Association of pp36, a phosphorylated form of the presumed target protein for the src protein of Rous sarcoma virus, with the membrane of chicken cells transformed by Rous sarcoma virus

Annexin II tetramer: structure and function

The annexins are a family of proteins that bind acidic phospholipids in the presence of Ca2+. The interaction of these proteins with biological membranes has led to the suggestion that these proteins may play a role in membrane trafficking events such as exocytosis, endocytosis and cell-cell adhesion. One member of the annexin family, annexin II, has been shown to exist as a monomer, heterodimer or heterotetramer. The ability of annexin II tetramer to bridge secretory granules to plasma membrane has suggested that this protein may play a role in Ca(2+)-dependent exocytosis. Annexin II tetramer has also been demonstrated on the extracellular face of some metastatic cells where it mediates the binding of certain metastatic cells to normal cells. Annexin II tetramer is a major cellular substrate of protein kinase C and pp60src. Phosphorylation of annexin II tetramer is a negative modulator of protein function.

Novel tyrosine kinase substrates from Rous sarcoma virus-transformed cells are present in the membrane skeleton

We have previously reported the production of monoclonal antibodies directed against phosphotyrosine, which is the modification induced by many oncogene products and growth factor receptors. One of these antiphosphotyrosine antibodies (py20) was used in affinity chromatography to isolate phosphotyrosine (PY)-containing proteins from Rous sarcoma virus-transformed chick embryo fibroblasts (RSV-CEFs). Mice were immunized with these PY-proteins for the production of monoclonal antibodies to individual substrates. Fifteen antibodies were generated in this way to antigens with molecular masses of 215, 76, 60, and 22 kD. Antibodies to individual substrates were used to analyze the subcellular location in normal and RSV-CEFs. Antibodies to the 215- and 76-kD antigen stained focal contacts when used in immunofluorescence microscopy while anti-22-kD protein antibodies resulted in punctate staining concentrated in the margins of cells and in parallel arrays. Both distributions were altered in transformed cells. When cells were extracted with nonionic detergent under conditions that stabilize the cytoskeleton, 50% of the 76-kD protein and greater than 90% of the 22-kD protein fractionated with the cytoskeleton. This study offers a new approach to both the identification of membrane skeletal proteins in fibroblasts and changes that occur upon transformation by an activated tyrosine kinase.

The tyrosine phosphorylation substrate p36 is developmentally regulated in embryonic avian limb and is induced in cell culture

The 36-kD protein-tyrosine kinase substrate p36 has been variously postulated to be involved in membrane-cytoskeletal interactions, membrane traffic, and the regulation of phospholipase A2, and its phosphorylation may play some role in malignant transformation by avian sarcoma viruses. Because embryonic tissues are resistant to transformation by avian sarcoma viruses, we have examined the expression of p36 in the developing avian embryonic limb. The level of p36 increased progressively from day 5 to day 14 of development. It was largely absent from day-5 mesenchyme, and was induced during the differentiation of mesenchymal cells into connective tissue and cartilage, but was not induced in differentiating muscle. In contrast, p36 was detected in ectodermal cells at all developmental stages examined. When day-5 limbs were dissociated and cultured, p36 was induced in all adherent cells, beginning at 2-4 h after plating, and reaching levels comparable to those observed with intact day-14 limb tissue within 48 h. The accumulation of p36 in culture was dependent on substratum adherence, suggesting that its stability is regulated by cell attachment or spreading. These findings are consistent with a structural or mechanical role for p36.

Isolation of a cDNA clone complementary to sequences for a 34-kilodalton protein which is a pp60v-src substrate

We have isolated a partial cDNA clone containing sequences complementary to a mRNA encoding a 34- to 36-kilodalton normal chicken cell protein which is a substrate for pp60v-src kinase activity. Using this 34-kilodalton cDNA clone as a probe, we determined that the size of the 34-kilodalton mRNA was 1,100 nucleotides and the level of the 34-kilodalton RNA was the same in various tissues of mature chickens but was significantly higher in chicken embryo fibroblast cells.

Functional domains of the pp60v-src protein as revealed by analysis of temperature-sensitive Rous sarcoma virus mutants

Four temperature-sensitive (ts) Rous sarcoma virus src gene mutants with lesions in different parts of the gene represent three classes of alteration in pp60src. These classes are composed of mutants with (i) heat-labile protein kinase activities both in vitro and in vivo (tsLA27 and tsLA29), (ii) heat-labile kinases in vivo but not in vitro (tsLA33), and (iii) neither in vivo nor in vitro heat-labile kinases (tsLA32). The latter class indicates the existence of structural or functional pp60src domains that are required for transformation but do not grossly affect tyrosine kinase activity.

Cellular localization of the transforming protein of wild-type and temperature-sensitive Fujinami sarcoma virus

Fujinami sarcoma virus (FSV) encodes a 140,000-dalton transforming protein, P140, which contains gag- and fps-specific sequences. The cellular localization of this protein was examined by fractionation of [35S]methionine-labeled, FSV-infected chicken embryo fibroblasts. In homogenates of cells infected by wild-type, temperature-resistant FSV prepared in either hypotonic or isotonic buffer, 60 to 80% of the P140 was particulate. Isopycnic separation on discontinuous sucrose gradients indicated that the majority of the particulate P140 was present in a light membrane fraction enriched for plasma membranes. Much of the particulate P140 could be solubilized by the addition of 0.6 M salt to a postnuclear supernatant, suggesting that P140 is not an integral membrane protein. Particulate P140 may be associated with membranes either directly as a peripheral membrane protein or indirectly via cytoskeletal elements. In cells infected by mutants of FSV temperature sensitive for cellular transformation, most of the P140 is particulate at the permissive temperature, whereas most is soluble at the nonpermissive temperature; this change in distribution is not a secondary consequence of the change in cellular phenotype, since it also occurs in nonconditionally transformed cells doubly infected with temperature-sensitive FSV and wild-type Rous sarcoma virus. The movement of P140 from the particulate to the soluble fraction occurs rapidly when cells infected by temperature-sensitive FSV are shifted from the permissive to the nonpermissive temperature. Furthermore, P140 moves from the soluble to the particulate fraction, although somewhat more slowly, when cells are shifted from the nonpermissive to the permissive temperature. These observations suggest that the association of P140 with plasma membranes or the cytoskeleton may play a role in transformation by FSV.

Isolation of a cDNA clone complementary to sequences for a 34-kilodalton protein which is a pp60v-src substrate

We have isolated a partial cDNA clone containing sequences complementary to a mRNA encoding a 34- to 36-kilodalton normal chicken cell protein which is a substrate for pp60v-src kinase activity. Using this 34-kilodalton cDNA clone as a probe, we determined that the size of the 34-kilodalton mRNA was 1,100 nucleotides and the level of the 34-kilodalton RNA was the same in various tissues of mature chickens but was significantly higher in chicken embryo fibroblast cells.

Functional domains of the pp60v-src protein as revealed by analysis of temperature-sensitive Rous sarcoma virus mutants

Four temperature-sensitive (ts) Rous sarcoma virus src gene mutants with lesions in different parts of the gene represent three classes of alteration in pp60src. These classes are composed of mutants with (i) heat-labile protein kinase activities both in vitro and in vivo (tsLA27 and tsLA29), (ii) heat-labile kinases in vivo but not in vitro (tsLA33), and (iii) neither in vivo nor in vitro heat-labile kinases (tsLA32). The latter class indicates the existence of structural or functional pp60src domains that are required for transformation but do not grossly affect tyrosine kinase activity.

Biochemical characterization of a 34-kilodalton normal cellular substrate of pp60v-src and an associated 6-kilodalton protein

Transformation of fibroblasts by several retroviruses that produce transforming gene products associated with protein kinase activity results in the phosphorylation of a normal cellular protein with an Mr of 34,000 (the 34K protein). Evidence is presented here that, as extracted from chicken embryo fibroblasts, this protein exists in two forms that differ both in their elution from hydroxylapatite and in their native molecular weight. The form that eluted from hydroxylapatite at 210 to 295 mM potassium phosphate displayed a native molecular weight of 30,000 to 40,000, whereas the form that eluted at 320 to 440 mM displayed a native molecular weight of 60,000 to 70,000. The latter form copurified with a low-molecular-weight protein with an approximate Mr of 6,000 (6K). Both forms of 34K were completely separable from malate dehydrogenase activity. Phosphorylated 34K, isolated from Rous sarcoma virus-transformed cells, was also present in two forms; hence, in the cell neither form serves as a preferential substrate for pp60v-src. We found that the expression of 34K differed greatly in various avian tissues. In particular, it was present in the highest concentration in cultured fibroblasts and in very low concentration in brain tissue. Its expression in this tissue seems to be controlled at the level of transcription, since 34K mRNA in brain tissue was barely detectable. The expression of 6K was similar to that of 34K.

Changes in the distribution of the 34-kdalton tyrosine kinase substrate during differentiation and maturation of chicken tissues

We examined the distribution of the 34-kilodalton (34-kD) tyrosine kinase substrate in tissues of adult and embryonic chicken using both a mouse monoclonal antibody and a rabbit polyclonal antibody raised against the affinity purified 34 kD protein. We analyzed the localization by immunoblotting of tissue extracts, by immunofluorescence staining of frozen tissue sections, and by staining sections of paraffin-embedded organs by the peroxidase antiperoxidase method. The 34-kD protein was present in a variety of cells, including epithelial cells of the skin, gastrointestinal, and respiratory tracts, as well as in fibroblasts and chondrocytes of connective tissue and mature cartilage, and endothelial cells of blood vessels. The 34-kD protein was also found in subpopulations of cells in thymus, spleen, bone marrow, and bursa. The protein was not detected in cardiac, skeletal, or smooth muscle cells, nor in epithelial cells of liver, kidney, pancreas, and several other glands. Although most neuronal cells did not contain the 34-kD protein, some localized brain regions did contain detectable amounts of this protein. The 34-kD protein was not detected in actively dividing cells of a number of tissues. Changes in the distribution of the 34-kD protein were observed during the differentiation or maturation of cells in several tissues including epithelial cells of the skin and gastrointestinal tract, fibroblasts of connective tissue, and chondroblasts.

The 46,000-dalton tyrosine protein kinase substrate is widespread, whereas the 36,000-dalton substrate is only expressed at high levels in certain rodent tissues

Proteins of molecular mass 46,000 (p46) and 34,000-39,000 (p36) daltons are phosphorylated at tyrosine in Rous sarcoma virus-transformed chicken and mouse fibroblasts. p46 has recently been identified as an isozyme of enolase but the function of p36 is unknown. The expression of these proteins in various mouse and rat tissues has been examined. In most tissues, except muscle, p46 is found at relatively constant levels. In muscle, a more basic, related protein is present. In contrast, the abundance of p36 varies more widely from tissue to tissue, suggesting that it has a function in some but not all differentiated cells. By SDS gel electrophoresis and immunoblotting, high levels of p36 (60-120% of its relative abundance in fibroblasts) were found in small intestine, lung, and thymus, and intermediate levels (20-50%) were found in spleen, lymph nodes, and testes. No p36 was detectable in brain and muscle. Where studied, p36 mRNA expression paralleled protein levels. The cell types within each tissue expressing p36 were identified by immunofluorescence and immunoperoxidase staining. These cell types include all endothelial cells and fibroblastic cells examined, as well as various epithelial cells, cardiac muscle cells, macrophages, and testicular interstitial cells. We were unable to detect p36 in skeletal or smooth muscle cells, erythrocytes, nerve cells, or lymphocytes in any of the examined tissues. p36 appears to be concentrated in the terminal web region of intestinal columnar epithelial cells.

Biochemical characterization of a 34-kilodalton normal cellular substrate of pp60v-src and an associated 6-kilodalton protein

Transformation of fibroblasts by several retroviruses that produce transforming gene products associated with protein kinase activity results in the phosphorylation of a normal cellular protein with an Mr of 34,000 (the 34K protein). Evidence is presented here that, as extracted from chicken embryo fibroblasts, this protein exists in two forms that differ both in their elution from hydroxylapatite and in their native molecular weight. The form that eluted from hydroxylapatite at 210 to 295 mM potassium phosphate displayed a native molecular weight of 30,000 to 40,000, whereas the form that eluted at 320 to 440 mM displayed a native molecular weight of 60,000 to 70,000. The latter form copurified with a low-molecular-weight protein with an approximate Mr of 6,000 (6K). Both forms of 34K were completely separable from malate dehydrogenase activity. Phosphorylated 34K, isolated from Rous sarcoma virus-transformed cells, was also present in two forms; hence, in the cell neither form serves as a preferential substrate for pp60v-src. We found that the expression of 34K differed greatly in various avian tissues. In particular, it was present in the highest concentration in cultured fibroblasts and in very low concentration in brain tissue. Its expression in this tissue seems to be controlled at the level of transcription, since 34K mRNA in brain tissue was barely detectable. The expression of 6K was similar to that of 34K.

Identity of p36K phosphorylated upon Rous sarcoma virus transformation with a protein purified from brush borders; calcium-dependent binding to non-erythroid spectrin and F-actin

Membrane vesicles derived from the apical side of procine intestinal epithelial cells retain, after demembranation in the presence of calcium, two major proteins (I, II) which are released by the addition of calcium chelators. We have purified and characterized these two calcium-binding proteins. Protein I has a mol. wt. of 85 000 and contains two copies of a 36-K subunit and an additional 10-K subunit. It binds in a calcium-dependent manner to F-actin as well as to non-erythroid spectrin. Immunofluorescence microscopy reveals protein I-related antigens in the terminal web of the intestinal cell and in a submembraneous cortical layer in various tissue culture cells. Biochemical and immunological results document that the 36-K subunit of protein I is identical with the cellular p36K recognized as a major substrate for tyrosine phosphorylation by the sarc gene kinase in Rous sarcoma virus-transformed cells. The biochemical properties of protein I agree with its location seen in immunofluorescence microscopy and cell fractionation and suggest that the actin-spectrin network in the cortical layer may be affected by virus transformation.

Membrane association of a 36,000-dalton substrate for tyrosine phosphorylation in chicken embryo fibroblasts transformed by avian sarcoma viruses

A cellular protein of 36,000 daltons becomes phosphorylated at tyrosine in chicken embryo fibroblasts transformed with avian sarcoma viruses. We have used cellular fractionation and immunofluorescence to locate the 36-kdalton protein in virus-transformed and uninfected chicken fibroblasts. The 36-kdalton protein in transformed cells fractionated mainly with high-speed particulate material, and in density gradient separations, the 36-kdalton protein was found in association with light density membranes together with most of the plasma membrane marker. Increasing the concentration of salt or adding ion chelators solubilized some of the 36-kdalton protein that otherwise was pelletable with high g forces. Based on these data, we conclude that this protein is peripherally or indirectly attached to light density membranes, including plasma membranes. Indirect immunofluorescent staining of the 36-kdalton protein in fixed cells revealed that it was located inside the cell in an extensive reticulum apposed to surface membranes. The same pattern of staining was found in both uninfected and virus-transformed cells. Pretreatment of cells with nonionic detergents before fixation altered or abolished 36-kdalton staining. The 36-kdalton protein appeared to be excluded from regions of the cells where actin cables were present. The pattern of staining observed with the anti-36-kdalton antibody was similar, but not identical, to that observed with antiserum against nonerythroid spectrin. Thus, the data obtained by biochemical fractionation and by immunofluorescent staining indicate that the 36-kdalton protein is found in a reticulum at the inner surface of the plasma membrane, possibly in association with cytoskeletal proteins.