Abelson murine leukemia virus-induced tumors elicit antibodies against a host cell protein, P50

Protein kinase activities in immune complexes of simian virus 40 large T-antigen and transformation-associated cellular p53 protein

Immune complex kinase assays in the simian virus 40 system were performed by incubation of immunoprecipitates containing tumor antigens with [gamma-32P]ATP, followed by analysis of any phosphoacceptor proteins. These assays yielded mainly the viral large T-antigen and, in particular, the associated cellular p53 as endogenous substrates. The nature of these substrates was confirmed by proteolysis techniques. Under specific conditions, casein could be used as an exogenous substrate as well. The kinase reactions showed preference for ATP and MgCl2 instead of GTP or MnCl2. Both phosphoserine and phosphothreonine, but in no case phosphotyrosine, were detected after an immune complex kinase reaction. Apparently, several in vivo phosphorylation sites were recognized in vitro in both large T-antigen and p53, but the presence of some artifactual sites could not be completely excluded. Although contaminating kinases were detectable in the immune complexes, at least the p53 molecules were phosphorylated in vitro in a more specific way. This followed from several characteristics of the immune complex kinase reactions and especially from the strong inhibition of p53 phosphorylation by two anti-large-T monoclonal antibodies. It was shown that large T-antigen showed associated kinase activity, although none of our results could unambiguously demonstrate an intrinsic kinase activity of this protein. Finally, anti-p53 monoclonal antibodies only slightly affected in vitro phosphorylation reactions, whereas a p53 molecule from a simian virus 40-free, chemically transformed human cell line was not phosphorylated in vitro under any condition tested. Thus, it is highly unlikely that the p53 molecule per se carries intrinsic or even associated kinase activities.

Chromosomal assignment of the murine gene encoding the transformation-related protein p53

p53 is a transformation-related protein that is encoded by the cellular genome and is synthesized at elevated levels in a wide range of different cell line types and in primary tumors of various species. By using several independently established anti-p53 monoclonal antibodies, it was possible to distinguish between p53 of mouse origin and p53 of Chinese hamster origin. By analysis of a series of mouse X Chinese hamster hybrid cell lines containing various mouse chromosomes, we mapped the p53 gene product to mouse chromosome 11.

Growth regulation of a cellular tumour antigen, p53, in nontransformed cells

Many transformed cells in culture have been found to express elevated levels of a cellular tumour antigen, termed p53. This protein has also been implicated in the regulation of cellular growth. For these reasons experiments were designed to examine the expression of p53 as quiescent cultures of nontransformed 3T3 fibroblasts were stimulated to reenter the cell cycle. Synchronous populations of cells were obtained by releasing a culture from density-dependent inhibition of growth with the addition of fresh serum. Steady-state levels of p53 protein and mRNA were measured as a function of time after addition of serum to quiescent cultures and the rate of synthesis of p53 protein was analysed at a number of time points. The results, reported here, demonstrate an increase in the synthesis and steady-state levels of p53 protein and mRNA prior to DNA synthesis in late G1, and suggest a role for p53 in the progression of cells from a growth-arrested state to an actively dividing state.

Abelson murine leukemia virus-transformed cells that lack p53 protein synthesis express aberrant p53 mRNA species

Cells of the Abelson murine leukemia virus-transformed line L12 that lack the p53 protein also lack polyadenylated mRNA capable of directing the synthesis of p53 in a cell-free system. Direct analysis of stable polyadenylated mRNA from a variety of cell lines shows that all p53 producers shared a common mRNA species (2.0 kilobases) which hybridized with a p53-specific cDNA probe. This species, which appears to be the mature, normal-sized p53 mRNA, was totally undetectable in L12 cells, which did not produce p53 in vivo. However, L12 cells contained two major p53-specific mRNA species of a substantially larger size (3.5 and 6.5 kilobases) than the p53-specific mRNA in the p53-producing cells. Genomic DNA analysis uncovered an apparent alteration in the 5' proximal part of only one p53 gene, which is unique to the L12 cell line. It is thus possible that the nonproducer phenotype of L12 cells is due at least in part to an alteration within a p53-specific DNA sequence. These findings define a system in which production of p53 appears to be efficiently regulated at the level of stable mRNA and which can be used to study the mechanisms controlling p53 expression in Abelson murine leukemia virus-transformed cells.

Large-T-antigen-p53 complex formation is not cold sensitive in a cold-sensitive transformant induced by simian virus 40 mutant tsA1499

F111 rat cells transformed by simian virus 40 mutant tsA1499 are cold sensitive for the expression of transformation. Yet, unlike F111 cells transformed by tsA58, they do not lose the ability to stabilize the transformation-associated host cell protein p53 at the temperature at which transformation is extinguished.

Chromosomal assignment of the murine gene encoding the transformation-related protein p53

p53 is a transformation-related protein that is encoded by the cellular genome and is synthesized at elevated levels in a wide range of different cell line types and in primary tumors of various species. By using several independently established anti-p53 monoclonal antibodies, it was possible to distinguish between p53 of mouse origin and p53 of Chinese hamster origin. By analysis of a series of mouse X Chinese hamster hybrid cell lines containing various mouse chromosomes, we mapped the p53 gene product to mouse chromosome 11.

Protein kinase activities in immune complexes of simian virus 40 large T-antigen and transformation-associated cellular p53 protein

Immune complex kinase assays in the simian virus 40 system were performed by incubation of immunoprecipitates containing tumor antigens with [gamma-32P]ATP, followed by analysis of any phosphoacceptor proteins. These assays yielded mainly the viral large T-antigen and, in particular, the associated cellular p53 as endogenous substrates. The nature of these substrates was confirmed by proteolysis techniques. Under specific conditions, casein could be used as an exogenous substrate as well. The kinase reactions showed preference for ATP and MgCl2 instead of GTP or MnCl2. Both phosphoserine and phosphothreonine, but in no case phosphotyrosine, were detected after an immune complex kinase reaction. Apparently, several in vivo phosphorylation sites were recognized in vitro in both large T-antigen and p53, but the presence of some artifactual sites could not be completely excluded. Although contaminating kinases were detectable in the immune complexes, at least the p53 molecules were phosphorylated in vitro in a more specific way. This followed from several characteristics of the immune complex kinase reactions and especially from the strong inhibition of p53 phosphorylation by two anti-large-T monoclonal antibodies. It was shown that large T-antigen showed associated kinase activity, although none of our results could unambiguously demonstrate an intrinsic kinase activity of this protein. Finally, anti-p53 monoclonal antibodies only slightly affected in vitro phosphorylation reactions, whereas a p53 molecule from a simian virus 40-free, chemically transformed human cell line was not phosphorylated in vitro under any condition tested. Thus, it is highly unlikely that the p53 molecule per se carries intrinsic or even associated kinase activities.

Sodium butyrate inhibits the synthesis of the transformation related protein p 53 in 3T6 mouse fibroblasts

Sodium butyrate, which blocks the cell cycle of many cell types in the G1 phase, strongly inhibits the synthesis of the transformation related, 53 kDa protein in 3T6 fibroblasts but much less so in SV 40 transformed mouse cells. By several criteria, this effect of the fatty acid appears to be indirect; p 53 synthesis takes place several hours after the butyrate-sensitive step in G1. The results are discussed in the light of a putative role of p 53 in growth control.

A single gene and a pseudogene for the cellular tumour antigen p53

The cellular tumour antigen p53 is a protein found in elevated levels in a great variety of transformed cells (reviewed in ref. 1). Overproduction of p53 was observed in cells transformed by a wide spectrum of agents as well as in embryonal carcinoma cells, and in spontaneous transformants. Although initially described in mice, similar p53-like proteins were also observed in cells of other species, including those derived from several human tumours. In non-transformed cells the protein turns over very rapidly and its levels appear to correlate with cell proliferation. Thus far, very little has been known about the precise nature of the protein and of the corresponding genes. We now provide evidence for the existence of a single functional gene for murine p53 and a processed pseudogene. The predicted amino acid sequence of murine p53 is also presented.

Immunoaffinity chromatography of a cellular tumor antigen from mouse neuroblastoma cells

The cellular tumor antigen p53 was isolated from mouse neuroblastoma cells and was found in a form not complexed to another protein. The p53 in these cells was stable, turning over about every 10 h. Its methionine-labelled tryptic peptides were very similar to those of the p53 isolated from SV40-transformed mouse cells. The labelled protein was purified from neuroblastoma cells by immunoaffinity using specific monoclonal antibodies and was about 80% radiochemically pure. Furthermore, the purified p53 sedimented in sucrose gradients with a sedimentation coefficient of approximately 8S. This correlated with the sedimentation coefficient of p53 prior to purification, showing that the purified protein retained its native size.

Pre-crisis mouse cells show strain-specific covariation in the amount of 54-kilodalton phosphoprotein and in susceptibility to transformation by simian virus 40

We have used several inbred mouse strains to examine the role of the 54-kilodalton (kDa) cellular phosphoprotein in transformation by the papovavirus simian virus 40. We have measured the endogenous 54-kDa phosphoprotein in cells obtained from these inbred mouse strains. To study the effect of passage, cell cultures were measured for amount of the 54-kDa phosphoprotein at the 2nd and 12th passages. In the absence of any transforming agent, the amount of endogenous 54-kDa phosphoprotein in early pre-crisis mouse cells varied in a strain-specific way. Transformation frequency varied coordinately with endogenous 54-kDa expression. Mouse strains whose cells produced a high level of endogenous 54-kDa phosphoprotein on passage did not further increase its expression after simian virus 40 transformation.

Stoichiometry of large T antigen and pp53 in complexes isolated from simian virus 40-transformed rat cells

Simian virus 40-transformed cells synthesize high-molecular-weight protein complexes (22 to 30S) that consist of the virus-coded large T antigen (81,500 daltons) and the cellular antigen pp53. These complexes were partially purified from lysates of transformed rat cells by sucrose velocity sedimentation. The stoichiometry of the two proteins in the complex was studied by direct enzyme-linked immunosorbent assays, using alkaline phosphatase-conjugated anti-T and anti-pp53 monoclonal antibodies. The results from these experiments indicate that the T antigen-to-pp53 ratio in the complex is 0.87 +/- 0.27. No statistically significant differences were found in this ratio for faster- and slower-sedimenting complexes. These results from enzyme-linked immunosorbent assays and previous molecular weight estimates of the complex suggest that this complex is composed, on the average, of four molecules of T antigen and four or five molecules of pp53.

p53, a transformation-related cellular-encoded protein, can be used as a biochemical marker for the detection of primary mouse tumor cells

p53, a transformation-related cellular-encoded protein, was found to accumulate at high concentration in transformed cell lines. The results presented here show that p53 biosynthesis is also increased in most induced and spontaneous mouse tumors. Judged by the identity in antigenic determinants (estimated by binding to monoclonal antibodies), size, and partial peptide mapping, I conclude that the p53 molecule found in primary tumors is indistinguishable from that in established cell lines. The fact that p53 is found in heterogeneous populations of primary tumors makes it a convenient biochemical diagnostic marker for the detection of primary tumors in mice. It is found in primary tumors as a phosphoprotein, just as it was found previously in established cell lines. On the other hand, the p53 found at low concentration in normal thymocytes is labeled with [35S]methionine but cannot be found in its phosphorylated form.

The presence of p53 transformation-related protein in Ab-MuLV transformed cells is required for their development into lethal tumors in mice

p53, a cellular-encoded protein, is synthesized at elevated levels in a wide range of tumor cells. Ab-MuLV-transformed cells expressing both the viral-encoded p120 oncogene and the cellular-encoded p53 display a lethal tumor phenotype in syngeneic mice. L12 is an exceptional Ab-MuLV-transformed cell line that expresses the p120 oncogene and lacks the p53 cellular protein. Injection of L12 cells into syngeneic mice is followed by the development of local tumors that are subsequently rejected. Prolonged treatment of L12 cells with TPA, a tumor cell promoter, gave rise to L12T cells that synthesize the p53 protein and exhibit a lethal tumor phenotype. Comparison of one-dimensional proteolytic partial peptide map of p53 obtained from L12T to that obtained from other Ab-MuLV-transformed cell lines confirmed their identity. These results suggest a correlation between the cellular expression of p53 in Ab-MuLV-transformed cells and their capacity to develop into lethal tumors in syngeneic mice.

Antibodies of predetermined specificity for the NH2 terminus of a cellular protein p53 react with the native molecule: evidence for the presence of different p53s

Two synthetic peptides corresponding to residues 1-20 and 10-20, respectively, of one type of a cellular protein called "p53" have been linked to a carrier protein and injected into rabbits to raise antibodies. The antibodies obtained were capable of reacting with the native protein, as judged by an enzyme-linked immunosorbent assay, protein A-linked staining of immunoblots after NaDodSO4 gel electrophoresis, and immunoprecipitation. The immunoassay titers against the protein were lower for these antibodies than for antisera derived from immunization with purified p53. However, staining with the immunoblot method showed that the antipeptide antibodies against p53 were uniquely specific. The data suggest that at least two different types of p53 molecules occur. The cellular protein previously isolated from human cells transformed by Epstein-Barr virus and from murine tumors induced by methylcholanthrene appears to be larger than the p53 reported in relation to simian virus 40- or adenovirus-transformed cells and to some other tumors. Some interrelationships have not been excluded, but it is clear that the two protein molecules do not behave identically. The reactions of the antipeptide antibodies with the intact protein have implications in regard to protein conformations. The strict specificities of such antibodies allow the generation of distinct sets of reagents useful for quantitation, purification, and cloning.

Identification and purification of Namalwa nuclear RNP antigen 52/5.3

Using affinity purified rabbit antibodies to HeLa nucleoli and the Western blotting techniques, an antigen with an approximate molecular weight of 52,000 and pI of 5.3 was found in Namalwa cells (a Burkitt lymphoma), but not in normal liver cells. This antigen was purified from Namalwa RNP by column chromatography on Sephacryl S-200, hydroxylapatite and one-dimensional SDS gel electrophoresis. A liver protein with the same molecular weight and pI value was purified from RNP fraction by one-dimensional SDS gel electrophoresis. Both proteins had similar amino-acid compositions. The tryptic map of 125I-labeled protein 52/5.3 contained approximately nine major spots; spot 9 was present in the Namalwa protein but not in the liver protein. The similarity of the structures of these proteins and their differences in antigenicity are noteworthy and require further structural and functional analysis.

Molecular cloning of a cDNA specific for the murine p53 cellular tumor antigen

A cDNA library was constructed from sucrose-gradient-fractionated mRNA from SVT2, a mouse cell line transformed by simian virus 40. Polysomes containing the p53 messenger were specifically immunoprecipitated with monoclonal antibodies against the protein and used to prepare mRNA. This immunoselected mRNA, enriched 1,000-to 2,000-fold for p53-specific sequences, was used to make a cDNA probe and to screen the cDNA library. When approximately 10,000 colonies were screened by differential hybridization with probes made from immunoselected vs. nonenriched mRNA, a single clone was found that contained p53-specific sequences. The identity of this clone, termed pp53-208, was confirmed by the ability of its DNA to hybridize the mRNA coding for p53 (hybrid selection assay). When hybridized to a blot of EcoRI digested mouse DNA, the pp53-208 insert reacted with a single 3.3-kilobase band, suggesting that it is complementary to a single gene.

P53 transformation-related protein accumulates in the nucleus of transformed fibroblasts in association with the chromatin and is found in the cytoplasm of non-transformed fibroblasts

The subcellular localization of the p53 molecule was studied in transformed and non-transformed fibroblasts. A newly established transformed cell line obtained by treating primary embryonic mouse cells in vitro with the chemical carcinogen methylcholanthrene was compared with the embryonic parent fibroblasts. The transformed cells lost the spindle shape characteristic of the parent fibroblasts, acquired an accelerated growth rate, developed into tumors when injected into syngeneic mice and expressed high levels of p53 synthesis estimated by immunoprecipitation of [35S]methionine-labeled cell extracts. The cellular localization of the p53 molecule was studied by immunofluorescent staining of fixed cells with monoclonal antibodies and by immunoprecipitation of [35S]-methionine-labeled p53 from various subcellular fractions. p53 was mainly found in the nucleus of the transformed fibroblast, while in the parent non-transformed primary embryonic cells, p53 was detected in the cytoplasm in a Triton X-100 soluble fraction, and associated with the cytoskeleton. The modulated distribution of p53 was also confirmed by analyzing a wide range of independently established transformed and non-transformed fibroblastic cell lines growing in vitro. The switch from the cytoplasmic localization of p53 in the non-transformed fibroblasts to a chromatin-associated accumulation in the transformed cells suggests a possible mechanism by which this protein may function in the transformed fibroblasts.

Surface antigen expression and immunoglobulin gene rearrangement during mouse pre-B cell development

The first part of this article discusses the isolation and characterization of several monoclonal antibodies to the B lineage-specific surface molecule, B220. B220 was shown to be expressed on precursors of B cells by the demonstration that removal of B220+ cells from B cell-depleted bone marrow removes the ability of bone marrow to regenerate B cells. Although these antibodies recognize a broad range of differentiation stages within the B lineage, they can be used to isolate highly enriched populations of pre-B cells from mouse bone marrow. We also describe the use of antibodies to the surface markers B220 and ThB to define two sequential stages of pre-B cell differentiation. A simplified diagram of our current view of the B lineage differentiation sequence is shown in Figure 4. No attempt has been made to include the various functionally defined B cell subsets on this diagram since we know almost nothing about the expression of these two surface markers on them. This model reflects an assumption that the early part of B cell differentiation is a linear rather than a branching pathway. At present, there is no evidence for a branching pathway, but little evidence against it either. B220 is the first B cell-specific molecule known to be expressed during differentiation and it continues to be expressed on most subsequent B lineage cells. In this regard, it resembles the Thy-1 molecule on thymus-derived lymphocytes and, like Thy-1, B220 should be quite useful for identifying and classifying B lineage cells. One example of this is the use of B220 expression to clearly assign germinal center cells to the B lineage. The example of Thy-1+, RA3-2C2+ cells from mice with the lpr/lpr genotype, however, suggests that some caution should be used when interpreting data, especially with pathological samples. The availability of substantially purified pre-B cell populations has made it possible to follow changes in immunoglobulin gene organization and expression during differentiation. Our current understanding of these events is also shown in Figure 4, correlated with cell surface phenotype. The large pre-B cell population has extensive heavy chain rearrangements and synthesizes significant quantities of mu heavy chain, but does not yet have detectable light chain gene rearrangement. The small pre-B population consists of two cell types, some with kappa gene rearrangement and some without. This suggests that kappa rearrangement occurs within this cell population, which is homogeneous with respect to morphology and surface phenotype. The asynchrony of heavy and light chain gene rearrangement results in an asynchrony at the level of expression of these genes as well, but the purpose of this remains one of many unanswered questions about pre-B cell differentiation. Now that it is possible to identify, isolate, and manipulate pre-B cells as readily as B or T cells, many of these questions may now be addressed.

Microinjection of monoclonal antibody to protein p53 inhibits serum-induced DNA synthesis in 3T3 cells

Monoclonal antibody directed against the transformation-related protein p53 was microinjected manually into the nuclei of quiescent Swiss 3T3 mouse cells. The cells were subsequently stimulated with 10% fetal calf serum. Microinjection of p53 antibody at or around the time of serum stimulation clearly inhibited the subsequent entry of Swiss 3T3 cells into the S phase of the cell cycle. p53 antibody had no effect on serum-stimulated DNA synthesis when it was microinjected 4 hr or later after serum stimulation. Monoclonal antibody to an unrelated antigen, Lyt-2.2, had no effect on serum-stimulated DNA synthesis regardless of the time it was microinjected. Under similar experimental conditions, p53 antibody had no effect on simian virus 40- or adenovirus 2-induced DNA synthesis. These experiments add strength to the suggestion that p53 is involved in the regulation of cell proliferation.

Loss of viral gene expression and retention of tumorigenicity by Abelson lymphoma cells

Lymphomas induced by the Abelson murine leukemia virus (A-MuLV) were examined for the expression of biochemical and biological markers associated with A-MuLV transformation before and after in vivo growth in genetically distinguishable host mice. Although all tumors and clonal lines derived from them initially expressed the A-MuLV-encoded gag fusion protein p160, they ceased synthesis of this molecule after several weeks of growth in vivo as ascites tumors. Transplanted clonal lines continued to express the alloantigenic marker H-2b and the isoenzyme marker Gpi-1b of the donor tumor cells, indicating that the cells were of donor and not host origin. Examination of cellular DNA obtained from p160-positive and derivative p160-negative lines indicated that p160-negative clones had lost A-MuLV-specific proviral sequences as detected by hybridization with several probes. Although the clonal lines no longer expressed p160, they retained their malignant phenotype and continued to express the Abelson antigen, a cell surface marker associated with A-MuLV lymphomagenesis. Continued expression of the A-MuLV genome was not required for maintenance of oncogenic potential under these conditions of in vivo tumor growth.

Reactivity with patient antibodies of partially purified gp40 antigen from immune complexes in Burkitt's lymphoma and nasopharyngeal carcinoma

A glycoprotein antigen (gp40) was previously identified as a major component of immune complexes isolated from sera of patients with Burkitt's lymphoma (BL) and nasopharyngeal carcinoma (NPC). In the present work gp40 was partially purified from a pool of BL/NPC sera. Sera of patients with BL and NPC as well as sera of patients with other malignant and non-malignant diseases were tested for antibodies against gp40, using a double antibody radioimmunoassay. Practically all normal sera and sera of patients with non-malignant diseases had antibodies capable of binding radioiodinated gp40. In contrast, sera of patients with BL or NPC had very low binding, while sera of patients with other malignant diseases had intermediate binding values. The low binding activity of BL/NPC sera was shown to be due to inhibition by excess gp40 present in such sera. Effusions of patients with breast or ovarian cancer also contained demonstrable amounts of gp40. The origin of gp40 is still unknown.

A 53-kilodalton protein common to chemically and virally transformed cells shows extensive sequence similarities between species

A heat-stable DNA-binding protein with subunits of about 53 kilodaltons (kDal) was purified from two virally transformed human cell lines (Epstein-Barr virus-positive Raji and Namalwa) and two mouse tumor cell lines (methylcholanthrene-induced Meth A sarcoma and TA3 mammary carcinoma). All four 53kDal proteins showed closely related total amino acid compositions, similar peptide maps, and identical NH2-terminal amino acid sequences for 20 residues. These 53-kDal proteins are therefore evolutionarily highly conserved, independent of whether they originate from virally or chemically transformed cells. The NH2-terminal sequence and the protein chain as a whole are not hydrophobic; however, some unexpected residue distributions were observed. Comparisons with other proteins reveal no clear sequence similarity with known tumor antigen structures, homologous immunoglobulins, or some other proteins of known sequence. Epstein-Barr virus-determined nuclear antigen also appears to have a different NH2-terminal sequence. Thus, the results show that the 53-kDal proteins represent a unique protein type with little species variation; this finding suggests that these proteins must perform an important common function in different transformation systems.

Radioimmunoassay of the cellular protein p53 in mouse and human cell lines

We have developed quantitative radioimmunological solid phase assays for the host protein p53 from mouse cells and from human cells. The first assay, for mouse p53, depends on having two monoclonal antibodies reacting with different determinants on the p53 molecule. With this assay we have shown that SV40-transformed cells have approximately 100-fold more p53 than untransformed mouse cells and that other transformed cells have intermediate levels. Embryonal carcinoma cell lines have approximately 50-fold less p53 than SV40-transformed cells. This is in contrast to the high levels of incorporation of [35S]methionine into p53 in these cells and indicates that metabolic labelling is not a valid approach for measuring p53 levels. The second assay, for human p53, required a different approach and made use of the anti-p53 antibodies detected in the sera of some breast cancer patients. Human tumour cell lines contained amounts of p53 varying from the high level seen in SV40-transformed human fibroblasts down to less than one hundredth of this amount. Normal human cells showed low levels of p53. The data confirm that many, but not all, human tumour cell lines contain more p53 than normal cells.

Phosphorylation patterns of tumour antigens in cells lytically infected or transformed by simian virus 40

The phosphorylation sites of simian virus 40 (SV40) large tumor (T) antigens have been analyzed by partial proteolysis peptide mapping and phosphoamino acid analysis of the resulting products. At least four sites were found to be phosphorylated. An amino-terminal part of the molecule contained both phosphoserine and phosphothreonine. One phosphothreonine residue was located in the proline-rich carboxy-terminal end of the molecule, either at position 701 or at position 708. The mutant dl 1265, which is defective in adenovirus helper function, lacked this phosphorylation site. In addition, the carboxy-terminal part of the molecule contained phosphoserine at a more central position. T-antigen-associated proteins of SV40-transformed cell (nonviral T; 51,000 to 55,000 daltons) also contained multiple phosphorylation sites involving at least two serine residues in mouse antigens and an additional threonine residue in rat, human, and monkey antigens. The latter residue and at least one phosphoserine residue were located near one terminus of the human NVT molecule. We did not find any evidence for phosphorylation of tyrosine residues in any of the multiple species of either large T or nonviral T molecules. Several forms of large T antigens were extracted from both SV40-transformed and SV40-infected permissive and nonpermissive cells, and their phosphorylation patterns were compared. No evidence was found for a different phosphorylation pattern of T antigen in transformed cells.

p53 transformation-related protein: detection of an associated phosphotransferase activity

Malignant cells of the mouse transformed by a variety of different agents have been found to express high levels of a 53,000 Mr phosphoprotein (designated p53). Little or no p53 can be detected in normal mouse cells. The nucleus appears to be the predominant site of p53 localization in transformed cells. p53-related antigens are also found in transformed cells of rat, hamster, rabbit, and human. In cells transformed by simian virus 40 (SV40), p53 forms a complex with SV40 tumor (t) antigen, resulting in the coprecipitation of T antigen by monoclonal p53 antibodies. Immune complexes of p53 precipitated from extracts of SV40- or methylcholanthrene-transformed cells by monoclonal p53 antibodies have protein kinase activity. This enzymatic activity is dependent upon divalent cations, utilizing Mn2+ more effectively than Mg2+. The phosphorylation of p53 in this kinase reaction has been found to involve serine and threonine, but not tyrosine residues. In view of the finding that the transforming proteins of several different oncogenic viruses have kinase activity, the association of this activity with p53 is important with regard to the possibility of a common pathway of transformation by diverse agents.

Increased concentration of an apparently identical cellular protein in cells transformed by either Abelson murine leukemia virus or other transforming agents

Abelson murine leukemia virus (A-MuLV)-transformed cells, simian virus 40 (SV40)-transformed cells, and chemically transformed cells all have increased levels of a 50,000-molecular-weight host cell protein. The protein was detected with sera raised to the A-MuLV-transformed and chemically transformed cells and was tightly bound to T-antigen in extracts of SV40-transformed cells. Partial protease digests showed that the proteins from all three sources were indistinguishable. The three proteins were phosphorylated in cells, and the linkage of phosphate to the A-MuLV-associated P50 was to a serine residue. By immunofluorescence methods, P50-related protein was found on the surface of both normal lymphoid cells and A-MuLV-transformed lymphoid cells, but cell fractionation showed that the majority of P50 was free in the cytoplasm of the transformed cells. Immunofluorescence also showed that P50 was found in granules in the cytoplasm of both untransformed and SV40-transformed fibroblasts. Other cells gave indistinct patterns. Cocapping experiments showed that the A-MuLV-specified P120 protein is weakly associated with the surface P50-related protein of lymphoid cells, but no association of P120 and P50 could be demonstrated by immunoprecipitation methods. Although a monoclonal antiserum to P50 was used in many of these studies, the identity of the bulk P50 protein with the molecules that are reactive at the cell surface requires further study.

p53 transformation-related protein: detection by monoclonal antibody in mouse and human cells

A transformation-related protein of M(r) 53,000, designated p53, has been detected in a range of neoplastic cell types of the mouse by using immunoprecipitation of [(35)S]-methionine-labeled cell extracts with mouse antiserum [DeLeo, A. B., Jay, G., Appella, E., DuBois, G. C., Law, L. W. & Old, L. J. (1979) Proc. Natl. Acad. Sci. USA 76, 2420-2424]. We have now prepared a monoclonal antibody to p53 and have used it to study the occurrence and intracellular location of p53 by indirect immunofluorescence assays. In accordance with the results of immunoprecipitation, these tests showed p53 in all 13 transformed mouse cell lines studied. In each case, p53 was found in the nucleus. No p53 was detected in normal mouse fibroblasts, 3T3 cells, bone marrow cells, thymus cells, or embryo cells. A serologically related protein was detected in the nucleus of human cells by monoclonal antibody and was found in both normal and neoplastic cultured cells. Expression of p53 in human cells correlates with the growth characteristics of the culture, high p53 levels being associated with rapid cell proliferation and low p53 levels, with cessation of cell division. Normal and malignant human cells differ, however, with regard to the effect of confluency on p53 expression. Normal kidney epithelium and fetal brain cells, which express high p53 levels during exponential growth, show a prompt decrease in p53 associated with contact inhibition of cell division. Malignant cells, on the other hand, continue to express p53 after confluency and subsequent overgrowth of the monolayers. These results suggest that p53 may be involved in the normal regulation of cell division and that malignant transformation leads to abnormalities in the control of p53 expression.

B220: a B cell-specific member of th T200 glycoprotein family

T200, a major cell-surface glycoprotein on lymphoid cells, exists in several forms with different electrophoretic mobilities. These forms have been correlated with different classes of lymphoid cell. The smaller forms, with molecular weights (MWs) of congruent to 170,000 and 180,000 are found predominantly on T cells while the 220,000 MW form is associated with B cells. The polypeptide portions of each molecule may be identical or closely related as all three forms share the same allelic variations, and all reported herologous antisera and monoclonal antibodies to T200 precipitate all three forms. We report here a monoclonal antibody specific for the 220,000 MW form of T200 and show that it is expressed only on B cells and a subset of bone marrow cells which includes B cell precursors. We suggest that this form of the molecule be designated provisionally B220.

A monoclonal antibody that recognizes B cells and B cell precursors in mice

The monoclonal antibody, RA3-2C2, appears to be specific for cells within the B cell lineage. This antibody does not recognize thymocytes, peripheral T cells, or nonlymphoid hematopoietic cells in the spleen or bone marrow. Nor does it recognize the pluripotent hematopoietic stem cells, the spleen colony-forming unit, All sIg+ B cells and most plasma cells are RA3-2C2+. In addition, approximately 20% of nucleated bone marrow cells are RA3-2C2+ but sIg-. This population contains B cell precursors that can give rise to sIg+ cells within 2 d in vitro.