth of cells of the mononuclear phagocyte series. Apart from its role in stimulating the proliferation of bone marrow-derived precursors of monocytes and macrophages, CSF-1 acts as a survival factor and primes mature macrophages to carry out differentiated functions. Each of the actions of CSF-1 are mediated through its binding to a single class of high-affinity receptors expressed on monocytes, macrophages, and their committed progenitors. The CSF-1 receptor (CSF-1R) is encoded by the c-fms proto-oncogene, and is one of a family of growth factor receptors that exhibits an intrinsic tyrosine-specific protein kinase activity. Transduction of c-fms sequences as a viral oncogene (v-fms) in the McDonough (SM) and HZ-5 strains of feline sarcoma virus has resulted in alterations in receptor coding sequences that affect its activity as a tyrosine kinase and provide persistent signals for cell growth in the absence of its ligand. The genetic alterations in the c-fms gene that unmask its latent transforming potential abrogate its lineage-specific activity and enable v-fms to transform a variety of cells that do not normally express CSF-1 receptors.

Colony-stimulating factor 1-mediated regulation of a chimeric c-fms/v-fms receptor containing the v-fms-encoded tyrosine kinase domain.

A chimeric gene specifying the 308 N-terminal amino acids of the extracellular ligand binding domain of the human c-fms protooncogene joined to the remainder of the feline v-fms oncogene product encodes a functional colony-stimulating factor 1 (CSF-1) receptor. When expressed in mouse NIH 3T3 fibroblasts, the chimeric gene product was rapidly transported to the cell surface, was autophosphorylated on tyrosine only in response to human recombinant CSF-1, underwent ligand-induced but not phorbol ester-induced down-modulation, and stimulated CSF-1-dependent cell proliferation. By contrast, the C-terminally truncated glycoprotein encoded by the v-fms oncogene is partially inhibited in its transport to the plasma membrane, is constitutively phosphorylated on tyrosine, and is relatively refractory to both ligand-induced and phorbol ester-induced down-modulation. Although the v-fms oncogene can transform cells in the absence of CSF-1, its tyrosine kinase activity and turnover can be appropriately regulated by the human c-fms-encoded ligand binding domain. The results confirm that C-terminal truncation of the c-fms gene is insufficient to activate its transforming potential and suggest that an additional mutation in its distal extracellular domain is required for oncogenic activation.

Introduction of a human colony stimulating factor-1 gene into a mouse macrophage cell line induces CSF-1 independence but not tumorigenicity.

The SV40-immortalized mouse macrophage cell line, BAC1.2F5, is strictly dependent on CSF-1 for its survival and proliferation in culture. Introduction of a retroviral vector containing a 1.6 kilobase (kb) pair human CSF-1 cDNA into these cells abrogated their growth factor dependence but did not render the cells tumorigenic in nude mice. The infected macrophages contained multiple copies of the vector provirus, expressed both membrane-bound and secreted forms of CSF-1, and exhibited constitutive down modulation of the murine CSF-1 receptor. Because insertion of the v-fms gene has previously been shown to abrogate factor dependence and induce tumorigenicity in BAC1.2F5 macrophages, the failure of these cells to express a fully transformed phenotype after persistent stimulation by endogenous CSF-1 suggests that the v-fms and c-fms gene products provide different signals for cell proliferation.

Ligand-induced tyrosine kinase activity of the colony-stimulating factor 1 receptor in a murine macrophage cell line.

Metabolic labeling of simian virus 40-immortalized murine macrophages with 32Pi and immunoblotting with antibodies to phosphotyrosine demonstrated that the c-fms proto-oncogene product (colony-stimulating factor 1 [CSF-1] receptor) was phosphorylated on tyrosine in vivo and rapidly degraded in response to CSF-1. Stimulation of the CSF-1 receptor also induced immediate phosphorylation of several other cellular proteins on tyrosine. By contrast, the mature cell surface glycoprotein encoded by the v-fms oncogene was phosphorylated on tyrosine in the absence of CSF-1, suggesting that it functions as a ligand-independent kinase.

The colony-stimulating factor 1 (CSF-1) receptor (c-fms proto-oncogene product) and its ligand.

Alterations in genes that function in normal growth and development have been linked to malignant cell transformation. The mononuclear phagocyte colony-stimulating factor (CSF-1 or M-CSF) is a polypeptide growth factor synthesized by mesenchymal cells, which stimulates the survival, proliferation, and differentiation of haematopoietic cells of the monocyte-macrophage series. Multiple forms of soluble CSF-1 are produced by proteolytic cleavage of membrane-bound precursors, some of which are stably expressed at the cell surface. The c-fms proto-oncogene encodes the CSF-1 receptor, which is composed of an extracellular ligand-binding domain linked by a single membrane-spanning segment to a cytoplasmic tyrosine-specific protein kinase domain. Whereas the tyrosine kinase activity of the normal receptor is stimulated by CSF-1, mutations in the c-fms gene can constitutively activate the kinase to provide growth-stimulatory signals in the absence of the ligand. Oncogenic activation of the c-fms gene product appears to involve removal of a negative regulatory tyrosine residue near the carboxyl terminus of the receptor and one or more additional mutations that may simulate a conformational change induced by CSF-1 binding. Expression of the human c-fms gene in mouse NIH-3T3 cells confers a CSF-1 stimulated growth phenotype, indicating that receptor transduction is sufficient for fibroblasts to respond to a haematopoietic growth factor. In contrast, the v-fms oncogene induces factor-independent growth and tumorigenicity in factor-dependent myeloid cell lines, and contributes to the development of proliferative disorders of multiple haematopoietic lineages when introduced into murine bone marrow progenitors. Aberrant expression of an endogenous c-fms gene secondary to proviral insertion and transcriptional activation has also been implicated in virus-induced myeloblastic leukaemia in mice. The c-fms and CSF-1 genes have been mapped on the long arm of human chromosome 5, a region that frequently undergoes interstitial deletions in certain haematopoietic disorders including acute myelogenous leukaemia. The study of CSF-1 and its receptor should provide information concerning the role of tyrosine kinases in regulating the normal growth and differentiation of haematopoietic cells and in contributing to their malignant transformation.

Multilineage hematopoietic disorders induced by transplantation of bone marrow cells expressing the v-fms oncogene.

Mouse bone marrow cells infected with a helper-free retrovirus containing v-fms were engrafted into lethally irradiated mice. Dominant provirus-positive clones emerged in the spleens of some recipients within 1 month. When spleen cells were transplanted into lethally irradiated secondary recipients, clonal erythroleukemias or B cell lymphomas expressing the v-fms-coded glycoprotein developed. Other secondary recipients repopulated by "unmarked" progenitor cells or by cryptic provirus-positive precursors present in the spleens of the same donor mice did not develop disease; thus cells expressing v-fms did not invariably have a proliferative advantage after transplantation. Several primary engrafted recipients developed myeloproliferative disorders that were provirus-positive without evidence of clonality. Although expression of the c-fms product (CSF-1 receptor) is normally restricted to cells of the mononuclear phagocyte series, the v-fms-coded glycoprotein can contribute to proliferative abnormalities of multiple hematopoietic lineages.

Synthesis, post-translational processing, and autocrine transforming activity of a carboxylterminal truncated form of colony stimulating factor-1.

The mononuclear phagocyte colony stimulating factor encoded by a 1.6 kilobase pair human cDNA is synthesized as a homodimeric transmembrane glycoprotein that is released from the plasma membrane by proteolysis. Premature termination of the CSF-1 coding sequence upstream of its carboxylterminal transmembrane-spanning segment and expression of the truncated CSF-1 cDNA in either bovine papilloma virus or retrovirus vectors led to the synthesis of a soluble, biologically active growth factor that was rapidly secreted from cells. Like the full-length CSF-1 precursor, the truncated polypeptide was rapidly assembled through disulfide bonds immediately after synthesis and acquired asparagine-linked oligosaccharide chains that underwent progressive post-translational modifications during intracellular transport. Soluble CSF-1 encoded by the truncated cDNA stimulated the formation of bone marrow-derived mouse macrophage colonies in semisolid medium and induced transformation of mouse NIH-3T3 cells when coexpressed with the human c-fms proto-oncogene product (CSF-1 receptor). Compared to results obtained with the full-length CSF-1 cDNA, the efficiency of transformation obtained with the truncated CSF-1 gene was reduced, in spite of the fact that transfected cultures produced similar levels of the extracellular growth factor. The results indicate that CSF-1 amino acid residues 1-158 (together with the aminoterminal signal peptide at residues -32 to -1) are sufficient for biological activity and that CSF-1 cDNAs encoding either membrane-bound or soluble precursors are active in autocrine transformation.

Synthesis of membrane-bound colony-stimulating factor 1 (CSF-1) and downmodulation of CSF-1 receptors in NIH 3T3 cells transformed by cotransfection of the human CSF-1 and c-fms (CSF-1 receptor) genes.

NIH 3T3 cells cotransfected with the human c-fms proto-oncogene together with a 1.6-kilobase cDNA clone encoding a 256-amino-acid precursor of the human mononuclear phagocyte colony-stimulating factor CSF-1 (M-CSF) undergo transformation by an autocrine mechanism. The number of CSF-1 receptors on the surface of transformed cells was regulated by ligand-induced receptor degradation and was inversely proportional to the quantity of CSF-1 produced. A tyrosine-to-phenylalanine mutation at position 969 near the receptor carboxyl terminus potentiated its transforming efficiency in cells cotransfected by the CSF-1 gene but did not affect receptor downmodulation. CSF-1 was synthesized as an integral transmembrane glycoprotein that was rapidly dimerized through disulfide bonds. The homodimer was externalized at the cell surface, where it underwent proteolysis to yield the soluble growth factor. Trypsin treatment of viable cells cleaved the plasma membrane form of CSF-1 to molecules of a size indistinguishable from that of the extracellular growth factor, suggesting that trypsinlike proteases regulate the rate of CSF-1 release from transformed cells. The data raise the possibility that this form of membrane-bound CSF-1 might stimulate receptors on adjacent cells through direct cell-cell interactions.