An invariant asparagine residue belonging to a highly conserved domain in all protein kinases is instrumental in the protein kinase activity of the v-mil gene product

P100gag-mil, the translation product of the v-mil oncogene of MH2 is a protein kinase specific of serine/threonine residues. We report here that the P100gag-mil encoded by the MH2-Hd isolate displays a considerably reduced kinase activity in vitro. Construction of chimeric viruses and sequencing revealed that the lesion responsible for this reduced activity results from a single point mutation converting an asparagine residue at position 720 in fully active P100gag-mil kinase into serine in the P100gag-mil of MH2-Hd. Since this asparagine residue together with an invariant aspartate residue bracket a highly conserved 6 amino-acid region in all known protein kinases as well as in phosphotransferases of bacterial origin, our results indicate that integrity of this region is essential to enzymatic function and support the notion that it could be directly involved in ATP binding or phosphate transfer from ATP to kinase substrates.

Nuclear and cytoplasmic distribution of cellular myb protein in human haematopoietic cells evidenced by monoclonal antibody

A monoclonal antibody was used for analysing the expression of the cellular myb (c-myb) protein in a variety of established human tumor cell lines and its decrease after induction of differentiation. Differentiated resting human T-cells and B-cells do not express detectable amounts of c-myb protein. However, upon mitogenic stimulation in vitro T-cells exhibit strong expression of the c-myb protein as demonstrated by immunocytochemical staining and indirect immunoprecipitation. In contrast to the transformed T-lymphoblastic cell line Molt-4, where c-myb protein is a nuclear antigen, it was found in proliferating normal T-cells almost exclusively distributed in the cytoplasm. Screening of a total of 70 fresh human malignant lymphomas by immunohistochemical staining indicates the presence of the c-myb protein primarily in non-Hodgkin's lymphomas with a large growth fraction, i.e. precursor cell-derived lymphoblastic lymphomas of B-cell type and T-cell type (9/10, 3/4, respectively) and anaplastic large cell Ki-1 lymphomas (5/9), which originate from activated lymphoid cells. The c-myb protein was located predominantly in the nucleus and in some cases additionally in the cytoplasm. The different subcellular locations suggest a dual functional role. While nuclear localisation is exhibited by transformed haematopoietic cells, cytoplasmic localisation appears to be characteristic for proliferating normal T-cells and points to a second property of the c-myb protein other than interaction with DNA.

Partial purification and substrate analysis of bacterially expressed HIV protease by means of monoclonal antibody

Retroviruses code for a specific protease which is essential for polyprotein precursor processing and viral infectivity. The HIV-specific protease has been predicted to be an aspartic protease which is located at the amino terminus of the pol gene. We have prepared several constructs for bacterial expression of the protease. Two of them span the whole protease region and result in its autocatalytic activation. Analysis of the dynamics of this activation indicates a two-step process which starts at the carboxy terminus and ends at the amino terminus of the protease. The activated protease is a molecule of 9 kd as evidenced by monoclonal antibody in immunoblot analysis. A construct in which the carboxy terminus of the protease is deleted results in a stable, enzymatically inactive 27-kd protein which proved useful as substrate since it contains one of the predicted cleavage sites. The stability of this protein indicates that the carboxy-terminal sequences of the protease are essential for its activity and its autocatalytic activation. The protease which is very hydrophobic was solubilized by acetone treatment and passaged over ultrogel and propylagarose columns for partial purification. It elutes as a dimer and tends to aggregate. It is inhibited by pepstatin A in agreement with its expected active site and its theoretical classification as aspartic protease. Cleavage of the gag precursor results in the mature capsid protein, p17. The protease does not, however, cleave the denatured 27-kd substrate or the denatured gag precursor. Therefore its specificity appears to be not solely sequence- but also conformation-dependent. This property needs to be taken into account for the development of protease inhibitors for therapy of AIDS.

Epidermal growth factor receptor expression in human lung cancer cell lines

Non-small cell lung cancer (NSCLC) and small cell lung cancer (SCLC) cell lines were studied for epidermal growth factor (EGF) receptor expression. All NSCLC cell lines tested (eight of eight) had specific EGF binding sites, whereas only five of 11 SCLC cell lines bound EGF. NSCLC and SCLC cell lines expressed the same type of high affinity EGF binding sites with a Kd of 0.5 to 4.5 nM; however, NSCLC cells bound significantly more EGF than SCLC cell lines. The amount of binding sites in NSCLC cells ranged between 71 and 1,000 fmol/mg of protein and in SCLC cells, between 26 and 143 fmol/mg of protein. The two SCLC cell lines with EGF binding values within the range of NSCLC belonged to the variant subtype of SCLC. By means of an anti-erbB serum and indirect radioimmunoprecipitation, a strong Mr approximately 170,000 protein band could be detected in the NSCLC cell lines. This protein corresponds to the EGF receptor molecule. Its identity was proven by competition with excess erbB antigen for the antibody during the radioimmunoprecipitation. Furthermore, this Mr 170,000 protein exhibited protein kinase activity as evidenced by in vitro autophosphorylation. The radioactivity incorporated into the Mr 170,000 band in radioimmunoprecipitation and protein kinase assays was 10 to 100 times lower in these SCLC cell lines which were positive in the EGF binding assay compared to the NSCLC cell lines. We conclude that NSCLC in contrast to SCLC expresses high levels of EGF receptors which may be used to facilitate the differential diagnosis in some cases of lung cancer. These data suggest that EGF may play a role in growth and differentiation of NSCLC.

Replacement of lys 622 in the ATP binding domain of P100gag-mil abolishes the in vitro autophosphorylation of the protein and the biological properties of the v-mil oncogene of MH2 virus

Lysine 622 in the ATP-binding domain of P100gag-mil, the translation product of the v-mil oncogene of MH2, has been replaced with methionine using oligonucleotide site-directed mutagenesis. This substitution results in the inactivation of the serine/threonine-specific autophosphorylation of P100gag-mil in vitro, indicating that this activity is an intrinsic property of the viral protein. This substitution also suppresses two of the biological properties of MH2 which have previously been shown to be dependant upon the expression of v-mil, namely, the production of chicken myelomonocytic growth factor (cMGF) by v-myc-transformed chicken macrophages and the sustained proliferation of chicken neuroretina cells. These data strongly suggest that the biological properties of v-mil are mediated by the phosphorylation at serine/threonine residues of key cellular substrates. In contrast to the in vitro situation, both the mutant and wild-type proteins appear to be phosphorylated at the same sites and to the same extent in either transformed fibroblasts or macrophages. This, together with the fact that the sites phosphorylated in vivo and in vitro are essentially different indicate that most of the phosphate associated with P100gag-mil in transformed cells does not result from an obligate autophosphorylation event but from the phosphorylation by as yet uncharacterized cellular kinase(s).

Identification and characterization of HIV-specific RNase H by monoclonal antibody

Human immune deficiency virus (HIV) replicates by conversion of the RNA genome into the double-stranded DNA provirus. The reverse transcriptase is not the only enzymatic function crucial in DNA-provirus synthesis. A viral-coded RNase H activity which specifically degrades RNA in RNA-DNA hybrids has been shown to be essential as well. Here we demonstrate that the HIV-reverse transcriptase which consists of a two-polypeptide complex, p66 and p51, copurifies with an RNase H activity which exhibits properties of a processive exonuclease. Only the p66 molecule, not p51, is active as polymerase as evidenced by activated gel analysis. p66 exhibits RNase H activity when precipitated as immune complex by a monoclonal antibody raised against a bacterially expressed carboxy-terminal portion of p66. The monoclonal antibody which does not interfere with enzyme activity also precipitates a second population of molecules with RNase H activity which is of low mol. wt, p15. This RNase H appears therefore to be derived from the carboxy terminus of p66 during processing to the p51 polypeptide. It exhibits low template-binding ability and is of a non-processing mode of action which may be due to the absence of the reverse transcriptase domain. These results lend experimental support to the hypothesis that the RNase H gene maps at the carboxy terminus of the reverse transcriptase. Since both RNase H populations are virus-coded they may be essential for retrovirus replication in general and useful targets for chemotherapeutic agents.

Epidermal growth factor receptor expression, proliferation, and colony stimulating activity production in the urinary bladder carcinoma cell line 5637

Addition of epidermal growth factor (EGF) to cultures of the urinary bladder carcinoma cell line 5637 regulated proliferation and production of colony stimulating activity (CSA). The optimal concentration range of EGF for stimulation of cell proliferation was 5-20 ng/ml EGF and for production of CSA 2-20 ng/ml EGF. High EGF concentrations (100-200 ng/ml) showed inhibitory effects on proliferation and to a greater extent on CSA production. Also, EGF binding sites of high affinity (kd:3.25 nM) were demonstrated on the cell surface. In the optimal concentration range for stimulation (5-20 ng/ml EGF) EGF binding sites were occupied half-maximally. The loss in EGF binding after long incubation at 37 degrees C was prevented by the lysosomal inhibitory agent, chloroquine. Nonspecific binding of EGF was very low, the amount of maximally bound EGF was 1430 fmol/mg protein (130,000 bound EGF molecules/cell). A strong band of approximately 170,000 daltons could be detected by means of an anti-erbB serum which recognizes the EGF receptor protein. The protein became phosphorylated upon addition of gamma-32P ATP. The data suggest that EGF initiates its action by binding to specific high affinity receptors and plays a role in growth regulation and differentiation of the urinary bladder carcinoma cell line 5637.

RNase H activity associated with bacterially expressed reverse transcriptase of human T-cell lymphotropic virus III/lymphadenopathy-associated virus

The reverse transcriptase polymerase of the human T-cell lymphotropic virus/lymphadenopathy-associated virus has been cloned into an expression vector and expressed in Escherichia coli. Two polypeptides of 66 and 51 kDa molecular mass are detectable in polymerase-expressing bacterial lysates with human patient sera. They are processed from a short-lived 120-kDa polyprotein precursor equivalent to a region consisting of polymerase, protease, and endonuclease. The 51 kDa protein appears to originate from the 66-kDa molecule; additional processing products are 32- and 15-kDa proteins. The bacterially expressed polymerase is enzymatically active and exhibits the template specificities, ion requirements, and response to inhibitors of the authentic enzyme. It was purified by DEAE-cellulose-, phosphocellulose-, and poly(rC)-agarose column chromatography followed by glycerol density gradient centrifugation. It copurifies with an RNase H activity, suggesting the existence of a virus-coded DNA polymerase-RNase H complex. The purified bacterial enzyme allows a safe large-scale screening for inhibitors of both activities.

Interaction of the oncogene protein myc with specific DNA fragments

The p110gag-myc protein coded for by the retrovirus MC29 was purified 3,000-fold from MC29-Q8 transformed cells by immuno-affinity chromatography using IgG specific for the N-terminal region of the gag protein. Interaction of the protein with DNA fragments was studied by filter binding assay. DNA fragments were obtained from a MC29 DNA clone by restriction endonuclease treatment. Besides the complete DNA provirus the clone contained flanking cellular sequences into which the provirus had integrated. The DNA fragments which were retained by the p110gag-myc protein were eluted from the filter and analyzed by agarose gel electrophoresis. Preferential binding of a DNA fragment originating from the flanking cellular sequences was detected. The protein did not preferentially bind to the viral LTR promoter/enhancer region as suggested by an autoregulatory model, which can therefore no longer be substantiated.

Isolation and characterization of the human cellular myc gene product

Antibodies against the product of the human cellular myc gene (c-myc) were prepared against a bacterially expressed human c-myc protein by inserting the ClaI/BclI fragment of the human c-myc DNA clone in an expression vector derived from pPLc24. These antibodies cross-react with viral-coded myc (v-myc) proteins from MC29 and OK10 viruses. Furthermore, IgGs specific for synthetic peptides, corresponding to the 12 carboxy-terminal amino acids of the human c-myc gene and 16 internal amino acids, were isolated. By use of the various myc-specific antisera or IgGs, a protein of Mr 64 000 was detected in several human tumor cell lines including Colo320, small cell cancer of the lung (417d), HL60, Raji, and HeLa. This protein is larger than the corresponding v-myc or chicken c-myc proteins from avian virus transformed cells or avian bursa lymphoma cells (RP9), both of which are proteins of Mr 55 000. The human c-myc protein is located in the nucleus of Colo320 cells, exhibits a half-life of about 15 min, and is expressed at significantly lower levels than the viral protein. The human c-myc protein was enriched about 3000-fold from Colo320 cells using c-myc-specific IgG coupled to Sepharose beads. The protein binds to double-stranded DNA in vitro, a reaction that can be inhibited to more than 90% by c-myc specific IgG.

Analysis of a tyrosine-specific protein kinase activity associated with the retroviral erbB oncogene product

The transforming protein erbB of avian erythroblastosis virus (AEV) has considerable sequence homology with the epidermal growth factor (EGF) and appears to represent a truncated form of this receptor. The sequence of the erbB gene is furthermore related to that of other viral transforming genes such as src, fps, yes or abl. The transforming proteins of these src-related oncogenes as well as receptors for EGF, platelet-derived growth factor (PDGF), and insulin are associated with tyrosine-specific protein kinases. It has been difficult to demonstrate this activity for the erbB protein. To analyze the erbB gene product, we prepared polyclonal antibodies against a bacterially expressed erbB DNA restriction fragment (BamHI/BamHI). The antiserum is shown to immunoprecipitate the erbB protein from AEV-transformed chicken fibroblasts and also recognizes the EGF receptor protein. Both proteins become phosphorylated in vitro on tyrosine residues upon the addition of [gamma-32P]ATP. The protein kinase activity is low compared to other oncogene-specific kinases. This is not due to kinase blocking by the serum, because erbB carboxyterminal synthetic peptide antibodies give rise to low levels of protein kinase activity as well indicating that this may be a characteristic property of erbB in vitro.

Isolation of monoclonal antibodies specific for Rous sarcoma virus structural, polymerase and transforming proteins and their use for the study of mutant virus-infected cells

Monoclonal antibodies were developed that are specific for Rous sarcoma virus structural, polymerase (reverse transcriptase) and transforming proteins. The monoclonal antibodies were shown to bind to purified virus proteins in an indirect 125I-labelled Protein A binding assay suitable for screening even very large numbers of hybridomas. Additional tests for specificity included radioimmunoprecipitation of purified virus structural proteins P12 and P27, of reverse transcriptase subunits alpha and beta, and of the transforming protein pp60v-src. Pilot immunofluorescence and protein kinase assays of the expression of virus proteins in avian and mammalian cells infected by wild-type virus as well as by temperature-sensitive, transformation-defective virus mutants revealed that synthesis of virus structural and transforming proteins is hardly affected by changes in temperature, whereas the pp60v-src-associated kinase activity is temperature-sensitive in cells infected by most, but not all the virus mutants.

DNA-binding activity is associated with purified myb proteins from AMV and E26 viruses and is temperature-sensitive for E26 ts mutants

Oncogene protein products from avian myeloblastosis virus, p48v-myb, and from avian leukemia virus E26, p135gag-myb-ets, are located predominantly in the nucleus of nonproducer bone marrow cell clones, as revealed by indirect immunofluorescence. Both oncogene proteins were purified by immunoaffinity chromatography using monoclonal antibodies against p19 and immunoglobulins specific for myb, which was expressed in bacteria for antibody production. The purified proteins bind to DNA in vitro. In contrast, purified p135gag-myb-ets proteins from several mutants of E26 virus, temperature-sensitive for myeloblast transformation, either lost their abilities to bind to DNA or exhibited highly thermolabile DNA-protein interactions in vitro. DNA binding of AMV and E26 oncogene proteins is inhibited by myb-specific immunoglobulins. Our results suggest that lesions in the myb oncogene affect transformation as well as DNA binding of myb proteins in vitro.

Serine- and threonine-specific protein kinase activities of purified gag-mil and gag-raf proteins

Retroviruses carry cell-derived oncogenes (v-onc) that have the potential to transform cells in culture and induce tumours in vivo. One of the few carcinoma-inducing viruses is the acutely transforming retrovirus MH2, which carries the putative oncogene v-mil and the known oncogene v-myc. Recently, a high degree of homology was discovered between v-mil and v-raf, the transforming gene of the murine retrovirus 3611 murine sarcoma virus (MSV), whereas homology to v-src is low. Both viruses express their oncogenes as the gag-fusion polyproteins p100gag-mil and p75gag-raf (of respective relative molecular mass (Mr) 100,000 and 75,000), while the myc oncogene of MH2 is expressed by means of a subgenomic messenger RNA. We have recently demonstrated that p100gag-mil is not a nuclear protein. Here we report that purified p100gag-mil and p75gag-raf exhibit protein kinase activities in vitro which, in contrast to the src-related p130gag-fps of Fujinami sarcoma virus (FSV) and all other characterized oncogene-encoded protein kinases, phosphorylate serine and threonine but not tyrosine. Both types of protein kinases phosphorylate lipids in vitro.

Inhibition of DNA binding of purified p55v-myc in vitro by antibodies against bacterially expressed myc protein and a synthetic peptide

To identify viral myc proteins, we have prepared myc-specific antibodies: (i) against a synthetic peptide corresponding to the nine carboxy-terminal amino acids of the viral myc (C9); (ii) against a bacterially expressed viral myc protein obtained by inserting the SalI-BamHI fragment of the viral MC29 DNA clone in the expression vector pPLc24. Both antisera recognize a protein of 55 000 mol. wt., p55v-myc, in MH2- and OK10-transformed fibroblasts. The protein is located in the nucleus, as shown by indirect immunofluorescence and cell fractionation. Antibodies against the C9 peptide were used to purify the p55v-myc by immunoaffinity column purification (3000-fold) from OK10- and MH2-transformed fibroblasts. p55v-myc binds to double-stranded DNA in vitro as does p110gag-myc. DNA binding in vitro is inhibited by the immunoglobulin fraction of antibodies against the bacterially expressed myc protein. Furthermore, a synthetic peptide consisting of 16 amino acids (C16) was used to isolate specific immunoglobulins which also inhibit DNA binding in vitro. OK10 codes, in addition to p55v-myc, for a p200gag-pol-myc polyprotein. The majority of this protein is located in the cytoplasm (79%). The purified protein binds to single-stranded RNA in vitro, unlike other gag-myc or myc proteins.

The transforming protein of the MC29-related virus CMII is a nuclear DNA-binding protein whereas MH2 codes for a cytoplasmic RNA-DNA binding polyprotein

The acute avian leukemia viruses MH2 and CMII belong to the group of avian myelocytomatosis viruses, the prototype virus of which is MC29. This group of viruses is characterized by myc-specific oncogenes which are presumably expressed as gag-myc polyproteins. These polyproteins are synthesized in non-producer cells transformed by MH2 and CMII and have mol. wts. of 100 000 (p100) and 90 000 (p90), respectively. Monoclonal antibodies against the N terminus of gag, p19, were used to localize the protein in MH2- and CMII-transformed non-producer fibroblasts. Immunofluorescence and cell fractionation indicated that greater than 90% of p100 from MH2 was located in the cytoplasm, whereas greater than 70% of p90 from CMII resided in the nucleus. Isolation of p100 and p90 by immunoaffinity chromatography resulted in an approximately 2000-fold purification of the two polyproteins. Both of them, as well as p110 of MC29, bound to double-stranded DNA of chick fibroblasts in vitro. However, only the MH2-specific polyprotein p100 bound to RNA in vitro. Such a binding was not observed for p90 or p110, or for the purified gag precursor Pr76. Another polyprotein, gag-erbA, from avian erythroblastosis virus, which is also located in the cytoplasm, did not bind to RNA. Our results indicate that the CMII-specific polyprotein p90 behaved indistinguishably from the p110 of MC29. However, the MH2-specific polyprotein p100 exhibited unique and novel properties which were distinct from a gag-myc-type protein.

Decreased DNA-binding ability of purified transformation-specific proteins from deletion mutants of the acute avian leukemia virus MC29

Avian myelocytomatosis virus MC29 is a highly oncogenic replication-defective retrovirus that predominantly affects hematopoietic cells and causes acute leukemia in vivo and that transforms hematopoietic cells as well as fibroblasts in vitro. The transformation-specific sequence, v-myc, is expressed as part of a fusion protein that contains the viral structural protein p19. By use of monoclonal antibodies against p19 we showed that the v-myc-encoded protein is located in the nucleus of MC29-transformed fibroblasts and that after purification over an immunoaffinity column the protein binds to double-stranded DNA. In this report we describe the analysis of the v-myc gene product from MC29-transformed bone marrow cells. The immunoaffinity column-purified protein from these cells also bound to DNA and was indistinguishable from the purified protein from MC29-transformed fibroblasts. In addition, the v-myc gene products from fibroblasts transformed by three nonconditional mutants of MC29--which transform hematopoietic cells with a markedly decreased efficiency in vivo and in vitro but still transform fibroblasts in vitro, expressing deleted v-myc proteins--were analyzed. In contrast to the wild-type protein, the purified mutant proteins had decreased DNA-binding abilities. Furthermore, a preferential binding of the wild-type protein to poly(dG) . poly(dC) duplexes was observed. Such a specificity was lost with a mutant protein. These results provide evidence that the interaction of the v-myc protein with DNA may be directly involved in transformation of the hematopoietic target cells. Further, the transformation-specific fusion proteins purified from cells transformed by avian erythroblastosis virus, which belongs to a different class of acute leukemia viruses, and by Fujinami sarcoma virus were found not to be DNA-binding proteins, suggesting the existence of different transformation mechanisms.

Analysis of two phosphoproteins related to pp60src from Schmidt-Ruppin D virus particles

During endogenous phosphorylation of partially purified pp60src from virus particles, besides pp60src two additional phosphoproteins, 45K and 42K, were found. These proteins copurify with pp60src. They were shown to be proteolytic degradation products due to the action of the virus-associated protease p15. All three phosphoproteins were present in particles of two different sarcoma virus strains, Schmidt-Ruppin D and Prague C, indicating that this phenomenon is general rather than strain-specific. The degradation rate of pp60src was reduced by the presence of 3 mM-ZnCl2, which acts as a protease inhibitor.

DNA-mediated gene transfer in Friend leukemia cells by cotransfection of simian virus 40 DNA with herpes simplex virus thymidine kinase DNA

Thymidine kinase-negative Friend leukemia cells were cotransfected with simian virus 40 (SV40) DNA and thymidine kinase gene DNA of herpes simplex virus type 1. The transfected thymidine kinase-positive cells were selected in HAT medium, and SV40 T-antigen expression was observed over many months in cells cultured under selective conditions, and after adaptation to normal growth medium under nonselective conditions. It was shown by Southern blot hybridization that SV40 DNA was integrated in multiple copies in the chromosomal DNA of several clones. All SV40 DNA-containing Friend leukemia cell clones analyzed were able to undergo induced erythroid differentiation. Induced cultures still expressed SV40 T-antigen to the same extent that untreated control cultures did.