p37mos-associated serine/threonine protein kinase activity correlates with the cellular transformation function of v-mos.

A serine/threonine-specific protein kinase activity is closely associated with v-mos-encoded proteins. Experiments were conducted with several mutant forms of p37mos to determine whether or not the kinase function correlates with the biological activity of the mutant v-mos genes. Two mutants lacking cell transformation activity, one an arginine substitution for lysine-121 in the putative ATP-binding site and the other a 23-amino acid deletion from the C-terminal end of p37mos, had no kinase activity associated with their mutant proteins. However, a third mutant with reduced biological activity had drastically less kinase activity than the wild-type protein. The latter mutant was able to phosphorylate the kinase-inactive p37mos(Arg-121) protein in vitro. These results indicate that even though p37mos(Arg-121) can be phosphorylated in trans by other kinase molecules, it lacks the ability to phosphorylate itself in vitro. This provides a compelling argument that the protein kinase function of p37mos is an intrinsic property of the protein. Moreover, since the kinase function correlates with the cellular transformation activity of the v-mos gene, we predict that it is required for the biological activity of the v-mos gene.     

Use of site-specific antipeptide antibodies to perturb the serine kinase catalytic activity of p37mos.

The mos oncogene of Moloney murine sarcoma virus encodes a protein of approximately 37,000 daltons (designated p37mos). We have detected a serine protein kinase activity which is closely associated with p37mos in immune complexes obtained with antibodies [anti-mos(37-55) serum] that were generated with a peptide containing amino acids 37 through 55 of the v-mos protein (S. A. Maxwell and R. B. Arlinghaus, Virology 143:321-333, 1985). Immune complexes that were derived with antibodies generated against peptides representing the C-terminal 8 or 12 amino acids of v-mos (anti-C2 and anti-C3 serum, respectively) exhibited very little kinase activity capable of phosphorylating p37mos. Treatment of anti-mos(37-55) complexes containing active v-mos kinase with anti-C3 or anti-C2 serum resulted in a dramatic reduction of the in vitro phosphorylation of p37mos. Antiserum blocked with the appropriate C-terminal peptide had no inhibitory effect on the phosphorylation of p37mos in anti-mos(37-55) complexes which indicated that the inhibition of v-mos kinase activity was a specific effect of these antibodies. The specific inhibition of the in vitro phosphorylation of p37mos by antibodies directed against the C terminus of the v-mos protein provides strong evidence that the v-mos gene encodes a serine protein kinase. In addition, the extreme C terminus of p37mos may be critical for an active v-mos kinase.     

Transfection of a mutant regulatory subunit gene of cAMP-dependent protein kinase causes increased drug sensitivity and decreased expression of P-glycoprotein

Wild-type Chinese hamster ovary (CHO) cells were transfected with a DNA clone (MT-REV, site A) carrying a mouse gene for a dominant mutant regulatory subunit (RI) gene of cAMP-dependent protein kinase (PKA) from S49 cells along with a marker for G418 resistance. G418-resistant transfectant clone R-2D1 was resistant to 8-Br-cAMP-induced growth inhibition and morphological changes. The cells also did not phosphorylate a 50-kDa protein after cAMP stimulation and had decreased PKA activity, both characteristics of PKA mutants. Northern blot analysis indicated that clone R-2D1 was actively transcribing the MT-REV (site A)-specific RNA. We also tested clone R-2D1 for sensitivity to certain natural product hydrophobic drugs and found increased sensitivity to several drugs including adriamycin. Hypersensitivity to these drugs has previously been shown by us to be a characteristic of a CHO PKA mutant cell line. Expression of the mutant RI gene is also associated with a decrease in expression of the multidrug resistance associated P-glycoprotein (gp170) mRNA and protein. These results show that the PKA mutant RI gene from S49 cells acts as a dominant mutation to reduce the total PKA activity in the CHO transfectants as it does in mouse S49 cells. This study also confirms that reduced PKA activity modulates the basal multidrug resistance of these cells, apparently by causing decreased expression of the mdr gene at the protein and mRNA level.     

mos gene transforming efficiencies correlate with oocyte maturation and cytostatic factor activities.

The mos proto-oncogenes from different vertebrate species transform mouse NIH 3T3 cells with markedly different efficiencies. v-mos, mouse (c-mosmu), and chicken (c-mosch) mos transform NIH 3T3 cells 10- to 100-fold more efficiently than do human (c-moshu) and Xenopus (c-mosxc) mos. The mos genes with the highest transforming activity efficiently induce maturation in Xenopus oocytes and mimic cytostatic factor (CSF) by causing mitotic cleavage arrest in embryos. Chimeric v-mos/c-moshu proteins that had high transforming efficiencies in NIH 3T3 cells were also effective in the induction of oocyte maturation and CSF cleavage arrest. We measured the in vitro autophosphorylation activities of the different mos proteins and found that the levels of kinase activity of v-mos, c-mosmu, and c-mosch were much higher than that of c-mosxc. These data indicate that mos gene transforming efficiency and the ability to induce oocyte maturation or mimic CSF activity are correlated with in vitro autophosphorylation activity and suggest that the mos protein plays a similar role in transformed cells and normal oocytes.     

The transforming protein of Moloney murine sarcoma virus is a soluble cytoplasmic protein

The transforming gene, v-mos, of Moloney murine sarcoma virus (M-MuSV) encodes a 37,000-dalton phosphoprotein, p37mos. Since the biochemical function of this protein is unknown, we have determined the subcellular location of p37mos in M-MuSV 124-transformed cells. Using two different methods of cell lysis and fractionation, we found that newly synthesized as well as mature p37mos is a soluble cytoplasmic protein. In agreement with these results, immunofluorescent staining of cells acutely infected with M-MuSV 124, using an antiserum directed against a synthetic v-mos peptide, produced a diffuse cytoplasmic pattern. Gel filtration experiments and glycerol gradient sedimentation analysis suggest that the bulk of p37mos exists as a monomer and is not involved in a specific association with other cellular proteins. These properties of p37mos are different from those of other characterized retroviral transforming proteins.     

Detection of a transforming gene product in cells transformed by Moloney murine sarcoma virus

We identified, in cells transformed by Moloney murine sarcoma virus (M-MuSV clone 124), a protein encoded by the M-MuSV transforming gene, v-mos. An antiserum against a synthetic peptide corresponding to the C terminus of a protein predicted from the v-mos nucleotide sequence specifically recognizes a protein doublet of approximately 37,000 daltons from 35S-methionine-labeled M-MuSV 124-transformed producer cells. By peptide mapping, this protein is almost identical to the 37 kd in vitro translation product from the M-MuSV v-mos gene. Immunoprecipitates from 32P-labeled cells contain a single v-mos-specific phosphoprotein, which has at least six sites of phosphorylation containing phosphoserine. Pulse-chase experiments show that the lower band in the 35S-methionine-labeled doublet is the primary translation product, which is modified, probably by phosphorylation, to yield the upper band. A similar mos protein is immunoprecipitated from HT1-MuSV-transformed cells, but not from uninfected NIH/3T3 cells. These mos proteins are present at very low levels in transformed cell lines. Cells acutely infected with M-MuSV 124, however, transiently contain much higher levels of the mos protein. These high levels coincide with extensive cell mortality.     

KT5720 and U-98017 inhibit MAPK and alter the cytoskeleton and cell morphology

We previously identified KT5720 and U-98017 as agents that had paclitaxel (taxol)-like activity in a Chinese hamster ovary (CHO) paclitaxel-dependent cell screen for paclitaxel mimetics. In vitro polymerization of purified brain tubulin is not affected substantially by these compounds, suggesting that, unlike paclitaxel, these agents do not directly affect tubulin. However, these compounds cause profound rearrangements of the cytoskeleton in intact cells, including an apparent alteration of microtubule length, overlapping of cells, and an increase in cell size. We show that KT5720 and U-98017 effectively inhibit mitogen-activated protein kinase (MAPK) activity in vitro. Staurosporine, a poor inhibitor of MAPK but a potent inhibitor of cAMP-dependent protein kinase A (PKA) activity, phospholipid/Ca⁺⁺-dependent kinase (PKC), and cdc2, does not cause similar changes. In addition, paclitaxel-dependent cells grown in U-98017 have substantially decreased levels of stimulated MAPK. In correlation with these results, we have confirmed the presence of MAPK in isolated tubulin and microtubules in cells. We have examined the hypothesis that these compounds are working through inhibition of MAPK to alter microtubules by inhibiting the phosphorylation of microtubule-associated proteins. A MAPKK dominant negative mutation transfected in CHO cells inhibits activation of MAPK. Transfectants carrying this dominant mutant have impaired activation of MAPK and an altered cell morphology, similar in some respects to that seen with KT5720 and U-98017. These results support a role for MAPK family members in the control of microtubule dynamics and suggest that in intact cells U-98017 and KT5720 achieve their effects of altering cytoskeleton and supporting partial growth of paclitaxel-dependent cells through inhibition of kinases such as MAPK. J. Cell. Physiol. 176:525–536, 1998. © 1998 Wiley-Liss, Inc.     

Inhibition of mos-induced oocyte maturation by protein kinase A

The relationship between the mos protooncogene protein and cAMP- dependent protein kinase (PKA) during the maturation of Xenopus oocytes was investigated. Microinjection of the PKA catalytic subunit (PKAc) into Xenopus oocytes inhibited oocyte maturation induced by the mos product but did not markedly affect the autophosphorylation activity of injected mos protein. By contrast, PKAc did not inhibit maturation promoting factor (MPF) activation or germinal vesicle breakdown (GVBD) that was initiated by injecting crude MPF preparations. In addition, inhibiting endogenous PKA activity by microinjecting the PKA regulatory subunit (PKAr) induced oocyte maturation that was dependent upon the presence of the endogenous mos product. Moreover, PKAr potentiated mos protein-induced MPF activation in the absence of progesterone and protein synthesis. These data are consistent with the hypothesis that progesterone-induced release from G2/M is regulated via PKAc and that PKAc negatively regulates a downstream target that is positively regulated by mos.     

Dose-dependent regulation of macrophage differentiation by mos mRNA in a human monocytic cell line.

The proto-oncogene c-mos was expressed during differentiation of the human monocytic cell line U937 into macrophages. To investigate a possible role of the mos oncogene, we introduced the v-mos gene under an inducible promoter, MT-I, into U937 cells. The v-mos transformed cells expressed mos mRNA at an amount proportional to the concentration of Zn2+ ions. The induction of the v-mos gene caused growth inhibition and macrophage differentiation in these cells. The differentiation of v-mos transformed monocytes into macrophages required continuous expression of the v-mos gene. The extent of expression of phenotypic characteristics of macrophages, such as phagocytosis, cell surface antigens and typical morphology, depends on the amount of mos mRNA present. We were therefore able to demonstrate that the expression of only one oncogene, mos, determines monocyte differentiation into macrophages.     

Biologically active mutants with deletions in the v-mos oncogene assayed with retroviral vectors.

We have constructed retroviral expression vectors by manipulation of the Moloney murine leukemia virus genome such that an exogenous DNA sequence may be inserted and subsequently expressed when introduced into mammalian cells. A series of N-terminal deletions of the v-mos oncogene was constructed and assayed for biological activity with these retroviral expression vectors. The results of the deletion analysis demonstrate that the region of p37mos coding region upstream of the third methionine codon is dispensable with respect to transformation. However, deletion mutants of v-mos which allow initiation of translation at the fourth methionine codon have lost the biological activity of the parental v-mos gene. Furthermore, experiments were also carried out to define the C-terminal limit of the active region of p37mos by the construction of premature termination mutants by the insertion of a termination oligonucleotide. Insertion of the oligonucleotide just 69 base pairs upstream from the wild-type termination site abolished the focus-forming ability of v-mos. Thus, we have shown the N-terminal limit of the active region of p37mos to be between the third and fourth methionines, while the C-terminal limit is within the last 23 amino acids of the protein.     

Use of the mouse mammary tumor virus long terminal repeat to promote steroid-inducible expression of v-mos.

We used the mouse mammary tumor virus long terminal repeat to promote dexamethasone-regulated expression of the Moloney murine sarcoma virus (M-MSV) transforming gene, v-mos. A recombinant DNA vector containing the mouse mammary tumor virus long terminal repeat fused to the M-MSV 124 v-mos gene was cotransfected with a plasmid containing the herpes simplex virus thymidine kinase gene (tk) into 3T3TK- cells. Individual clones of cells which grew in hypoxanthine-aminopterin-thymidine medium were tested for dexamethasone-regulated expression of p37mos as well as several transformation-specific phenotypic parameters. In the absence of dexamethasone, the v-mos transfectants appeared morphologically similar to the control cells despite low basal levels of p37mos expression. Upon hormone treatment, the levels of p37mos increased 5- to 10-fold, coincident with morphological changes typical of M-MSV transformation of 3T3 cells. The ability to form foci in monolayers also correlated with p37mos induction. The extent of morphological changes varied in individual clones of cells with similar levels of induced p37mos. Although the induced levels of p37mos were comparable to those seen in stable M-MSV 124 virus-transformed NIH 3T3 cells, the transfectants were unable to grow in soft agar under conditions which support growth of the virus-transformed cells. Acute infection of the transfectants with M-MSV 124 virus, a situation which resulted in elevated levels of p37mos, allowed these cells to grow in soft agar. The results described in this paper suggest that different threshold levels of p37mos may be necessary for the expression of various parameters of the transformed phenotype and also that continued expression of p37mos is necessary for maintenance of the transformed state. However, it also appears that the sensitivity to given levels of p37mos varies among clonal cell lines.     

The cystic fibrosis transmembrane regulator is present and functional in endosomes. Role as a determinant of endosomal pH.

Cystic fibrosis is caused by mutations in the gene encoding the cystic fibrosis transmembrane conductance regulator (CFTR), which lead to defective Cl- conductance in epithelial cells. While the CFTR gene product has been detected in the plasma membrane, its presence and functional role in the membranes of intracellular compartments remain to be established. The purpose of the present experiments was to functionally localize CFTR in the endosomal membrane and to test the role of the associated Cl- conductance in the regulation of endosomal pH (pH(en)). When using conductive protonophores, the net H+ flux across the endosomal membrane of Chinese hamster ovary (CHO) cells is limited by the movement of counterions. Thus, ionic permeability could be estimated indirectly, from the changes in pH(en) determined fluorimetrically. Measurements in situ and in a cell-free microsomal preparation indicate the presence of a protein kinase A (PKA)-activated anion conductance in endosomes from CHO cells transfected with CFTR, but not in endosomes from wild-type or mock-transfected cells. In endosomes isolated from CFTR-expressing cells, the stimulatory effect of PKA was diminished by a specific peptide inhibitor of PKA, by alkaline phosphatase treatment or by a monoclonal antibody against the second nucleotide binding fold of CFTR. Increasing counterion permeability by phosphorylation of CFTR or by addition of valinomycin failed to alter the rate or extent of endosomal acidification in situ. Our observations indicate that functional CFTR, susceptible to activation by PKA, is present in endosomes of transfected CHO cells. More importantly, the data suggest that factors other than counterion permeability are the major determinants of pH(en).     

Absence of DNA ligase IV protein in XR-1 cells: evidence for stabilization by XRCC4

XR-1 is a CHO mutant cell line defective in double strand break repair and V(D)J recombination. These defects are due to a deletion of the XRCC4 gene which encodes a 38-kDa nuclear phosphoprotein. Recent studies have shown that XRCC4 interacts with and enhances the activity of DNA ligase IV in vitro. In this study we investigate the effect of the absence of XRCC4 on the level of DNA ligase IV in XR-1 cells. Western blot analysis indicates that levels of DNA ligase IV protein are almost undetectable in these cells, however, introduction of the XRCC4 cDNA into XR-1 resulted in a return to wild type levels of the protein. Furthermore, analysis of DNA ligase IV mRNA showed equivalent levels in both XR-1 and XRCC4 transfected XR-1 indicating that the altered level of DNA ligase IV is not due to a change in the expression of the gene. These data strongly suggest that an important function of XRCC4 is to stabilize the DNA ligase IV protein.     

Expression and characterization of calmodulin-dependent protein kinase II from cloned cDNAs in Chinese hamster ovary cells

cDNAs containing the entire coding regions of the alpha and beta subunits of calmodulin-dependent protein kinase II (CaM kinase II) were isolated from a rat cerebrum cDNA library, ligated into an expression vector under the control of SV40 early promoter and introduced into Chinese hamster ovary (CHO) cells. To investigate the role of the alpha and beta subunits and their functional domains in CaM kinase II activity, the properties of the kinases expressed in the transfected cells were studied. CaM kinase II activity was detected in the transfected cells when the alpha and beta cDNAs were introduced into CHO cells simultaneously. RNA transfer blot and protein immunoblot analyses demonstrated the expression of the mRNAs and proteins of both alpha and beta subunits in the cloned cells. When alpha or beta cDNA was introduced into CHO cells separately, a significant level of the enzyme activity was also expressed, indicating that the alpha and beta subunits exhibited enzyme activity individually. The apparent Km values for ATP and MAP 2 were almost the same for the alpha subunit, beta subunit, alpha beta complex, and brain CaM kinase II. However, there was a slight difference in the affinity for calmodulin between the expressed proteins. The alpha and beta subunits expressed in the same cells polymerized to form alpha beta complex of a size similar to that of brain CaM kinase II. The alpha subunit also polymerized to form an oligomer, which showed almost the same S value as that of alpha beta complex and brain CaM kinase II. In contrast, the beta subunit did not polymerize. The alpha subunit, beta subunit, alpha beta complex, and brain CaM kinase II were autophosphorylated with [gamma-32P]ATP in the presence of Ca2+ and calmodulin, which resulted in the appearance of Ca2+-independent activity. The Ca2+-independent activity was 60-75% of the total activity as measured in the presence of Ca2+ plus calmodulin. To examine the functional relationship of peptide domains of the subunits of CaM kinase II, deleted cDNAs were introduced into CHO cells and the properties of the expressed proteins were studied. In cells transfected with alpha or beta cDNA from which the association domain was deleted, a significant level of kinase activity was expressed. However, the expressed proteins showed hardly any autophosphorylation and the appearance of Ca2+-independent enzyme activity was very low, indicating that the association domain was essential for the autophosphorylation and for the appearance of the Ca2+-independent activity.     

Analysis of Rotavirus Nonstructural Protein NSP5 Phosphorylation

The rotavirus nonstructural phosphoprotein NSP5 is encoded by a gene in RNA segment 11. Immunofluorescence analysis of fixed cells showed that NSP5 polypeptides remained confined to viroplasms even at a late stage when provirions migrated from these structures. When NSP5 was expressed in COS-7 cells in the absence of other viral proteins, it was uniformly distributed in the cytoplasm. Under these conditions, the 26-kDa polypeptide predominated. In the presence of the protein phosphatase inhibitor okadaic acid, the highly phosphorylated 28- and 32- to 35-kDa polypeptides were formed. Also, the fully phosphorylated protein had a homogeneous cytoplasmic distribution in transfected cells. In rotavirus SA11-infected cells, NSP5 synthesis was detectable at 2 h postinfection. However, the newly formed 26-kDa NSP5 was not converted to the 28- to 35-kDa forms until approximately 2 h later. Also, the protein kinase activity of isolated NSP5 was not detectable until the 28- and 30- to 35-kDa NSP5 forms had been formed. NSP5 immunoprecipitated from extracts of transfected COS-7 cells was active in autophosphorylation in vitro, demonstrating that other viral proteins were not required for this function. Treatment of NSP5-expressing cells with staurosporine, a broad-range protein kinase inhibitor, had only a limited negative effect on the phosphorylation of the viral polypeptide. Staurosporine did not inhibit autophosphorylation of NSP5 in vitro. Together, the data support the idea that NSP5 has an autophosphorylation activity that is positively regulated by addition of phosphate residues at some positions.