Purification and characterization of caldesmon77: a calmodulin-binding protein that interacts with actin filaments from bovine adrenal medulla.

Caldesmon150, a protein composed of the Mr 150,000/147,000 doublet, alternately binds to calmodulin and actin filaments in a Ca2+-dependent "flip-flop" fashion. In all fibroblast cell lines examined, we also found a Mr 77,000 protein that crossreacts with anti-caldesmon150 antibody by using an immunoprecipitation technique [Owada, M.K., Hakura, A., Iida, K., Yahara, I., Sobue, K. & Kakiuchi, S. (1984) Proc. Natl. Acad. Sci. USA 81, 3133-3137]. In this report, we examine the tissue distribution of caldesmon by the method of immunoblotting, using caldesmon-specific antibody. Both caldesmon150 and caldesmon77 show widespread distribution in the tissues examined. Caldesmon77 is more widely distributed than caldesmon150, and we have purified caldesmon77 from bovine adrenal medulla. Its molecular weight estimated by NaDodSO4/polyacrylamide gel electrophoresis was 77,000, and a tetramer of this polypeptide may constitute the native molecule (Mr, 300,000). Caldesmon77 possesses a number of features in common with caldesmon150, including flip-flop binding to calmodulin and actin filaments depending on the concentration of Ca2+ and crossreactivity with caldesmon150-specific antibody. Analysis of caldesmon77-F actin interaction by sedimentation and electrophoresis revealed that 0.5 mg of caldesmon77 bound to 1 mg of F actin. This indicated that the molar ratio between caldesmon77 (tetramer) and actin monomer was calculated to be 1:12-14. In addition, caldesmon77 regulated the actin-myosin interaction in Ca2+-sensitive actomyosin obtained from adrenal medulla. These results suggest that caldesmon77 might be a ubiquitous actin-linked regulator of nonmuscle contractile processes, including those in adrenal medulla.     

Transformation-dependent increases in endogenous cytochalasin-like activity in chicken embryo fibroblasts infected by Rous sarcoma virus.

Transformation of chicken embryo fibroblasts by infection with Rous sarcoma virus has been shown to cause disruption of actin filament organization as seen with fluorescence staining techniques. This study is an attempt to use quantitative biochemical techniques to compare actin-related parameters in normal and transformed cells. Normal cells and cells infected with a temperature-sensitive mutant virus (NY68) and grown at the restrictive temperature of 41.5 degrees C have normal bundles of actin filaments, or F-actin; these cells also have about the same number of high-affinity cytochalasin binding sites at the ends of F-actin (approximately 5 pmol of sites per mg of cellular protein; Kd, 20 nM). In contrast, infected cells grown at the permissive temperature of 37 degrees C have a more diffuse pattern of actin filaments, and the number of cytochalasin binding sites in these transformed cells was below the level of detection. DNase I inhibition assays showed that the percent of unpolymerized actin, or G-actin, in cell extracts was not significantly different between normal and transformed cells (approximately 50%). In assays of cell extracts for endogenous cytochalasin-like activity on actin filaments (i.e., retardation of filament assembly at the fast-growing end, inhibition of cytochalasin binding to actin "nuclei," and decrease of low-shear viscosity of solutions of actin filaments), infected cells at 37 degrees C showed a higher level of activity per mg of protein than did uninfected cells or infected cells at 41.5 degrees C. These results suggest that the increase in endogenous cytochalasin-like activity in transformed cells may relate to the decrease in measurable cytochalasin binding sites and the abnormal distribution of actin filaments previously seen by fluorescence staining techniques.     

Transformation by Rous sarcoma virus: effects of src gene expression on the synthesis and phosphorylation of cellular polypeptides.

Infection of chicken embryo fibroblasts by Rous sarcoma virus induces a variety of alterations in cellular growth and morphology. We have used two-dimensional polyacrylamide gel electrophoresis to examine the effects of viral transformation on the pattern of synthesis and phosphorylation of cellular polypeptides. Infection by Rous sarcoma virus does not appear to induce the de novo synthesis, or the complete suppression, of any of the [35S]methionine-labeled cellular polypeptides that can be resolved with this technique; however, there are quantitative changes in a minor fraction (approximately 4%) of the [35S]methionine-labeled polypeptides. When cells labeled with [32P]orthophosphate were examined, a phosphorylated polypeptide, Mr 36,000, was detected in transformed cells; this polypeptide appears within 20 min when cells infected by a temperature-sensitive mutant of Rous sarcoma virus are shifted from the nonpermissive to the permissive temperature. Phosphorylation of the 36,000 Mr polypeptide thus represents an early event in the process of transformation, and it is possible that this polypeptide is a target for the kinase activity associated with pp60src.     

Phosphorylation of the fibronectin receptor complex in cells transformed by oncogenes that encode tyrosine kinases.

The fibronectin (FN) receptor in avian cells has been characterized previously as a complex of three membrane glycoproteins of about Mr 160,000, Mr 140,000, and Mr 120,000 (simply termed protein band 1, band 2, and band 3, respectively). Monoclonal antibodies to the band 3 protein of the complex prevent FN and laminin binding both in vivo and in vitro and enable the detection of the receptor proteins in the plasma membrane and in adhesion plaques. Association of the FN receptor proteins with the adhesion-plaque protein talin also has been reported. We now find that the band 2 and band 3 proteins in the complex are phosphorylated in Rous sarcoma virus-transformed chicken cells but not in normal chicken cells. Phosphorylation occurs predominantly on tyrosine and is accompanied by a reorganization of the receptor complex in the membrane of the transformed cells. Whereas normal cells contain the FN receptor in focal contacts and cellular processes between cells, v-src-transformed cells exhibit a more diffuse distribution of this receptor. In addition to the viral v-src oncogene, cells transformed by other avian oncogenes that also encode tyrosine kinases (v-fps, v-erbB, and v-yes) also express the receptor complex proteins in the phosphorylated state regardless of whether the transforming protein is detectable in adhesion plaques. These results suggest that the altered FN and laminin receptor proteins may contribute to the transformed phenotype, but their significance and role in the transformed state remain to be established.     

Tyrosylprotein kinase and phosphatase activities in membrane vesicles from normal and Rous sarcoma virus-transformed rat cells.

Membrane vesicles; isolated from normal and Rous sarcoma virus-transformed rat cells, have an associated cyclic-AMP independent kinase that phosphorylates a Mr 37,000 protein in vesicles from normal cells and proteins of Mr 37,000, 50,000, and 67,000 in vesicles from transformed cells. Proteins in vesicles from normal and transformed cells contain 9% and 77%, respectively, of their labeled phospho amino acids as phosphotyrosine. Thus, isolation of vesicles and subsequent incubation with [gamma-32P]ATP enriches the proportion of labeled phosphotyrosine in proteins (relative to other phospho amino acids) by two orders of magnitude over that found in intact cells. The in vitro phosphorylation of each of these proteins is enhanced in the presence of 10 microM Zn2+, a phosphotyrosylprotein phosphatase inhibitor. From these studies it appears that membrane vesicles may be a valuable system for examination of transformation-specific phosphorylation of proteins.     

Transforming gene product of Rous sarcoma virus phosphorylates tyrosine.

The protein kinase activity associated with pp60src, the transforming protein of Rous sarcoma virus, was found to phosphorylate tyrosine when assayed in an immunoprecipitate. Despite the fact that a protein kinase with this activity has not been described before, several observations suggest that pp60src also phosphorylates tyrosine in vivo. First, chicken cells transformed by Rous sarcoma virus contain as much as 8-fold more phosphotyrosine than do uninfected cells. Second, phosphotyrosine is present in pp60src itself, at one of the two sites of phosphorylation. Third, phosphotyrosine is present in the 50,000-dalton phosphoprotein that coprecipitates with pp60src extracted from transformed chicken cells. We infer from these observations that pp60src is a novel protein kinase and that the modification of proteins via the phosphorylation of tyrosine is essential to the malignant transformation of cells by Rous sarcoma virus. pp60sarc, the closely related cellular homologue of viral pp60src, is present in all vertebrate cells. This normal cellular protein, obtained from both chicken and human cells, also phosphorylated tyrosine when assayed in an immunoprecipitate. This is additional evidence of the functional similarity of these structurally related proteins and demonstrates that all uninfected vertebrate cells contain at least one protein kinase that phosphorylates tyrosine.     

Differences in intracellular location of pp60src in rat and chicken cells transformed by Rous sarcoma virus.

We have investigated the intracellular location of pp60src in Rous sarcoma virus-transformed rat cells (RR1022) by indirect immunofluorescence microscopy and cell fractionation. Immunofluorescence data suggest that pp60src is predominantly associated with the nuclear envelope and the juxtanuclear reticular membrane structures. The bulk of pp60src and of the associated phosphotransferase activity fractionated with nuclei and not with plasma membranes in disrupted cells. This localization contrasts strikingly with the association of pp60src with the plasma membrane of Rous sarcoma virus-transformed chicken fibroblasts. We propose that pp60src is a membrane protein that associates with cellular membranes through hydrophobic regions and that this membrane association is a general feature of the interaction of pp60src with avian and mammalian cells. Although there are major differences in the intracellular localizations of pp60src, it may interact with cellular membranes through one or more NH2-terminal hydrophobic regions.     

Calcium-dependent regulatory protein of cyclic nucleotide metabolism in normal and transformed chicken embryo fibroblasts.

The concentration of a calcium-binding protein modulator of 3':5'-cyclic-nucleotide phosphodiesterase (EC 3.1.4.17; 3':5'-cyclic-nucleotide 5'-nucleotidohydrolase) activity is increased in chicken embryo fibroblasts upon transformation by Rous sarcoma virus. This modulator protein from fibroblasts, which has roughly the same molecular size, charge, and functional properties as that isolated from chicken brain, comprises approximately 1.32% of the soluble protein in homogenates of fibroblasts infected and transformed by Rous sarcoma virus. In comparison, the modulator comprises approximately 0.30% of the soluble protein in homogenates of normal fibroblasts from confluent cultures and 0.36% of the soluble protein in homogenates of fibroblasts infected with a transformation-defective mutant of Rous sarcoma virus. Modulator levels in normal fibroblasts at subconfluent cell densities are 0.42-0.76% of the homogenate soluble protein, i.e., between that found in confluent normal fibroblasts and in fibroblasts transformed by Rous sarcoma virus. These observations suggest that the levels of the modulator protein are elevated under conditions in which chicken embryo fibroblasts are undergoing rapid growth and have decreased adenosine 3':5'-cyclic monophosphate levels.     

Processing of 60,000-dalton sarc gene protein synthesized by cell-free translation.

In this report we show that antiserum prepared against the Mr60,000 transformation-specific antigen of Rous sarcoma virus immunoprecipitates both the Mr60,000 and Mr 25,000 transformation-specific proteins that are synthesized by cell-free translation of virion RNA; however, in the cell-free system the Mr 60,000 protein appears to be synthesized as a precursor that is approximately Mr 2000 larger than the [35S]-methionine-labeled protein immunoprecipitated from Rous sarcoma virus-infected cells. Peptide mapping of the cell-free translation product and of this cellular protein has confirmed that they are structurally related to one another. The addition of membrane vesicles to the reticulocyte lysate system during translation specifically cleaves a Mr 2000 segment from the Mr 60,000 protein so that it comigrates with the cellular species. Secretory proteins and probably at least some integral membrane proteins are synthesized with short hydrophobic signal sequences at their NH2 terminus. Two facts suggest that the segment lost from the Mr 60,000 transformation-specific protein is a signal sequence: (i) the membrane vesicles process the Mr 60,000 protein only during translation, and (ii) the processed protein is sequestered by the vesicles.     

Morphological and histochemical properties of human embryonic cells transformed by Rous and polyoma viruses.

It is shown that human embryonic cells transformed by Rous sarcoma virus (stable cell line 23) and those transformed by polyoma virus (stable cell line P-2) are morphologically distinguished from the normal human embryonic cells. The mitotic activity of P-2 cells was 51% and the mitotic activity of 23 cells was 48%. While the mitosis activity of human embryo fibroblast was 28%. The duration of the mitosis of P-2 cells was 20 hours and that of 23 cells was 18 hr. The duration of the mitotic cycle of human embryo fibroblast was 18 hr. The G1 periods lasted 6 hours for both the cell lines; the S period of P-2 cells lasted 8 hr and the S period of 23 cells was 6 hr. Both the cell lines had a high content of RNA, DNA, protein bound SH-groups, and a high activity of acid phosphatase, acid RNAase and glucose-6-phosphatase. The content of glycogen, and acidic mucopolysaccharides, the activity of NADPH-tetrazolium reductase, succinic dehydrogenase of both the lines were the same as in normal human cells.     

Phosphorylation of ribosomal protein S6 in avian sarcoma virus-transformed chicken embryo fibroblasts

Protein phosphorylation was examined in whole cell extracts from normal and avian sarcoma virus-transformed chicken embryo fibroblasts. The addition of serum or epidermal growth factor to serum-starved normal cells resulted in increased 32P labeling of a Mr 30,000 protein. In extracts from cells transformed by a temperature-sensitive mutant of Schmidt-Ruppin virus, subgroup A, and grown at the permissive temperature, the protein was phosphorylated regardless of serum starvation. This Mr 30,000 protein was shown to be ribosomal protein S6, and the effects of avian sarcoma virus transformation on S6 phosphorylation were further investigated. The ability to phosphorylate S6 in the absence of serum was found to be temperature sensitive when S6 preparations from the temperature-sensitive mutant-infected cells incubated at permissive and nonpermissive temperatures were compared. Cells transformed by the parent virus (Schmidt-Ruppin, subgroup A) maintained the ability to phosphorylate S6 in the absence of serum when incubated at either temperature. Phosphoserine was the only phospho-amino acid detected in acid hydrolysates from phosphorylated S6 preparations.     

Detection of phosphotyrosine-containing 34,000-dalton protein in the framework of cells transformed with Rous sarcoma virus.

Phosphotyrosine-containing 34,000-dalton protein is detected by treatment of a two-dimensional gel of cellular framework with 1 M NaOH at 40 degrees C for 1 hr. The alkali-resistant 32PO4-labeled 34,000-dalton protein is detected in various cell lines transformed by Rous sarcoma virus but not in lines transformed by simian virus 40, polyoma virus, herpes simplex II virus, adenovirus type 2, or chemical carcinogens. In addition, interferons or fibronectin matrices have no detectable effect on the phosphorylation of the 34,000-dalton protein in Rous sarcoma virus-transformed cells.     

Active proliferation of Rous sarcoma virus-infected, but not normal, chicken heart mesenchymal cells in culture medium of physiological composition.

Normal as well as Rous sarcoma virus-infected chicken pectoral and chicken embryo fibroblasts proliferate actively in a plasma containing medium of physiological ion concentrations (Ca2+, 1.2 mM; Mg2+, 0.7 mM). Reduction of medium calcium and magnesium concentrations is necessary to achieve selective quiescence of normal fibroblasts in these cell systems. By contrast, normal chicken heart mesenchymal cells proliferate only sluggishly (one doubling or less during a 6-day period) in a plasma containing medium of physiologic ion concentrations, whereas Rous sarcoma virus-infected heart mesenchymal cells proliferate actively (more than four doublings during an initial 2-day phase of exponential growth). The chicken heart mesenchymal cell system therefore has great potential for studies of the mechanism that initiates cell replication and of the failure in cellular regulatory processes that is responsible for the autonomous initiation of replication of neoplastic cells. From comparison of the chicken heart mesenchymal cell system to dialyzed plasma-based systems in which 3T3 cells tend to proliferative quiescence, it is argued that this proliferative quiescence of 3T3 cells is a result of cell starvation and is not physiologically meaningful.     

Differences among 100-A filamentilament subunits from different cell types.

The protein subunit of 100-A filaments constitutes approximately 50% of the cytoskeleton protein of chick fibroblasts. In addition to the 43,000-dalton protein (constitutive actin) common to all cell types, fibroblast cytoskeletons contain a 58,000-dalton protein likely to be the 100-A filament subunit, whereas smooth muscle contains, instead, a 55,000-dalton protein. Additional differences among 100-A filaments are shown by immunofluorescence using antibodies angainst chick fibroblast 58,000-dalton component (anti-F58K) and against chick brain 100-A filament subunits (anti-BF). Anti-F58K binds to 100-A filaments in chick fibroblasts, presumptive myoblasts, chondroblasts, pigment cells, and neurons, but not to 100-A filaments in mouse or human fibroblasts. This antibody stains cables of 100-A filaments induced by sequentially treating cells with cytochalasin B and Colcemid. Anti-BF binds only to neurofilaments and not to 100-A filaments of other cell types studied. Absorption or antibodies with purified subunits from gizzard 100-A filaments eliminates binding of anti-F58K to the filaments of all cell types but does not diminish binding of anti-BF to neurofilaments. Various IgGs also bind nonspecifically to induced cables of 100-A filaments. The problem of nonspecific binding of labeled antibodies, as well as the problem of cell and species specificity of the 100-A filaments, is discussed.     

Levels of translatable mRNAs for cell surface protein, collagen precursors, and two membrane proteins are altered in Rous sarcoma virus-transformed chick embryo fibroblasts.

Transformation of chick embryo fibroblasts by Rous sarcoma virus results in decreased amounts of a major cell surface protein and of collagen. To determine the mechanism accounting for the decreased production of these proteins, we have measured the relative amounts of functional mRNAs for these and other transformation-sensitive proteins. Total cellular RNAs extracted from normal cells and from cells transformed by the Schmidt-Ruppin strain of Rous sarcoma virus were translated in a cell-free system derived from wheat germ. Analysis of the in vitro translation products of RNAs from normal and transformed chick embryo fibroblasts shows a 5-fold reduction in the translatable mRNA for cell surface protein and a 10-fold reduction in translatable mRNA for two collagen precursors. In addition, increases in functional mRNA are observed for myosin and for two membrane polypeptides with molecular weights of 95,000 and 78,000; the latter two proteins increase on transformation, but the increases are in large part secondary to the depletion of glucose from the medium of transformed cells. Our data suggest that some of the major cellular changes induced by oncogenic viruses are due to changes in the activity of specific cellular genes.     

Talin is phosphorylated on tyrosine in chicken embryo fibroblasts transformed by Rous sarcoma virus.

We have examined the extent of tyrosine phosphorylation of talin, a component of the cytoskeleton localized in the focal adhesions and, therefore, a potential substrate of p60v-src, the transforming protein of Rous sarcoma virus. p60v-src is a tyrosine kinase that induces high levels of phosphotyrosine and the disorganization of the cytoskeleton in transformed cells. With a polyclonal antibody utilized in a previous study [Maher, P. A., Pasquale, E. B., Wang, J. Y. J. & Singer, S. J. (1985) Proc. Natl. Acad. Sci. USA 82, 6576-6580] for the detection of tyrosine-phosphorylated proteins, we have detected phosphotyrosine residues in talin molecules immunoprecipitated from Rous sarcoma virus-transformed, but not normal, chicken embryo fibroblasts. Phospho amino acid analysis of talin from the infected cells confirmed the presence of phosphotyrosine, in addition to phosphoserine and phosphothreonine. The extent of tyrosine modification in talin was compared to that in vinculin, the other focal adhesion component previously found to contain enhanced levels of phosphotyrosine in various retrovirus-transformed cells. A considerably (3 times) larger fraction of the talin than of the vinculin molecules was found to be phosphorylated on tyrosine. The phosphorylation of talin on tyrosine may be crucial for the expression of the abnormal morphology characteristic of cells transformed by Rous sarcoma virus.     

Filamin, a new high-molecular-weight protein found in smooth muscle and non-muscle cells.

A new high-molecular-weight protein, named filamin, was isolated from chicken gizzard. In chicken gizzard, filamin is present in an amount approximately 30-40% of that of myosin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of highly purified filamin revealed a single polypeptide of about 250,000 daltons. Rabbit antibody directed against purified chicken gizzard filamin did not crossreact with myosin purified from the same source. By the use of microcomplement fixation and indirect immunofluorescent staining with antibodies to chicken gizzard filamin, an antigenically similar or identical protein was found to be widely distributed both in other organs of the chicken and in cultured cells of other species, but not in chicken skeletal muscle. In cultured cells, filamin was found largely to be arranged as a filamentous array very similar to that found for myosin. These data imply that filamin is a widely occurring and chemically conserved component of filaments is smooth muscle and non-muscle cells.     

Association of microtubules and intermediate filaments in normal fibroblasts and its disruption upon transformation by a temperature-sensitive mutant of Rous sarcoma virus.

By double indirect immunofluorescence, using primary rabbit antibodies to tubulin and guinea pig antibodies to vimentin, we have simultaneously labeled microtubules and intermediate filaments in several types of cultured normal fibroblasts. With well-spread interphase cells there was an extensive but not complete correspondence of the labeling patterns for the two filamentous structures out to the cell periphery. This correspondence existed both at a gross level, where parallel but not coincident arrays of thickly labeled strands of the two types of filaments were observed, and at a fine level, where thinly labeled strands of the two were superimposed. The results suggest that there may be some type(s) of molecular linkages between microtubules and vimentin intermediate filaments that is under metabolic control. With NRK fibroblasts infected with a temperature-sensitive mutant (LA23) of Rous sarcoma virus, cells grown at the nonpermissive temperature (39 degrees C) showed the correspondence of the distributions of the microtubules and intermediate filaments characteristic of the normal phenotype but within 1 hr after a shift to the permissive temperature (33 degrees C) there was an extensive retraction of the intermediate filaments around the cell nucleus whereas the microtubules remained dispersed into the cell periphery. These results suggest that one of the functions carried out by p60src, the protein kinase responsible for transformation by Rous sarcoma virus, may be to modify the component(s) involved in the putative linkages between microtubules and intermediate filaments in the normal cells.