Expression of bovine inhibin beta subunit in Escherichia coli.

1. A DNA fragment encoding the beta subunit of bovine inhibin was amplified using the polymerase chain reaction and was cloned in plasmids pUC8 and pUR291. 2. Cultures of Escherichia coli TG2 harbouring pKDK37, a pUR291-derived recombinant plasmid, produced a novel protein with a molecular weight of 130,000 corresponding to a beta-galactosidase-inhibin beta fusion protein. 3. The fusion protein was purified from inclusion bodies by solubilization in 8 M urea followed by an ion-exchange and gel permeation chromatography. 4. Analysis by immunoblotting and competitive radioimmuno assay revealed that the fusion protein was recognized by a monoclonal antibody raised against a chemically synthesized peptide for amino acid residues from +82 to +114 of the beta subunit of the bovine inhibin thereby confirming its identity.     

Identification of the initiation codon for the atpB gene in Chlamydomonas chloroplasts excludes translation of a precursor form of the beta subunit of the ATP synthase

The chloroplast atpB gene of Chlamydomonas reinhardtii, which encodes the beta subunit of the ATP synthase, contains three in-frame ATGs that are candidate translation initiation codons. An earlier study revealed that the N terminus of the assembled beta subunit maps at the +2 position with respect to the second in-frame methionine codon (Fiedler et al. 1995). Using chloroplast transformation, we have examined the possibility that either of the two additional in-frame ATG codons is competent for translation initiation. We provide evidence that translation of atpB is initiated exclusively at the second ATG codon. We conclude that the beta subunit is not synthesized with an N-terminal leader before its assembly into a functional ATP synthase complex.     

Molecular characterization of two point mutants in the chloroplast atpB gene of the green alga Chlamydomonas reinhardtii defective in assembly of the ATP synthase complex

Two point mutants of Chlamydomonas reinhardtii, previously found by recombination and complementation analysis to map in the chloroplast atpB gene encoding the beta subunit of the CF1/CF0 ATP synthase, are here shown to be missense alterations near the 5' end of that gene. One mutant (ac-u-c-2-9) has a change at amino acid position 47 of the beta subunit from leucine (CTA) to arginine (CGA). In the second mutant (ac-u-c-2-29), the codon AAA (lysine) is changed to AAC (asparagine) at position 154. Spontaneous revertants of each mutant were isolated that restore the original wild type base pair. Northern analysis of total RNA and in vivo pulse labeling followed by immunoprecipitation reveals that both mutant atpB genes are transcribed and translated normally. However, immunoblots show that the amount of beta subunit associated with mutant thylakoids is only approximately 3% of that seen in wild type and that the CF1 alpha and gamma subunits are missing entirely. The disruption of ATP synthase complex assembly in these mutants is much more severe than in Escherichia coli beta subunit gene point mutants, which retain significant amounts of alpha and beta subunits on their membranes (Noumi, T., Oka, N., Kanazawa, H., and Futai, M. (1986) J. Biol. Chem. 261, 7070-7075). These results support the hypothesis that there are differences in assembly of the ATP synthase between E. coli and chloroplasts. In particular they indicate that beta must be present for assembly of the alpha and gamma subunits of CF1 onto chloroplast membranes.     

Synthesis of maize chloroplast ATP-synthase beta-subunit fusion proteins in Escherichia coli and binding to the inner membrane

The maize chloroplast gene for the beta subunit (atpB) of the chloroplast CF1 component of ATPase from maize, when fused to either the lacZ or ral genes in the vectors pMC1403 or pHUB4, is expressed in Escherichia coli as a fusion protein with beta-galactosidase or with bacteriophage lambda Ral sequences. Some of the fusion proteins are converted to a membrane-bound form, as determined by differential and sucrose-gradient centrifugation. The specificity of membrane binding has been examined using E. coli unc mutants that are defective in binding of the F1 ATPase component to the F0 receptor site on the membrane, and by the use of two different length maize atpB::lacZ gene fusions. We show that the first 365 N-terminal amino acids (aa) of the maize beta subunit are involved in binding to the E. coli inner membrane, and that this binding is probably mediated by the bacterial F0 receptor.     

Solubilization and regeneration of Vitreoscilla hemoglobin isolated from protein inclusion bodies

Vitreoscilla hemoglobin (VHb), a homodimeric protein containing two heme groups in its native state, was used as a model to investigate inclusion body approtein solubilization, prosthetic group incorporation, and reactivation. High-level expression in recombinant Escherichia coli results in accumulation of a substantial portion of heme-free VHb in inclusion bodies. VHb can be solubilized from these inclusion bodies by relatively low concentrations of urea with the dissolution midpoint at approximately 3.2M urea. Dissolution in the presence of stoichiometric heme shifts the dissolution midpoint to approximately 4.5M urea without influencing the dissolution properties of contaminant proteins, suggesting the effect is specific for VHb. Denaturation of apoVHb and holoVHb obtained from purified native VHb has midpoints of 2.9M and 5.1M urea, respectively. VHb solubilized from inclusion bodies with urea at concentrations from 0 to 3.5M urea can be regenerated by heme addition without dilution of urea to yield active holoVHb. The fraction of solubilized VHb reconstituted upon heme addition is maximum at around 30% when solubilization and reconstitution is conducted in less than 1M urea. At these low urea concentrations, approximately 5% of inclusion body VHb is solubilized. These results show the utility of prosthetic group addition to reconstitute holoVHb in the presence of urea. Also, these findings suggest that some inclusion body protein has partially folded conformation and that a fractional dissolution and refolding process may be advantageous.     

Studies on the subunits of Escherichia coli coenzyme A transferase. Reconstitution of an active enzyme.

The alpha and beta subunits of the acetyl-CoA:acetoacetate-CoA transferase were purified by isoelectric focusing of the enzyme in the presence of 6 M urea. The purified beta subunit, in which the active center of the enzyme is located, exhibits low catalytic activity (2% of the specific activity of the native enzyme) which is stimulated 5-6-fold in the presence of an equimolar concentration of alpha subunit. The presence of the substrate,acetoacetyl-CoA, is required to recover the catalytic activity of the beta subunit and mixtures containing purified alpha and beta subunits. When the enzyme is dissociation in the presence of 6 M urea and the subunits are not fractioned, removal of the urea by dialysis results in the recovery of 88-98% of enzymic activity and the native alpha2beta2 subunit structure. However, analysis of this renatured enzyme by immunochemical techniques shows that the enzyme does not refold to a completely native conformation. This renatured enzyme exhibits an immunological reactivity more closely resembling the isolated alpha subunit. The results indicate that the alpha subunit serves as a structural subunit, or possible a maturation subunit, imposing a conformation on the beta subunit that is catalytically more competent.     

Optimization of inclusion body solubilization and renaturation of recombinant human growth hormone from Escherichia coli

Recombinant human growth hormone (r-hGH) was expressed in Escherichia coli as inclusion bodies. In 10 h of fed-batch fermentation, 1.6 g/L of r-hGH was produced at a cell concentration of 25 g dry cell weight/L. Inclusion bodies from the cells were isolated and purified to homogeneity. Various buffers with and without reducing agents were used to solubilize r-hGH from the inclusion bodies and the extent of solubility was compared with that of 8 M urea as well as 6 M Gdn-HCl. Hydrophobic interactions as well as ionic interactions were found to be the dominant forces responsible for the formation of r-hGH inclusion bodies during its high-level expression in E. coli. Complete solubilization of r-hGH inclusion bodies was observed in 100 mM Tris buffer at pH 12.5 containing 2 M urea. Solubilization of r-hGH inclusion bodies in the presence of low concentrations of urea helped in retaining the existing native-like secondary structures of r-hGH, thus improving the yield of bioactive protein during refolding. Solubilized r-hGH in Tris buffer containing 2 M urea was found to be less susceptible to aggregation during buffer exchange and thus was refolded by simple dilution. The r-hGH was purified by use of DEAE-Sepharose ion-exchange chromatography and the pure monomeric r-hGH was finally obtained by using size-exclusion chromatography. The overall yield of the purified monomeric r-hGH was approximately 50% of the initial inclusion body proteins and was found to be biologically active in promoting growth of rat Nb2 lymphoma cell lines.     

Cloning and expression of human haptoglobin subunits in Escherichia coli: delineation of a major antioxidant domain

Human plasma haptoglobin (Hp) comprises alpha and beta subunits. The alpha subunit is heterogeneous in size, therefore isolation of Hp and its subunits is particularly difficult. Using Escherichia coli, we show that alpha1, alpha2, beta, and alpha2beta chain was abundantly expressed and primarily present in the inclusion bodies consisting of about 30% of the cell-lysate proteins. Each cloned subunit retained its immunoreactivity as confirmed using antibodies specific to alpha or beta chain. By circular dichroism, the structure of each expressed subunit was disordered as compared to the native Hp. The antioxidant activity was found to be associated with both alpha and beta chains when assessed by Cu(2+)-induced oxidation of low density lipoprotein (LDL). Of remarkable interest, the antioxidant activity of beta chain was extremely potent and markedly greater than that of native Hp (3.5x), alpha chain (10x) and probucol (15x). The latter is a clinically proved potent compound used for antioxidant therapy. The "unrestricted" structure of beta subunit may therefore render its availability for free-radical scavenge, which provides a utility for the future design of a "mini-Hp" in antioxidant therapy. It may also provide a new insight in understanding the mechanism involved in the antioxidant nature of Hp.     

Optimized procedures for purification and solubilization of basic fibroblast growth factor inclusion bodies

The efficiency of purification of basic fibroblast growth factor (bFGF) inclusion bodies using EDTA and nonionic detergents was improved from 25 to 40% by shifting the pH from 8.5 to strong alkaline conditions (pH 9.5 – 10.5). Complete dissolution of bFGF inclusion bodies by guanidinium hydrochloride (> 3 m) was independent of pH and the presence of reducing agents. In contrast, solubilization of bFGF inclusion bodies by urea was pH-dependent and increased in efficiency (e.g. from 0 to 100%) by increasing the pH (from pH 5.0 to 10.5 at 9 m urea). The purification and solubilization procedures are efficient for inclusion body concentrations corresponding to 10 and 100 g per l dry cell weight, respectively.     

Positioning of protein-coding genes on the soybean chloroplast genome

Seven major plastid protein encoding genes were positioned on the soybean chloroplast DNA by heterologous hybridization. These include the genes for the alpha, beta and epsilon subunits of the CF₁ component of ATP synthase (atpA, atpB and atpE respectively), for subunit III of the CF₀ component of ATP synthase (atpH), for the cytochrome f (cytF), for the ‘32 Kd’ thylakoid protein (psbA), and for the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (rbcL), all of which map in the large single copy region. The atpB, atpE and rbcL genes are located in the region adjacent to one of the segments of the inverted repeat. The genetic organization of the soybean chloroplast DNA is compared to that of other plastid genomes.     

A rapid method for analyzing recombinant protein inclusion bodies by mass spectrometry

The identification and characterization of a protein overexpressed in insoluble inclusion bodies in Escherichia coli are the first crucial and time-limiting steps in recombinant protein expression. Here, a straightforward approach to the analysis of recombinant proteins in inclusion bodies is presented. Inclusion bodies were dissolved in 8M urea and analyzed by matrix-assisted laser desorption ionization (MALDI)-time of flight mass spectrometry without prior desalting. Mass determination was achieved by direct spotting of the samples onto the MALDI target and serial dilution in the matrix. The masses of four different proteins, expressed in inclusion bodies, were determined with a mass accuracy better than 0.1%. Furthermore, protein modifications, such as N-terminal processing of single amino acids or artificial cyanylation caused by incubation of the inclusion bodies with urea at elevated temperatures, could be detected. Similarly, tryptic digests were directly analyzed in 2M urea to obtain peptide mass fingerprints for identification and more detailed information on the primary protein structure and secondary modifications. Due to the presence of ammonia in the urea-containing buffers, no Na(+) adducts were observed in the peptide mass fingerprint analysis. Taken together, the rapid and robust procedures presented here greatly facilitate the analysis of recombinant proteins.     

Genes encoding the beta and epsilon subunits of the proton-translocating ATPase from Anabaena sp. strain PCC 7120.

The genes encoding the beta (atpB) and epsilon (atpE) subunits of the ATPase from the cyanobacterium Anabaena sp. strain PCC 7120 were cloned, and their sequences were determined. atpB and atpE are each single-copy genes in the Anabaena genome. The two genes are separated by a 96-base-pair intergenic spacer and transcribed as a single mRNA of 2.3 kilobases that initiates approximately 200 base pairs upstream of the atpB coding region. The predicted translation product of atpB has 81 and 68% amino acid identity with the corresponding proteins from spinach chloroplasts and Escherichia coli, respectively. The atpE gene product is less conserved, with 41 and 33% amino acid identity with the corresponding proteins from spinach chloroplasts and E. coli, respectively. The organization of the Anabaena atpB and atpE genes relative to adjacent genes differs from that of both E. coli and chloroplasts.