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.

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.

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.