Expression using vectors with phage lambda regulatory sequences.

In the expression system described here, plasmids (pSKF) utilize regulatory signals--such as the powerful promoter pL--from the bacteriophage lambda. Transcription from pL can be fully repressed and plasmids containing it are thus stabilized by the lambda repressor, cI. The repressor is supplied by an E. coli host which contains a integrated copy of a portion of the lambda genome. This so-called defective lysogen supplies the lambda regulatory proteins cI and N but does not provide the lytic components that would normally lead to cell lysis. Thus, cells carrying these plasmids can be grown initially to high density without expression of the cloned gene and subsequently induced to synthesize the product upon inactivation of the repressor. This system also ensures that pL-directed transcription efficiently traverses any gene insert, which is accomplished by providing the phage lambda antitermination function, N, to the cell and by including on the pL transcription unit a site necessary for N utilization (Nut site). The N protein interacts with and modifies the RNA polymerase at the Nut site so as to block transcription termination at distal sites in the transcription unit. In order to express the coding sequence, efficient ribosome-recognition and translation-initiation sites have been engineered into the pL transcription unit. Expression occurs after temperature or chemical induction inactivates the repressor (see first and second basic protocols). Restriction endonuclease sites for insertion of the desired gene have been introduced both upstream and downstream from an ATG initiation codon. Thus, the system allows either direct expression or indirect expression (via protein fusion) of any coding sequence, thereby potentially allowing expression of any gene insert. Protocols describe direct expression of "authentic" gene products, as well as heterologous genes fused to highly expressed gene partners generates chimeric proteins that differ from the native form. In the latter case, the fusion partner can be removed to obtain an unfused version of the gene product.

Production of monoclonal antibodies in COS and CHO cells.

Recent advances in the generation of genetically engineered monoclonal antibodies have enhanced the importance of COS cells as expression systems for rapidly producing sufficient quantities of these proteins for preliminary biochemical and biophysical analysis. In order to meet the demand for clinical supplies, a gradual increase has occurred in the usage of dihydrofolate reductase negative (DHFR-) Chinese hamster ovary (CHO) cells for large-scale antibody production. Using a variety of mammalian expression vectors and selection/amplification protocols, CHO cell lines capable of producing monoclonal antibodies at levels exceeding 1 gl-1 can now be obtained in an almost routine fashion. For the applications of monoclonal antibodies to expand into additional therapeutic areas, however, a 5-10-fold increase over current highest expression levels may still need to be achieved.

Candida albicans ALS1: domains related to a Saccharomyces cerevisiae sexual agglutinin separated by a repeating motif.

Transfer of budding Candida albicans yeast cells from the rich, complex medium YEPD to the defined tissue culture medium RPMI 1640 (RPMI) at 37 degrees C and 5% CO2 causes rapid onset of hyphal induction. Among the genes induced under these conditions are hyphal-specific genes as well as genes expressed in response to changes in temperature, CO2 and specific media components. A cDNA library constructed from cells incubated for 20 min in RPMI was differentially screened with yeast (YEPD)- and hyphal (RPMI)-specific probes resulting in identification of a gene expressed in response to culture conditions but not regulated by the yeast-hyphal transition. The deduced gene product displays significant identity to Saccharomyces cerevisiae alpha-agglutinin, encoded by AG alpha 1, an adhesion glycoprotein that mediates mating of haploid cells. The presence of this gene in C. albicans is curious since the organism has not been observed to undergo meiosis. We designate the C. albicans gene ALS1 (for agglutinin-like sequence). While the N- and C-termini of the predicted 1260-amino-acid ALS1 protein resemble those of the 650-amino-acid AG alpha 1, ALS1 contains a central domain of tandem repeats consisting of a highly conserved 36-amino-acid sequence not present in AG alpha 1. These repeats are also present on the nucleotide level as a highly conserved 108 bp motif. Southern and Northern blot analyses indicate a family of C. albicans genes that contain the tandem repeat motif; at least one gene in addition to ALS1 is expressed under conditions similar to those for ALS1 expression. Genomic Southern blots from several C. albicans isolates indicate that the number of copies of the tandem repeat element in ALS1 differs across strains and, in some cases, between ALS1 alleles in the same strain, suggesting a strain-dependent variability in ALS1 protein size. Potential roles for the ALS1 protein are discussed.

A Candida albicans cyclic nucleotide phosphodiesterase: cloning and expression in Saccharomyces cerevisiae and biochemical characterization of the recombinant enzyme.

We have cloned a Candida albicans gene, which encodes a cyclic nucleotide phosphodiesterase (PDEase), by complementation in a Saccharomyces cerevisiae PDEase-deficient mutant. The deduced amino acid sequence is similar to that of the low-affinity PDEase of S. cerevisiae (PDE1) and the cyclic nucleotide PDEase (PD) of Dictyostelium discoideum. Biochemical analysis of recombinant protein produced in S. cerevisiae indicated that the enzyme behaves as a PDE1 homologue: it hydrolyses both cAMP (Km = 0.49 mM) and cGMP (Km = 0.25 mM), does not require divalent cations for maximal activity and is only moderately inhibited by millimolar concentrations of standard PDEase inhibitors. Based on these data, we designate the C. albicans we have cloned, PDE1. Low-stringency genomic Southern blots showed cross-hybridization between C. albicans PDE1 and DNA from Candida stellatoidea, but not with DNA from S. cerevisiae or several closely related Candida species.

High-level production of biologically active human cytosolic phospholipase A2 in baculovirus-infected insect cells.

Infection of Spodoptera frugiperda insect cells with a recombinant baculovirus expressing human cytosolic phospholipase A2 (cPLA2) resulted in the production of biologically active protein. The level of recombinant human cPLA2 production in infected insect cells was at least 50-fold higher than that observed in human monoblast U937 cells.

The pAS vector system and its application to heterologous gene expression in Escherichia coli.

There are numerous proteins of biological interest which cannot be obtained from natural sources in quantities sufficient for detailed biochemical and physical analysis. The limited bioavailability of these molecules has made it impossible to consider their potential utilization as either pharmacological agents and/or targets. One solution to this problem has been the development of recombinant vector systems which are designed to achieve efficient expression of cloned genes in a variety of biological systems. This paper will describe the development and application of a particular set of vectors which have been designed to achieve efficient expression of essentially any gene coding sequence in Escherichia coli. The system utilizes efficient phage-derived transcriptional and translational regulatory signals and provides a strong regulatable promoter, an antitermination mechanism to ensure efficient transcription across any gene insert, high stability and, when appropriate, efficient translation initiation information. In addition, a wide variety of host strains have been developed in order to help control, stabilize and maximize expression of various cloned genes. The system has now been used to express efficiently more than 75 different prokaryotic and eukaryotic gene products. The application of this system to the expression and characterization of several oncogene products will be described.

Expression and characterization of the human c-myc DNA-binding protein.

In an effort to study in detail the nature of the protein product of the human protooncogene c-myc, we have expressed the gene at high levels in Escherichia coli. The c-myc coding region was taken from a full-length cDNA clone and inserted into a vector designed to express foreign gene products efficiently in E. coli. Pulse-labeling experiments indicated that the rate of expression of c-myc in this thermoinducible expression system is very efficient. The product was relatively stable and accumulated to approximately 10% of total cellular protein. A purification protocol was devised which allowed the c-myc protein to be readily purified in quantities sufficient for detailed biochemical and physical analyses. A high-titer polyclonal antiserum was raised against the pure protein and shown to immunoprecipitate the p110gag-myc fusion protein of MC-29-infected quail cells. This antiserum also selectively detects a protein with an apparent molecular weight of 64,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis from a Burkitt lymphoma cell line. We conclude that this 64-kilodalton protein is the human c-myc gene product since the E. coli-made protein exhibits an equivalent molecular weight on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, even though its calculated molecular weight is 49,000. Furthermore, we demonstrate that the bacterially made human c-myc protein is a DNA-binding protein and that it exhibits a high nonspecific affinity for double-stranded DNA.

Improved genetically modified Escherichia coli strain for prescreening antineoplastic agents.

Clinical experience suggests that drugs that interact with and damage DNA are useful in cancer chemotherapy (H. Umezawa , p. 43-72, in V. T. DeVita , Jr., and H. Busch [ed.], Methods in Cancer Research; Cancer Drug Development, vol. XVI, 1979). Prescreening systems for antitumor agents in natural products require assays that are exquisitely sensitive, since the active components are often produced in quantities of micrograms per milliliter or less. One assay used to identify agents that interact with DNA is the biochemical induction assay, utilizing Escherichia coli BR 513 (R. K. Elespuru and R. J. White, Cancer Res. 43:2819-2830, 1983). In this paper we describe a genetic modification of strain BR 513 that displays an expanded spectrum of activity. This strain may provide an improved prescreen for detecting natural products that interact with DNA.

Efficient expression of influenza virus NS1 nonstructural proteins in Escherichia coli.

RNA segment 8 of the influenza A virus genome codes for two nonstructural proteins, NS1 and NS2, for which the functions are unknown. Cloned cDNA copies of this gene from three different influenza A virus strains were inserted into an Escherichia coli plasmid expression vector, pAS1, carrying the strong regulatable lambda phage promoter, PL. After induction, the NS1 proteins were overproduced to levels of 20-25% of total cellular protein. This was surprising in that the codon composition for these eukaryotic genes is similar to that for weakly expressed proteins in E. coli. Thus, under the appropriate conditions, it appears that high level expression of genes containing a relatively large proportion of minor codons can be obtained. The NS1 protein produced in bacteria from a cloned cDNA copy of the A/PR/8/34 virus NS gene was purified to apparent homogeneity and used to generate a high-titer monospecific rabbit antiserum. Immunoprecipitation studies showed this antibody to be crossreactive against the NS1 proteins produced by several different influenza A virus strains. Immunofluorescence experiments in Madin-Darby canine kidney cells showed the NS1 proteins to be located in the nucleoplasm early in infection for all strains examined. With some of the strains, NS1-specific immunofluorescence was observed predominantly in the nucleoli later in infection. This technology can be used to obtain other viral proteins in pure form for structural, functional, and immunological studies.

The proline-, glycine-, glutamic acid-rich pink-violet staining proteins in human parotid saliva are phosphoproteins.

The major proteins in human parotid saliva, isolated in Fractions II-V following chromatography on Sephacryl S-200, DEAE-Sephadex A-50, or CM cellulose, contain 6 moles of phosphate per mole of protein, the phosphate probably bound to the protein via an ester linkage. This phosphate represents greater than 90% of the protein-bound phosphate in human parotid saliva. Neither purified gustin nor amylase, the two other major proteins in human parotid saliva, contain phosphate.

Gustin concentration changes relative to salivary zinc and taste in humans.

Biochemical characteristics of gustin, the major zinc protein in human parotid saliva, are similar whether the protein is isolated from subjects with normal taste acuity or from patients with hypogeusia (who may have a little as 1/5th as much parotid saliva gustin as normal subjects do). Zinc concentration in fraction II of parotid saliva, the fraction in which gustin is found on Sephadex G-150 or Sephacryl S-200 column chromatography, is proportional to the gustin content of saliva and is decreased in patients with lower than normal total parotid saliva zinc. The quantity and spectrophotometric indices of all other protein fractions isolated from patients by these column chromatographic techniques did not differ from those of normals. One patient with proven hypogeusia and low concentrations of zinc in total parotid saliva and fraction II, after 9 days of treatment with exogenous zinc, showed a 150% increase in fraction II zinc and a concomitant increase in apparent gustin levels; these changes preceded the return of normal taste function. These data demonstrate that zinc treatment can affect both taste and gustin concentrations in hypogeusia.

Metal-binding characteristics of the parotid salivary protein gustin.

Metal binding characteristics of the parotid salivary protein gustin have been examined. When purified to apparent homogeneity, gustin contains 1 gatom Zn/mol which is tightly bound (Kd at pH 7.2, 4.5--10(-11) M). This tightly bound zinc can be removed with strong chelators such as diethyldithiocarbamic acid and 1,10-o-phenanthroline at pH 4.5, but not with EDTA or Chelex 100. Removal of the metal ion causes no appreciable conformational change in the protein. The apoprotein can be reconstituted by dialysis against Zn2+-containing buffer, a process favored by pH greater than 6.0. Only cobalt is able to bind to the apoprotein at this strong binding site. Cobalt binding is appreciably weaker than that of zinc (Kd at pH 7.2, 1.3--10(-7) M) and is maximal at pH 7.0. The weaker binding of cobalt is also illustrated by the loss of 37% of bound cobalt after 96 h of dialysis at pH 7.2, conditions under which the zinc content of gustin does not change. A second gatom Zn/mol may be loosely bound to gustin, but is easily removed by dialysis against metal ion-free buffer. Other metal ions such as copper, nickel, iron or manganese, but not cadmium or mercury, bind loosely to this second zinc site and are removed with ease. Zinc appears to be involved in the formation of the complex between gustin and glycoproteins which are present in human parotid saliva in vivo.

Biosynthesis and cellular distribution of the two superoxide dismutases of Dactylium dendroides.

The synthesis and subcellular localization of the two superoxide dismutases of Dactylium dendroides were studied in relation to changes in copper and manganese availability. Cultures grew normally at all medium copper concentrations used (10 nM to 1 mM). In the presence of high (10 muM) copper, manganese was poorly absorbed in comparison to the other metals in the medium. However, cells grown at 10 nM copper exhibited a 3.5-fold increase in manganese content, while the concentration of the other metals remained constant. Cultures grown at 10 nM copper or more had 80% Cu/Zn enzyme and 20% mangani enzyme; the former was entirely in the cytosol, and the latter was mitochondrial. Removal of copper from the medium resulted in decreased Cu/Zn superoxide dismutase synthesis with a concomitant increase in the mangani enzyme such that total cellular superoxide dismutase activity remained constant. The mangani enzyme in excess of the 20% was present in the non-mitochondrial fraction. The mitochondria, therefore, show no variability with respect to superoxide dismutase content, whereas the soluble fraction varies from 100 to 13% Cu/Zn superoxide dismutase. Copper-starved cells that were synthesizing predominantly mangani superoxide dismutase could be switched over to mostly Cu/Zn superoxide dismutase synthesis by supplementing the medium with copper during growth. Immunoprecipitation experiments suggest that the decrease in Cu/Zn activity at low copper concentration is a result of decreased synthesis of that protein rather than the production of an inactive apoprotein.