Expression, purification, and characterization of an activated cytokine-suppressive anti-inflammatory drug-binding protein 2 (CSBP2) kinase from baculovirus-infected insect cells.

An activated form of the human cytokine-suppressive anti-inflammatory drug-binding protein 2 (CSBP2) kinase was expressed in Spodoptera frugiperda (SF9) cells from a baculovirus vector. To maximize expression and to facilitate purification of the recombinant protein, CSBP2 kinase was expressed as a carboxy-terminal fusion protein to glutathione S-transferase (GST). Under optimal conditions, 2-3 mg of GST-CSBP2 could be obtained per liter of infected cell culture. The fusion protein was easily purified from the soluble fraction of the total cell lysate under nondenaturing conditions by using a glutathione-Sepharose 4B affinity resin. As expected, the purified GST-CSBP2 fusion protein was approximately 68 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and reacted with antibodies directed toward either the GST or the CSBP amino terminus. To obtain activated CSBP2, SF9 cells were coinfected with two recombinant baculovirus vectors: one that directed the synthesis of the GST-CSBP2 fusion protein and a second vector that directed the synthesis of a constitutively active form of the CSBP activating kinase, MKK3. Coexpression of GST-CSBP2 kinase with the MKK3 activator increased GST-CSBP2 activity 8- to 10-fold based on the ability of GST-CSBP2 to phosphorylate the substrate, myelin basic protein (MBP), and the ATF2 transcription factor, in vitro. Moreover, activated GST-CSBP2 was capable of activating a bacterially derived mitogen-activated protein kinase-activating protein kinase 2 in vitro. The activity of insect-derived GST-CSBP2 was also inhibited by the CSBP inhibitor, SB202190. We anticipate that the preparation and purification techniques described in this study will facilitate further biochemical characterization of this kinase.

Purification of ADAM 10 from bovine spleen as a TNFalpha convertase.

We have purified a protease with characteristics of TNFalpha convertase from bovine spleen membranes. Peptide sequencing of the purified protein identified it as ADAM 10 (Genbank accession no. Z21961). This metalloprotease cleaves a recombinant proTNFalpha substrate to mature TNFalpha, and can cleave a synthetic peptide substrate to yield the mature TNFalpha amino terminus in vitro. The enzyme is sensitive to a hydroxamate inhibitor of MMPs, but insensitive to phosphoramidon. In addition, cloned ADAM 10 mediates proTNFalpha processing in a processing-incompetent cell line.

Expression and purification of two recombinant sterol-carrier proteins: SCPX and SCP2.

We report the cloning, expression, and purification of the rat sterol carrier proteins SCPX and SCP2. The cDNA's encoding rat SCPX and SCP2 were isolated from a lambda gt11 rat liver cDNA library. To maximize expression and to facilitate the purification of the recombinant proteins, the SCPX and SCP2 proteins were expressed as carboxy-terminal fusion proteins to the glutathione S-transferase (GST). The GST-SCPX and GST-SCP2 fusion proteins contained a thrombin recognition site between the GST and SCPX or SCP2 polypeptides. The expression of the fusion proteins was controlled by the inducible tac promoter. Under optimal conditions, the approximately 85-kDa GST-SCPX and the approximately 41-kDa GST-SCP2 proteins represented approximately 1-2% of the total cell lysate. Both fusion proteins were easily purified under nondenaturing conditions from the soluble fraction of total cell lysate by glutathione-Sepharose 4B affinity chromatography. Thrombin cleavage resulted in the release of the SCPX and SCP2 proteins from the GST-SCPX and GST-SCP2 fusions, respectively. Amino terminal protein sequencing confirmed the authenticity of the recombinant proteins. Furthermore, functional assay revealed that recombinant SCP2 is highly active in facilitating the conversion of 7-dehydrocholesterol to cholesterol. Recombinant SCPX is also active in this assay but only 50% as active as SCP2. We anticipate that the preparation and purification techniques described in this study will facilitate further biochemical characterization of these proteins.

Isolation and purification of a biologically active human platelet-derived growth factor BB expressed in Escherichia coli.

Human platelet-derived growth factor (PDGF) was expressed in Escherichia coli from a high-level cytoplasmic expression vector. A cDNA fragment encoding the mature form of the human PDGF B chain (hPDGF-B) was cloned into a plasmid under transcriptional control of the inducible E. coli Tac promoter. Expression of hPDGF-B from the final construct, pTacBIq, is regulated by the lactose repressor (LacIq). Upon induction, a polypeptide of approximately 14 kDa that had the same molecular mass and immunoreactivity as authentic hPDGF-B was produced. The production of recombinant hPDGF-B was significantly increased in an E. coli strain (CAG629) defective in expression of the lon protease. Expression of hPDGF-B in the CAG629 strain accounted for approximately 1% of total cell protein. In this system, hPDGF-B is expressed as an insoluble, intracellular protein and can readily be obtained in a partially purified form after differential centrifugation. Amino acid sequence determination of the purified protein has verified that the amino-terminal portion of the recombinant PDGF is correct. After renaturation into dimers, the purified recombinant hPDGF is fully functional in assays for receptor binding and mitogenesis.

Expression of the adenovirus E1B 175R protein and its association with membranes of Escherichia coli.

The E1B 175-amino-acid (175R) protein of adenovirus 2 is required for cellular transformation of primary cells and establishing cell morphology in lytically infected cells. To investigate the biochemical function of this protein, we constructed a bacterial expression vector (pKHB1-T) to produce the 175R protein in sufficient amounts for purification and biochemical analysis. On the basis of DNA sequencing, gel electrophoresis, and immunoblot analysis, the pKHB1-T-encoded 175R protein appears to be identical to that expressed transiently in mammalian or adenovirus-transformed cells. The bacterially produced viral protein was also found to be quite stable and without any modifications. Partial purification of the pKHB1-T-encoded protein revealed that the majority of its associates with the inner membrane of the bacterial cell. This, together with the possibility of the 175R protein containing an N-terminal amphipathic alpha-helix as a potential translocation signal, suggests that there may be a common mechanism of protein transport operating in both eucaryotic and procaryotic systems.

The adenovirus E1A 243R protein purified from Escherichia coli under nondenaturing conditions is found in association with dnaK.

The adenovirus E1A 243R protein immortalizes primary cells in culture and induces part of the phenotypes required for transformation. It has also been shown to interact with a number of cellular polypeptides, including the product of the retinoblastoma gene. To understand more fully the molecular activities of the E1A 243R protein in association with these proteins as well as its role in the processes of cellular growth, we have developed a method for rapidly purifying this protein from genetically engineered Escherichia coli under nondenaturing conditions. The plasmid-encoded E1A protein, when expressed in a protease-deficient mutant, is found to have the same length and amino acid sequence as that which is produced in a mammalian cell. The procedure for purifying the E1A 243R protein from bacteria relies primarily upon immunoaffinity chromatography and the use of a peptide comprising the epitope recognized by an E1A-specific antibody. Elution of the E1A protein under this condition allows for gentle isolation and a purity that ranges from 90 to 96%. However, without the addition of micromolar amounts of ATP prior to its elution from the antibody column, the E1A protein is found in association with an E. coli protein of 70 kDa. Immunoblot analysis with a specific antibody showed that this bacterial protein was the heat shock protein dnaK, which is known to have extensive homology with the hsp-hsc70 family of proteins in mammalian cells. Recognition of E1A by the dnaK protein may very well reflect a situation that also occurs between the mammalian heat shock proteins and the E1A 243R protein after adenovirus infection.

Hsp70 proteins, similar to Escherichia coli DnaK, in chloroplasts and mitochondria of Euglena gracilis.

The heat-shock response of Euglena gracilis was studied by pulse-labeling cells with [35S]sulfate at both the normal growth temperature (21 degrees C) and an elevated temperature (36 degrees C). Analysis of the labeled proteins by polyacrylamide gel electrophoresis indicated that the rate of synthesis of at least 3 major and 15 minor polypeptides increased in cells grown at the higher temperature. Three of the proteins appear to be immunologically related to the ubiquitous approximately 70-kDa heat-shock protein (Hsp70) family. One protein of 68 kDa was found in the cytoplasm (P68cyt) and was the major heat-shock protein in Euglena gracilis. Two other proteins, 68 and 70 kDa, were localized in mitochondria (P68mit) and chloroplasts (P70chl), respectively, and they crossreacted with a polyclonal antibody raised against the Escherichia coli heat-shock protein DnaK. Like DnaK, P68mit and P70chl could be phosphorylated in vitro with [gamma-32P]ATP in a reaction that was stimulated by Ca2+. A protein with characteristics similar to those of P70chl was also found in chloroplasts isolated from maize and spinach.

Interaction of DnaK with ATP: binding, hydrolysis and Ca+2-stimulated autophosphorylation.

The autophosphorylation of DnaK from Escherichia coli using ATP as phosphate donor is markedly stimulated by Ca+2 and to a lesser degree by Mn+2. Mg+2 and other divalent ions are without effect in this reaction. Lanthanum, an agonist/antagonist of Ca+2, is also effective in stimulating the autophosphorylation. In contrast, Mg+2 but not Ca+2, markedly stimulates the hydrolysis of ATP catalyzed by DnaK. Also at 0 degrees, ATP forms a stable complex with DnaK without hydrolysis that is independent of cations. About 15% of the DnaK in E. coli is associated with membrane vesicles where it also can be phosphorylated in the presence of Ca+2.

A member of the Hsp70 family is localized in mitochondria and resembles Escherichia coli DnaK.

A 71-kDa protein (P71) with properties similar to those of the Escherichia coli heat shock protein DnaK has been found in extracts of HeLa cells. P71 was copurified by ATP-agarose affinity chromatography with three additional proteins of the Hsp70 family. Of these proteins, only P71 crossreacted strongly with antiserum raised against purified DnaK, and both DnaK and P71 could be phosphorylated in vitro with [gamma-32]ATP in a reaction that was markedly stimulated by Ca2+. In HeLa cells, P71 was found to be concentrated in mitochondria. A protein similar to P71 was also found in calf liver and yeast mitochondria.

Antibody to sigma 32 cross-reacts with DnaK: association of DnaK protein with Escherichia coli RNA polymerase.

A polyclonal antibody to sigma 32, the heat shock sigma factor, has been used to show the presence of low levels of sigma 32 in Escherichia coli RNA polymerase preparations (E sigma 70), which explains the observed in vitro activity of E sigma 70 towards heat shock genes. The sigma 32 antibody cross-reacts with DnaK, and DnaK has been found associated with purified preparations of both E sigma 70 and the heat shock RNA polymerase, E sigma 32.

Purification and biological characterization of an adenovirus type 2 E1A protein expressed in Escherichia coli.

The adenovirus 2 E1A gene encodes a multifunctional protein of 289 amino acids that can immortalize primary rodent cells and transcriptionally activate a number of viral and cellular genes. To facilitate an understanding of the molecular basis for the various actions of E1A, we have redesigned our bacterial expression vector (Ko, J.-L., and Harter, M. L. (1984) Mol. Cell. Biol. 4, 1427-1439) containing the cloned E1A gene such that a soluble authentic E1A protein now constitutes approximately 1.5% of the total Escherichia coli cellular protein. Further, we have developed a simple rapid purification scheme without the use of detergents or denaturants and show a purity of greater than 98% with a yield of approximately 53%. The E1A so purified is biologically active, stimulating cellular DNA synthesis following microinjection into quiescent NIH 3T3 and REF52 cells. In another report (Spangler, R., Bruner, M., Dalie, B., and Harter, M. L. (1987) Science 237, 1044-1046) we have also shown that our purified E1A protein activates transcription from appropriate promoters in an in vitro system.

Activation of adenovirus promoters by the adenovirus E1A protein in cell-free extracts.

The primary product of the adenovirus E1A gene is a protein that is sufficient for controlling host-cell proliferation and immortalizing primary rodent cells. The mechanism by which the protein induces these cellular effects is poorly understood, but might be linked to its ability to regulate RNA transcription from a number of viral and cellular genes. The mechanism of E1A's transcriptional-activation (trans-activation) was studied here by monitoring the protein's effect on specific adenovirus promoters in two types of transcriptional systems in vitro. One of these systems consisted of extracts from transformed cells constitutively expressing E1A, and the other consisted of extracts of HeLa cells supplemented with a plasmid-encoded E1A protein purified from Escherichia coli. The results show that the E1A protein specifically stimulates transcription from adenovirus promoters; thus, the induction of cellular transcription factors is not necessary to explain the stimulation of transcription by E1A.

Adenovirus-2 early region IA protein synthesized in Escherichia coli extracts indirectly associates with DNA.

The interaction of adenovirus-2 (Ad2) early region IA (EIA) protein (encoded by the 13S mRNA) with DNA was examined using EIA protein synthesized in Escherichia coli extracts directed by a plasmid containing the cloned EIA gene. Without any purification, this protein when chromatographed over calf thymus DNA immobilized on cellulose, showed at least two types of salt-sensitive activities after associating with equal efficiency to both single- and double-stranded DNA; however, a putative C-terminal proteolytic fragment of the EIA protein (identified by immunoprecipitation with anti-serum specific to the EIA carboxy-terminus) showed 10-fold greater affinity to double- versus single-stranded DNA. When examined with Ad2 DNA, the EIA protein had a retention that was at least 2-fold higher compared to calf thymus DNA, suggesting some substrate specificity. It was also found that a 1.0 M salt concentration was required for the elution of the EIA protein from pBR322 DNA containing cloned regulatory sequences of adenovirus early regions II and III. This suggests that the strength of the protein interaction depends on the target DNA sequence. Finally, addition of uninfected HeLa cell extract to bacterial extracts containing EIA-like protein potentiated the association of the protein to double-stranded calf thymus DNA up to 7-fold. These data support the hypothesis that the EIA protein interacts with target DNA, presumably mediated by co-factor(s) in an indirect fashion.