The receptor for colony-stimulating factor 1 (CSF-1) is a ligand-activated protein-tyrosine kinase. It has been shown previously that the CSF-1 receptor is phosphorylated on serine in vivo and that phosphorylation on tyrosine can be induced by stimulation with CSF-1. We studied the phosphorylation of the CSF-1 receptor by using the BAC1.2F5 murine macrophage cell line, which naturally expresses CSF-1 receptors. Two-dimensional tryptic phosphopeptide mapping showed that the CSF-1 receptor is phosphorylated on several different serine residues in vivo. Stimulation with CSF-1 at 37 degrees C resulted in rapid phosphorylation on tyrosine at one major site and one or two minor sites. We identified the major site as Tyr-706. The identity of Tyr-706 was confirmed by mutagenesis. This residue is located within the kinase insert domain. There was no evidence that Tyr-973 (equivalent to Tyr-969 in the human CSF-1 receptor) was phosphorylated following CSF-1 stimulation. When cells were stimulated with CSF-1 at 4 degrees C, additional phosphotyrosine-containing phosphopeptides were detected and the level of phosphorylation of the individual phosphotyrosine-containing phosphopeptides was substantially increased. In addition, we show that CSF-1 receptors are capable of autophosphorylation at six to eight major sites in vitro.

The receptor for colony-stimulating factor-1 (CSF-1) is a receptor protein-tyrosine kinase. To study the possible function of CSF-1 receptor autophosphorylation, two autophosphorylation sites, Tyr-706, located in the kinase insert, and Tyr-807, a residue conserved in all protein-tyrosine kinases, were changed independently to either phenylalanine or glycine. Wild-type and mutant receptors were stably expressed in Rat-2 cells. In response to CSF-1, cells expressing Phe- or Gly-706 mutant receptors showed increased growth rate and altered cell morphology. Both the Phe- and Gly-706 mutant receptors associated with and phosphorylated phosphatidylinositol-3 kinase at levels comparable with those of wild-type receptors. However, these mutant receptors differed subtly from each other and from the wild-type receptor in their ability to induce different aspects of the response to CSF-1. The Phe-706 mutant receptor was most strongly affected in its ability to increase growth rate or elevate the levels of c-fos and NGF1A mRNAs, whereas the Gly-706 mutant receptor was most markedly affected in its ability to induce a change in cell morphology or increase the levels of c-jun and NGF1A mRNAs. These findings indicate that Tyr-706 itself, or this region of the receptor, may be important for interaction of the CSF-1 receptor with different signalling pathways. Gly-807 mutant receptors lacked protein-tyrosine kinase activity, failed to respond to CSF-1, and were defective in biosynthetic processing. Phe-807 mutant receptors had 40 to 60% reduced protein-tyrosine kinase activity in vitro. Although cells expressing Phe-807 receptors were able to respond to CSF-1, the changes in growth rate and cell morphology were significantly less than seen with wild-type receptors, and the induction of early response genes was also slightly lower than for the wild-type receptor. In contrast, Phe-807 receptors were equivalent to wild-type receptors when tested for their ability to interact with phosphatidylinositol-3 kinase. These findings indicate that phosphorylation of Tyr-807 may be important for full activation of the receptor.

The receptor for the myeloid cell growth factor colony stimulating factor 1 (CSF-1) is a protein tyrosine kinase that is closely related to the PDGF receptor. Ligand binding results in kinase activation and autophosphorylation. Three autophosphorylation sites, Tyr697, Tyr706 and Tyr721, have been mapped to the kinase insert domain. Deletion of the entire kinase insert domain completely abrogates signal transduction by the CSF-1 receptor expressed in Rat-2 fibroblasts. To investigate the function of individual phosphorylation sites present in the CSF-1 receptor kinase insert domain, a number of phosphorylation site mutants were expressed in Rat-2 fibroblasts. Mutation of either Tyr697 or Tyr721 compromised signal transduction by the CSF-1 receptor. A mutant receptor, in which both Tyr697 and Tyr721 were replaced by phenylalanine, has lost all ability to induce changes in morphology or to increase cell growth rate in response to CSF-1. Tyr721 has been identified recently as the binding site for PI 3-kinase. Here we report that GRB2 associates with the CSF-1 receptor upon ligand binding. The phosphorylation on tyrosine of SHC and several other GRB2-associated proteins increased upon stimulation with CSF-1. Tyr697 was identified as a binding site for GRB2. We suggest that PI 3-kinase, GRB2 and some of the GRB2-associated proteins could play an important role in signal transduction by the CSF-1 receptor.

It is clear that the number of receptor PTKs and PTPs encoded by a typical vertebrate genome is rather large. Although the signal pathways activated by the receptor PTKs may in many cases be common, specificity is provided by the ligand-binding domain and the availability of ligand. In addition, the precise spectrum of substrates that bind to and are phosphorylated by each receptor PTK can differ based on the number and nature of the autophosphorylation sites and on the repertoire of SH2-containing proteins and other substrates expressed in each cell type. It is also clear that receptor PTKs can activate multiple independent signaling pathways and that the output of these pathways can be integrated to provide a specific cellular response. The role of receptor PTPs in such integrated signaling networks is not yet obvious. In some cases, they may activate nonreceptor PTKs, whereas in other cases, they may counteract the effects of activated receptor and nonreceptor PTKs by dephosphorylating the PTKs themselves or their substrates. We know very little about the substrate specificity of PTPs, but in part this must be dictated by their subcellular location. It is possible that there are specific pairs of receptor PTKs and PTPs, which act in concert at the cell surface to activate and down-regulate specific signal pathways. Progress in understanding the function of receptor PTPs will depend on identifying ligands for receptor PTPs and then determining how ligand binding influences their activity.

To determine whether the receptor-like protein-tyrosine phosphatase, RPTP alpha, which is widely expressed in both the developing and adult mouse, is regulated by phosphorylation, we raised antiserum against a C-terminal peptide. This antiserum precipitated a 140-kDa protein from metabolically 35S-labeled NIH3T3 cells. Using this antiserum, we showed that endogenous RPTP alpha is constitutively phosphorylated in NIH3T3 cells, predominantly on two serines, which we identified as Ser-180 and Ser-204, lying in the juxtamembrane domain. 12-O-tetradecanoylphorbol-13-acetate (TPA) stimulation of quiescent NIH3T3 cells rapidly increased phosphorylation of Ser-180 and Ser-204. Purified protein kinase C (PKC) phosphorylated bacterially expressed RPTP alpha at Ser-180 and Ser-204. When wild type and S180A/S204A double mutant RPTP alpha S were transiently expressed in 293 human embryonic kidney cells, TPA stimulated phosphorylation of wild type but not of double mutant RPTP alpha. PKC down-regulation following prolonged exposure to TPA diminished TPA-stimulated RPTP alpha phosphorylation. Taken together, these results indicate that RPTP alpha is a direct substrate for (PKC). Examination of 293 cells expressing exogenous RPTP alpha using immunofluorescence confocal microscopy showed that RPTP alpha exists predominantly in two subcellular compartments: in dense intracellular granules or dispersed within the plasma membrane. TPA treatment caused redistribution of some intracellular RPTP alpha to the cell surface, but this did not require direct phosphorylation of RPTP alpha at Ser-180/Ser-204. Our results suggest that activation of PKC by cytokines modulates RPTP alpha function in several different ways.

Signal transduction initiated by a wide variety of extracellular signals involves the activation of protein-tyrosine kinases. Phosphorylated tyrosine residues in activated receptors or docking proteins then function as binding sites for the Src homology 2 (SH2) or phosphotyrosine-binding (PTB) domains of cytoplasmic signalling proteins. Shc is an adaptor protein that contains both PTB and SH2 domains and becomes phosphorylated on tyrosine in response to many different extracellular stimuli. These results have suggested that Shc is a prominent effector of protein-tyrosine kinase signalling. Thus far, only a single Shc phosphorylation site, the tyrosine at position 317 (Y317) has been identified. Phosphorylation of Y317 has been implicated in Grb2 binding and activation of the Ras pathway.