The differential expression of the cellular src-gene product pp60src and its phosphokinase activity in normal chicken cells and tissues

Chick embryos of different ages and adult chickens were examined for the expression of pp60c -src, the normal cellular homolog of the transforming protein of Rous sarcoma virus. In any brain extract, the pp60c -src kinase activity was always high, whereas muscle extracts of embryos show an age-dependent decrease in kinase activity. Adult animals show either no or barely measurable activity in muscle tissue. In contrast, liver cell extracts of embryos show an age-dependent increase in pp60c -src kinase activity, with adult chickens displaying the highest activity, very similar to that found in brain extracts. This demonstrates that increased expression of c-src is not necessarily correlated with cell proliferation, but suggests that, at an early stage of differentiation of mesenchymal cells, the relatively high expression of c-src could be responsible, at least in part, for the control of cell metabolism and proliferation.     

pp60c-src Kinase is in chick and human embryonic tissues

The normal cellular protein pp60c-src is a tyrosine-specific protein kinase that is homologous to the transforming protein of Rous sarcoma virus (RSV) but its function is unknown. The expression of pp60c-src in chick and human embryonic tissues was monitored by the immune complex protein kinase assay, Western transfer analysis, and immunocytochemical staining at the light microscope level. pp60c-src kinase was expressed in the head and trunk regions of the chick embryo at all stages of development examined; however, expression increased significantly during the major period of organogenesis (Hamburger and Hamilton stages 21 to 32). Western transfer analysis showed that the amount of pp60c-src protein increased in parallel with the increase in kinase activity. Highest levels of pp60c-src kinase were present in the neural tube, brain, and heart of the stage 32 chick embryo. Lower levels of activity were found in eye, limb bud, and liver. Immunocytochemical staining of the neural tube region and heart of the chick confirmed the results of biochemical analysis and showed immunoreactive pp60c-src distributed throughout the neural tube and heart. The distribution of pp60c-src kinase in human fetal tissues was similar to that in the chick embryo; elevated levels of pp60c-src kinase were present in cerebral cortex, spinal cord, and heart, but all other tissues examined expressed some pp60c-src kinase. The results of our studies suggest that pp60c-src plays a fundamental role in an aspect of cellular metabolism that is particularly important in electrogenic tissues.     

An alternative non-tyrosine protein kinase product of the c-src gene in chicken skeletal muscle.

While the c-src locus is expressed as a 4.0-kilobase (kb) mRNA coding for pp60c-src in various chicken tissues, including embryonic muscle, it is expressed as a novel 3.0-kb mRNA in adult skeletal muscle. We have analyzed the primary structure of this alternatively transcribed and spliced c-src mRNA. The sequence revealed three open reading frames, with the previously defined c-src exons 1 through 5 or 6 comprising the third, on the 3' untranslated region of this 3-kb mRNA. The exons coding for the tyrosine kinase domain of pp60c-src were excluded. On the 5' side, 2 kb of sequence upstream from the previously defined exon 1 of the c-src gene was included in this mRNA. The start site for the 3-kb mRNA probably lies downstream of that for the 4-kb mRNA. The first reading frame of the 3.0-kb mRNA, called sur (for src upstream region), encoded a 24-kilodalton (kDa) protein product rich in cysteine and proline residues. In vitro analysis indicated that the 24-kDa sur protein was membrane associated. Antibodies to sur protein detected in vivo a 24-kDa muscle-specific protein which was developmentally regulated and corresponded to the switch from the 4-kb to the 3-kb c-src mRNA. A striking kinetic pattern of appearance of sur protein and disappearance of pp60c-src suggests that the expression of these two proteins is inversely related.     

Neural tissues express high levels of the cellular src gene product pp60c-src.

Chicken embryo tissues were examined for the expression of pp60c-src, the normal cellular homolog of the transforming protein of Rous sarcoma virus. Three assays, including a solid-phase radioimmunoassay, a competitive radioimmunoprecipitation assay, and an immune complex protein kinase assay, were employed. Elevated levels of pp60c-src were detected in lysates from several neural tissues, including brain, retina, and spinal ganglia. Other tissues contained 8- to 10-fold-lower levels of pp60c-src, levels comparable to those found in chicken embryo fibroblasts. Expression of pp60c-src in brain tissues was also shown to vary with the developmental stage of the embryo.     

Osteoclasts express high levels of pp60c-src in association with intracellular membranes

Deletion of the c-src gene in transgenic mice by homologous recombination leads to osteopetrosis, a skeletal defect characterized by markedly deficient bone resorption (Soriano, P., C. Montgomery, R. Geske, and A. Bradley. 1991. Cell. 64:693-702), demonstrating a critical functional role of pp60c-src in osteoclast activity. Since decreased bone resorption could result from a defect either within the osteoclast or within other cells present in its environment, indirectly affecting osteoclast functions, we determined which cell(s) in bone expressed high levels of pp60c-src Measuring pp60c-src protein and kinase activities in osteoclasts and immunolocalizing pp60c-src in bone, we find that expression of pp60c-src is nearly as high in osteoclasts as in brain and platelets. In contrast, other bone cells contain only very low levels of the protein. In addition, expression of the c-src gene product increases when bone marrow cells are induced to express an osteoclast-like phenotype by 1,25-dihydroxy-vitamin D3, further suggesting that high expression of pp60c-src is part of the osteoclast phenotype. Three other src-like kinases, c-fyn, c-yes, and c-lyn, are also expressed in osteoclasts at ratios to pp60c-src similar to what is found in platelets. These src-related proteins do not, however, compensate for the absence of pp60c-src in the src- mice, thereby suggesting that pp60c-src may have a specific function in osteoclasts. Although further work is necessary to elucidate what the critical role of pp60c-src in osteoclasts is, our observation that the protein is associated mostly with the membranes of intracellular organelles suggests the possibility that this role might be at least in part related to the targeting or fusion of membrane vesicles.     

pp60c-src kinase activity in bovine coronary extracts is stimulated by ATP

pp60c-src kinase is believed to participate in regulating key cellular mechanisms including signal transduction and differentiation of smooth muscle during early embryogenesis. In this study, pp60c-src kinase activity was demonstrated in extracts from adult bovine coronary arterial smooth muscle. Activity, reflected by autophosphorylation of pp60c-src, phosphorylation of exogenous substrates, and phosphorylation of several endogenous substrates, was enhanced about 2 fold when added Mg2+ was replaced by Mn2+. Unexpectedly, activity was dramatically stimulated 20-50 fold by prior incubation with ATP. Such stimulation appears to be mediated through a novel mechanism which is independent of ATP-induced phosphorylation of reaction components. These new observations strongly suggest that a unique mechanism exists for regulation of coronary arterial pp60c-src kinase activity. Conceivably, this mechanism may serve important roles in modulating signal transduction and contractility of vascular smooth muscle.     

ATP- and polyphosphate-mediated stimulation of pp60c-src kinase activity in extracts from vascular smooth muscle

Recently, we reported that pp60c-src kinase activity was present in adult bovine coronary arterial smooth muscle and showed that the activity of the enzyme in in vitro immunoprecipitation assays was stimulated 20-60-fold by ATP (Di Salvo, J., Gifford, D., and Kokkinakis, A. (1988) Biochem. Biophys. Res. Commun. 153, 388-394). In the present study, ATP-mediated stimulation of activity was also demonstrated in extracts from aortic vascular smooth muscle. In contrast, no stimulation was apparent in extracts from brain. Stimulation of activity in vascular preparations was also induced with beta,gamma-imidoadenosine 5'-triphosphate (AMP.PNP), a nonmetabolizable analog of ATP, and with several other polyphosphates including ADP and sodium pyrophosphate. No stimulation occurred in response to monophosphates such as AMP or KH2PO4. As expected, the specific activity of pp60c-src in brain extracts did not change when the amount of extracted protein included in immunoprecipitation mixtures was increased. Unexpectedly, however, the specific activity of the vascular enzyme decreased markedly as the amount of extracted protein subjected to immunoprecipitation was increased. Following stimulation of pp60c-src in vascular extracts with ATP, the enzyme behaved in a fashion similar to pp60c-src extracted from brain. That is, the enhanced specific activity of the stimulated vascular enzyme did not decrease with increasing amounts of extracted protein. Moreover, mixing experiments in which vascular smooth muscle extracts were added to brain extracts showed that the muscle extracts contained a factor which inhibited pp60c-src kinase activity. This inhibition was blocked when the mixed extracts were immunoprecipitated in the presence of ATP, or when inhibitory extract was treated with trypsin. Taken together, these data suggest that pp60c-src kinase activity in vascular tissue may be subject to a novel regulatory mechanism involving an inhibitory protein factor which can be nullified by polyphosphates.     

Characterization of cDNA clones for the human c-yes gene.

Three c-yes cDNA clones were obtained from poly(A)+ RNA of human embryo fibroblasts. Sequence analysis of the clones showed that they contained inserts corresponding to nearly full-length human c-yes mRNA, which could encode a polypeptide of 543 amino acids with a relative molecular weight (Mr) of 60,801. The predicted amino acid sequence of the protein has no apparent membrane-spanning region or suspected ligand binding domain and closely resembles pp60c-src. Comparison of the sequences of c-yes and v-yes revealed that the v-yes gene contains most of the c-yes coding sequence except the region encoding its extreme carboxyl terminus. The region missing from the v-yes protein is the part that is highly conserved in cellular gene products of the protein-tyrosine kinase family.     

pp60c-src in the developing cerebellum.

pp60c-src was localized in the cerebellum of developing chicken embryos by immunoperoxidase staining with antisera raised against bacterially expressed pp60v-src. Immunoreactivity (IR) appeared in the cerebellum of the chicken embryos at the time of neuronal differentiation. pp60c-src IR was detected in regions of the developing cerebellum where processes of developing neurons and glia are located. In the early embryo (stage 17), pp60c-src IR was localized in the marginal zone of the cerebellar plate. By stage 40, pp60c-src IR was localized in the process-rich molecular layer of the cerebellum and between the cells of the developing internal granular layer. Cell bodies of cerebellar neurons did not show pp60c-src IR at any stage of development. Mitotically active neuroepithelial cells of the metencephalon did not express pp60c-src before the onset of differentiation in the early embryo, nor did proliferating cells of the external granular layer express pp60c-src at later stages. Although it is not possible to ascertain whether pp60c-src is localized in developing neurons or glia at the light microscope level, the time of its appearance and pattern of distribution in the molecular layer is suggestive of a localization within the developing neuronal processes which compose the bulk of this layer. Biochemical analyses of pp60c-src in the developing cerebellum by the immune complex protein kinase activity and sensitivity of the kinase to inhibition by P1,P4-di(adenosine-5')tetraphosphate confirmed that the expression of pp60c-src coincided with the time of neuronal differentiation. We conclude from these results that in the central nervous systems, pp60c-src may be more important in an aspect of cell differentiation or a mature neuronal function than in the proliferation of neuronal or glial precursors.     

The expression in eukaryotes of a tyrosine kinase which is reactive with pp60v-src antibodies

All specimens of Eumetazoa and Parazoa, ranging from mammals, birds, teleosts, sharks, lampreys, amphioxus, insects, down to sponges showed the pp60c-src associated kinase activity, indicating that c-src, which is the cellular homologue of the oncogene v-src of Rous sarcoma virus (RSV) is probably present in all multicellular animals. Protozoa and plants did not show pp60c-src kinase activity. The degree of c-src expression depends on the taxonomic rank of the Eumetazoa tested, and is organ-specific with nervous tissues displaying the highest kinase activities. In the central nervous system of mammals and birds we found a high c-src expression, and in that of the lampreys, amphioxus, and insects the lowest. Unexpectedly, total extracts of sponges showed an amount of pp60c-src kinase activity similar to that of brain cell extracts of mammals and birds. These findings suggest that pp60c-src is a phylogenetic old protein that might have evolved together with the multicellular organisation of Metazoa, and that might be of importance in proliferation and differentiation of nontransformed cells.     

A protein tyrosine kinase involved in regulation of pp60c-src function

We recently identified a novel protein tyrosine kinase that specifically phosphorylates truncated pp60c-src (Mr = 53,000) at a tyrosine residue(s) distinct from its autophosphorylation site. In this study, we examined whether this enzyme phosphorylates intact pp60c-src (Mr = 60,000) and determined its phosphorylation site. Non-neuronal and neuronal forms of intact pp60c-src were separately purified from the membrane fraction of neonatal rat brain by sequential column chromatographies. The novel kinase phosphorylated tyrosine residues of both forms of intact pp60c-src. The phosphorylation occurred in parallel with autophosphorylation of pp60c-src, and in both forms the final stoichiometry estimated was quite similar to that of autophosphorylation (about 5%). The enzyme also phosphorylated pp60c-src in which the kinase activity had been destroyed by an ATP analogue, p-fluorosulfonylbenzoyl 5'-adenosine. The phosphorylation site of the non-neuronal form was analyzed by sequential peptide mapping with tosylphenylalanyl chloromethyl ketone-treated trypsin and alpha-chymotrypsin. Tryptic digestion of the phosphorylated pp60c-src yielded a unique phosphopeptide that cross-reacted with an antibody specific for the carboxyl-terminal sequence of chicken pp60c-src. Digestion of the phosphopeptide with chymotrypsin yielded a product that comigrated with a synthetic phosphopeptide corresponding to the carboxyl-terminal 15 residues of chicken pp60c-src. These results clearly indicate that the carboxyl-terminal sequence of rat pp60c-src is identical to that of chicken pp60c-src, and a tyrosine residue corresponding to chicken Tyr527 is the phosphorylation site. This phosphorylation resulted in a decrease in the enolase phosphorylating activity of pp60c-src. Kinetic experiments indicated that this decrease in activity was due to a decrease in the Vmax value of pp60c-src. These findings support our previous proposal that the novel tyrosine kinase acts as a specific regulator of pp60c-src in cells.     

Association of p62c-yes with polyomavirus middle T-antigen mutants correlates with transforming ability.

A number of mutants of polyomavirus middle T antigen (MTag) were constructed into replication-competent avian retroviruses. To assess the ability of these MTag variants to transform and to associate with the avian p60c-src and p62c-yes proto-oncogene products, we used these viruses to infect chicken embryo fibroblasts. We found that the ability of individual mutant MTags to associate with p62c-yes correlated well with the ability of these mutants to transform, as has been previously shown for the association of MTag with p60c-src. All transformation-competent mutant MTags retained the ability to complex with p62c-yes. Two transformation-defective mutants, RX67 and RX68, which could weakly associate with p60c-src, were unable to associate with p62c-yes.dl1015, a transformation-defective mutant which could associate with p60c-src and with a phosphatidylinositol kinase activity, was also able to associate with p62c-yes. Therefore, some as yet unmeasured biochemical property is defective in this mutant.     

Mutation of a cysteine residue in polyomavirus middle T antigen abolishes interactions with protein phosphatase 2A, pp60c-src, and phosphatidylinositol-3 kinase, activation of c-fos expression, and cellular transformation.

Polyomavirus middle T antigen (MT) interacts with several cellular proteins involved in cell proliferation. MT forms complexes with protein phosphatase 2A (PP2A), pp60c-src (and the related kinases c-fyn and c-yes), and phosphatidylinositol-3 kinase. We made a single point mutation in MT, changing a conserved cysteine residue at position 120 to tryptophan, and characterized the biochemical and biological properties of the mutant (C120W) protein. The mutant MT protein does not associate with PP2A, pp60c-src, or phosphatidylinositol-3 kinase as judged by coimmunoprecipitation and associated phosphatase or kinase activity. The C120W mutant is defective in activation of c-fos expression and in morphological transformation of NIH 3T3 cells.     

The Expression in Eukaryotes of a Tyrosine Kinase Which is Reactive with pp60v-src Antibodies

Abstract. All specimens of Eumetazoa and Parazoa, ranging from mammals, birds, teleosts, sharks, lampreys, amphioxus, insects, down to sponges showed the pp60 ^c-src associated kinase activity, indicating that c-src , which is the cellular homologue of the oncogene v-src of Rous sarcoma virus (RSV) is probably present in all multicellular animals. Protozoa and plants did not show pp60 ^c-src kinase activity.
The degree of c-src expression depends on the taxonomic rank of the Eumetazoa tested, and is organ-specific with nervous tissues displaying the highest kinase activities. In the central nervous system of mammals and birds we found a high c-src expression, and in that of the lampreys, amphioxus, and insects the lowest. Unexpectedly, total extracts of sponges showed an amount of pp60 ^c-src kinase activity similar to that of brain cell extracts of mammals and birds. These findings suggest that pp60 ^c-src is a phylogenetic old protein that might have evolved together with the multi-cellular organisation of Metazoa, and that might be of importance in proliferation and differentiation of nontransformed cells.     

5''-flanking sequences that inhibit in vitro transcription of a xenopus laevis tRNA gene

We determined the nucleotide sequences of all coding regions and a significant part of the flanking regions of the chicken c-src gene, which is a cellular homolog of the v-src gene of Rous sarcoma virus. The c-src gene consists of 12 exons; the boundaries of the exons were determined by assuming that the amino acid sequence of its product, pp60c-src, is basically the same as that of pp60v-src. The deduced amino acid sequence of pp60c-src was very similar to that of pp60v-src, but the last 19 carboxy-terminal amino acids of pp60c-src were replaced by a new set of 12 amino acids of pp60v-src. The sequence encoding the carboxy-terminal sequence of pp60v-src was found 900 bp downstream from the termination codon of the c-src gene. We suggest that the c-src sequence was captured by a virus through recombination at both sides of the c-src gene, and that the recombinations occurred at the level of proviral DNA.     

Human cellular src gene: nucleotide sequence and derived amino acid sequence of the region coding for the carboxy-terminal two-thirds of pp60c-src.

The nucleotide sequence of the 3' two-thirds of a highly conserved, molecularly cloned human cellular src gene (c-src) has been determined. This region of the c-src gene encodes the tyrosine kinase domain of the cellular src protein (pp60c-src) and corresponds to exons 6 through 12 of the chicken c-src gene, as well as nucleotides 545 to 1542 of the Rous sarcoma virus src gene (v-src). The human c-src sequence is very strongly conserved with respect to both the chicken c-src and the Rous sarcoma virus v-src genes, with nearly 90% nucleotide homology observed in this region. Amino acid sequence conservation in this region is even greater; 98% of the amino acids are conserved between human and chicken c-src. Furthermore, the exon sizes and the locations of the exon-intron boundaries are identical in the human and chicken c-src genes. However, sequences within the introns have not been conserved, and the introns within the human c-src gene are significantly larger than the corresponding introns within the chicken c-src gene. The strong amino acid conservation between the carboxy-terminal two-thirds of pp60c-src of species as divergent as humans and chickens suggests that this portion of the pp60c-src protein specifies one or more functional domains that are of great importance to some aspect of normal cellular growth or differentiation.