Efficient expression and secretion of recombinant hirudin III in E. coli using the L-asparaginase II signal sequence

One of the hirudin variants HV3 was efficiently expressed in Escherichia coli using the L-asparaginase II signal sequence and the product was secreted into the culture medium. For the secretory manufacture of HV3, the L-asparaginase II signal sequence containing a single NheI restriction site at its 3' end was designed using the degenerate codons and PCR-amplified from E. coli chromosomal DNA. The synthetic HV3 coding sequence was fused to the signal sequence in-frame by its 5' NheI restriction site. The above signal-HV3 fusion gene was inserted into an expression vector pTA, which was derived from pkk223-3 such that its expression was under the control of the tac promotor. The resulting HV3 secretion expression vector pTASH thus constructed was introduced into an E. coli host cell AS1.357 with high L-asparaginase II producing level. After inducing with IPTG, the expression product was efficiently secreted into the culture medium and shake-flask culturing gave a yield of approximately 5 x 10(5)ATU/L (approximately 60mg/L). The secreted HV3 was easily purified from culture supernatant using ultrafiltration, ion-exchange column chromatography, and FPLC reverse-phase chromatography. The purified rHV3 from the culture supernatant had the expected N-terminal amino sequence and strong antithrombin activity, suggesting that the signal sequence was completely removed and the product was processed accurately during the secretion process.     

Mutations that alter the signal sequence of alkaline phosphatase in Escherichia coli.

A phoA-lacZ gene fusion was used to isolate mutants altered in the alkaline phosphatase signal sequence. This was done by selecting Lac+ mutants from a phoA-lacZ fusion strain that produces a membrane-bound hybrid protein and is unable to grow on lactose. Two such mutant derivatives were characterized. The mutations lie within the phoA portion of the fused gene and cause internalization of the hybrid protein. When the mutations were genetically recombined into an otherwise wild-type phoA gene, they interfered with export of alkaline phosphatase to the periplasm. The mutant alkaline phosphatase protein was found instead in the cytoplasm in precursor form. DNA sequence analysis demonstrated that both mutations lead to amino acid alterations in the signal sequence of alkaline phosphatase.     

Secretion of human interferon-alpha induced by using secretion vectors containing a promoter and signal sequence of alkaline phosphatase gene of Escherichia coli

We constructed a new vector containing the promoter and the signal sequence of E. coli phoA gene, the structural gene for the periplasmic alkaline phosphatase. One of the most useful characteristics of this vector is the unique HindIII restriction site located just at the end of the phoA signal sequence. This restriction site was generated by oligonucleotide-directed site-specific mutagenesis without changing the amino acid sequence of the signal peptide. Any kind of foreign structural gene can be easily inserted into the HindIII site by using synthetic oligonucleotides to construct a hybrid gene which has neither an extra sequence nor a deletion between the phoA signal sequence and the foreign structural gene. Human alpha-interferon gene was inserted into this HindIII site. When this hybrid gene was expressed under the control of the phoA promoter region, a low but significant activity was recovered in the cold water wash of the cells after an osmotic shock procedure.     

A new signal sequence trap using alkaline phosphatase as a reporter.

Secreted and transmembrane proteins are critical to the cell-cell interactions governing normal development and carcinogenesis. To facilitate the identification of such molecules, we have developed a novel signal sequence trap that uses human placental alkaline phosphatase as a reporter. Libraries from mouse prostate and human prostatic carcinoma were constructed to test the PST (peptide signal trap) system, resulting in the identification of several secreted and transmembrane proteins.     

Signal sequence of alkaline phosphatase of Escherichia coli.

The amino acid sequence of the signal sequence of phoA was determined by DNA sequencing by using the dideoxy chain termination technique (Sanger et al., Proc. Natl. Acad. Sci. U.S.A. 74:5463-5467, 1977). The template used was single-stranded DNA obtained from M13 on f1 phage derivatives carrying phoA, constructed by in vitro recombination. The results confirm the sequence of the first five amino acids determined by Sarthy et al. (J. Bacteriol. 139:932-939, 1979) and extend the sequence in the same reading frame into the amino terminal region of the mature alkaline phosphatase (Bradshaw et al., Proc. Natl. Acad. Sci. U.S.A., 78:3473-3477, 1981). As was predicted (Inouye and Beckwith, Proc. Natl. Acad. Sci. U.S.A. 74:1440-1444, 1977), the signal sequence was highly hydrophobic. The alteration of DNA sequence was identified for a promoter mutation that results in the expression of phoA independent of the positive control gene phoB and in insensitivity to high phosphate.     

Reconstitution of denatured E. coli alkaline phosphatase with E. coli ribosome.

E. coli alkaline phosphatase was denatured by physical/chemical means. In vitro reconstitution of this denatured enzyme was assisted by 70S E. coli ribosome, as shown by the recovery of its catalytic competence. Almost total recovery of activity of the totally inactivated enzyme was obtained in presence of equimolar concentration of 70S ribosome at 50 degrees C.     

Expression of chemically synthesized alpha-neo-endorphin gene fused to E. coli alkaline phosphatase.

An alpha-neo-endorphin (alpha NE) gene, which we previously synthesized chemically and inserted into E. coli beta-galactosidase gene of pK013 plasmid, has been excised and fused to E. coli alkaline phosphatase (APase) gene. One of the transformants was named E15/pA alpha NE1. Under the APase gene regulation, APase-alpha NE chimeric protein was expressed at 1.3 X 10(6) molecules per cell, and accounted for about 60% of total cellular proteins. The HPLC pattern of CNBr treated E15/pA alpha NE1 was very simple reflecting the high content of the chimeric protein and low numbers of methionine residues in it. A series of genes encoding APase-alpha NE chimeric proteins in which 30 to 94 C-terminal amino acid residues were replaced by (met)-alpha NE, was cloned in E. coli. Transportation of the chimeric proteins to periplasmic space was studied. All chimeric proteins were apparently processed by signal peptidase but few, if any, was transported to the periplasmic space.     

Enzyme secretion in E. coli K12 : studies on alkaline phosphatase synthesis using an unsaturated fatty-acid auxotroph.

The role of unsaturated fatty-acid starvation, and of the substitution of $\text{trans}$ for $\text{cis}$ fatty acids in the membrane phospholipid, on the secretion of alkaline phosphatase, has been investigated. A system in which alkaline phosphatase synthesis was initiated by a temperature shift has been used to obviate possible complications resulting from phosphate depletion. In contrast to earlier reports, we find (a) there is very little effect of unsaturated fatty-acid starvation on the synthesis of alkaline phosphatase; (b) the synthesis of both β-galactosidase and alkaline phosphatase synthesis was severely reduced below 27–30°C in cells grown on $\text{trans}\text{Δ}{}^9$ 16:1 fatty-acid, compared to cells grown on the $\text{cis}\text{Δ}{}^9$ 16:1 analogue. Thus no $\text{preferential}$ effect on alkaline phosphatase synthesis was observed.     

Increased efficiency of alkaline phosphatase production levels in Escherichia coli using a degenerate Pe1B signal sequence

To obtain an expression vector that will optimize secretion of proteins with disulfide bridges in Escherichia coli we fused the phoA gene, encoding the bacterial alkaline phosphatase (PhoA), to the sequence encoding the pectate lyase B signal sequence (PelBSS). We used an extensively degenerate pelBSS with silent mutations to study their effects on the production level and activity of PhoA. 11 representative clones differed by a factor of five between the lowest and the highest level of activity, and by a factor greater than seven for the production levels. The efficiency of translocation seems to be the result of an equilibrium between production and secretion levels that favours the secretion of active PhoA according to the competence of the fusion protein being translocated. Free energy calculations and the predicted mRNA secondary structures of the translation initiation regions showed that the high stability of the secondary structure decreased production and secretion levels of PhoA and vice versa. A stem-loop encompassing the degenerate positions downstream from the AUG start codon appears to be responsible for the differences in the production levels     

3-13C-methionine-labelled E. coli alkaline phosphatase

3-13C-methionine has been biosynthetically incorporated into E. coli alkaline phosphatase using strain CW3747 which is auxotrophic for Met. 13C NMR of the dimeric native enzyme labelled at the eight methionine residues of the primary structure shows a dispersion of resonance signals permitting resolution of at least five methionine environments, none of which coincide with the chemical shift position of free methionine. At acid pH, 13C signal intensity is shifted to a chemical shift consistent with solvent exposure. However, three discrete resonances are observed, suggesting a retention of defined structure. The labelled protein thus can serve as a probe of conformational alterations of the enzyme.     

Factors affecting the zinc content of E. coli alkaline phosphatase

Through experiments with radioactively labeled EDTA, it has been shown that alkaline phosphatasc from E. coli has a high affinity for binding EDTA, requiring extensive dialysis for removal. This paper reviews the results of zinc analyses of E. coli alkaline phosphatase prepared in the presence and absence of EDTA. The presence of EDTA in most preparations of alkaline phosphatase accounts for previous overestimates of the zine content of the enzyme.With radioactively labeled EDTA, direct evidence for the binding of EDTA to the metal-free alkaline phosphatase is presented. It has been shown that the apoprotein binds two EDTA molecules rather strongly. Addition of four metal ions are necessary for reactivation of this EDTA-contaminated apoenzyme. However, when the EDTA-contaminated apoenzyme is subject for extensive dialysis and EDTA is removed, the addition of two zinc ions restores the enzyme activity completely.     

Isolation and properties of immobilized alkaline phosphatase from E. coli

Preparations of alkaline phosphatase from E. coli, immobilized on Sepharose, with a specific activity of 40-60 U/g wet weight were obtained. The immobilized enzyme was stable up to 50 degrees C; at higher temperatures it was inactivated. At 70 degrees most of the activity was lost for 1 h. The substrate (AMP) stabilized the enzyme. In the temperature range from 30 to 40 degrees C activation of the enzyme was observed, especially pronounced in the presence of the substrate. The pH optimum of the immobilized enzyme activity (7.8-8.2) is shifted towards the acid region, as compared to the soluble enzyme (8.0-8.6). The kinetic parameters for inhibition by the reaction product were determined using the integral Michaelis-Menten equation. KmAMP was found to be higher in case of the immobilized enzyme as compared to the soluble one (5.02 X 10(-4) M and 1.85 X 10(-5) M, respectively), which seems to be associated with diffusion limitations.     

Phospholipids of E. coli and activity of alkaline phosphatase]

The effects of liposomes prepared from the E. coli lipids on the activity of soluble alkaline phosphatase and on the complementation reaction between its subunits were studied. It was shown that the liposomes nonspecifically catalyze the dimerization of the enzyme subunits without changing the dimer activity. The effects of phospholipases A2 and C on the activity of membrane-bound alkaline phosphatase were studied. An interrelationship was found between the level of hydrolysis of membrane phosphatidyl glycerol (PG) by these enzymes and the changes in the activity of membrane-bound alkaline phosphatase. It was also shown that PG is less accessible to the effects of phospholipases in the cells with derepressed biosynthesis of alkaline phosphatase. It is assumed that the membrane PG interacts with the membrane-bound alkaline phosphatase during its translocation into the periplasm.     

Hysteresis on heating and cooling of E. coli alkaline phosphatase

Measurements of [theta](222) of E. coli phosphatase on heating from 20 degrees to 90 degrees and subsequent cooling to 20 degrees shows a gradual increase in [theta](222) on heating, while cooling shows a symmetric transition centered at 45 degrees . Reheating and cooling shows the same phenomenon. Enzyme heated and cooled once is fully active. The activity of the enzyme depends on its storage conditions (buffer and pH for example), but such changes are least to some extent reversible, especially by heating in different solvents. We conclude the enzyme exists in several forms which are in slow equilibrium with each other, so that the enzyme responds slowly when heated and hence is not at equilibrium during heating/cooling experiments.     

Expression and secretion of proteins in E. coli

This review outlines approaches to the cloning and expression of proteins in Escherichia coli. The expression vectors described here (pIN-III derivatives) utilize the strong lipoprotein promoter, which is controlled by the lac-UV5 promoter-operator. These vectors provide the means for targeting a protein to any of the four subcellular compartments of the bacterial cell: cytoplasm, cytoplasmic membrane, periplasm, and outer membrane. Of particular importance is that secretion of proteins into the E. coli periplasm (using the OmpA signal peptide) is applicable for the production of both prokaryotic and eukaryotic proteins thereby enhancing protein activity and stability.     

Interaction of effect on secretion of alkaline phosphatase from E. coli by charge of the N-terminal part of the signal peptide and proteins SecB and SecA

The cytoplasmic step of posttranslational secretion in Escherichia coli is catalyzed by export-specific chaperone SecB and translocational ATPase SecA. In addition, the efficiency of secretion depends on the charge of the signal peptide (SP). Substitution of positively charged Lys(-20) with noncharged Ala or negatively charged Glu in the N-terminal region of SP of the alkaline phosphatase (PhoA) precursor (prePhoA) was shown to decrease the PhoA secretion in the periplasm. The effect on secretion increased in the absence of SecB and was especially high on SecA inactivation. A change in SP charge strengthened the SecA and SecB dependences of secretion. On evidence of immunoprecipitation, the charge of the N-terminal region of SP had no effect on prePhoA interaction with the cytoplasmic secretion factors, suggesting no direct binding between this region and SecA or SecB. Yet the charge of the N-terminal region proved to affect the functions of SP as an intramolecular chaperone and a factor of prePhoA targeting to the membrane in cooperation with SecA and SecB.     

Efficient secretory production of alkaline phosphatase by high cell density culture of recombinant Escherichia coli using the Bacillus sp. endoxylanase signal sequence

New secretion vectors containing the Bacillus sp. endoxylanase signal sequence were constructed for the secretory production of recombinant proteins in Escherichia coli. The E. coli alkaline phosphatase structural gene fused to the endoxylanase signal sequence was expressed from the trc promoter in various E. coli strains by induction with IPTG. Among those tested, E. coli HB101 showed the highest efficiency of secretion (up to 25.3% of total proteins). When cells were induced with 1 mM IPTG, most of the secreted alkaline phosphatase formed inclusion bodies in the periplasm. However, alkaline phosphatase could be produced as a soluble form without reduction of expression level by inducing with less (0.01 mM) IPTG, and greater than 90% of alkaline phosphatase could be recovered from the periplasm by the simple osmotic shock method. Fed-batch cultures were carried out to examine the possibility of secretory protein production at high cell density. Up to 5.2 g/l soluble alkaline phosphatase could be produced in the periplasm by the pH-stat fed-batch cultivation of E. coli HB101 harboring pTrcS1PhoA. These results demonstrate the possibility of efficient secretory production of recombinant proteins in E. coli by high cell density cultivation. Received: 8 September 1999 / Received revision: 3 January 2000 / Accepted 4 January 2000     

Nucleotide sequence of the alkaline phosphatase gene of Escherichia coli

The nucleotide sequence of the alkaline phosphatase (APase) gene (phoA) of Escherichia coli strain 294 has been determined. Pre-APase has a total of 471 amino acids (aa) including a signal sequence of 21 aa. The derived aa sequence differs from that obtained by protein sequencing by the presence of aspartic acid instead of asparagine at positions 16 and 36, and glutamic acid instead of glutamine at position 197. Two open reading frames (ORF1 and ORF2) located downstream from phoA or upstream from proC have been found. ORF1 encodes a putative presecretory protein of 106 aa with a signal sequence of 21 or 22 aa. If this protein is actually produced, it may be one of the smallest periplasmic proteins in E. coli.     

Effects of signal sequence mutations on the kinetics of alkaline phosphatase export to the periplasm in Escherichia coli

We isolated a collection of mutants defective in the export of alkaline phosphatase to the periplasm. Two classes of mutants were obtained: one class with lesions unlinked to the phoA gene and a second class harboring linked mutations. Among the former class, one mutant is cold sensitive for growth and may be defective in a component of the Escherichia coli secretory apparatus. Included in the latter class are 47 mutants which are characterized in detail in this report. To facilitate DNA sequence analysis of these mutants, we devised a convenient method that relies on homologous recombination in vivo to transfer phoA mutations from the bacterial chromosome directly onto the genome of a single-stranded M13 phage vector. DNA sequence analysis revealed that our collection of mutants comprises six unique mutations, all of which reside in the phoA signal sequence coding region and lend further support to the notion that the length of the hydrophobic core of the signal sequence is crucial for its function in protein export. Kinetic studies showed that in these mutants, the small fraction of alkaline phosphatase which succeeds in reaching a periplasmic location, despite a defective signal sequence, is translocated across the membrane in a slow, posttranslational fashion.     

Receptor clustering and signal processing in E. coli chemotaxis

Chemotaxis in Escherichia coli is one of the most thoroughly studied model systems for signal transduction. Receptor-kinase complexes, organized in clusters at the cell poles, sense chemoeffector stimuli and transmit signals to flagellar motors by phosphorylation of a diffusible response regulator protein. Despite the apparent simplicity of the signal transduction pathway, the high sensitivity, wide dynamic range and integration of multiple stimuli of this pathway remain unexplained. Recent advances in computer modeling and in quantitative experimental analysis suggest that cooperative protein interactions in receptor clusters play a crucial role in the signal processing during bacterial chemotaxis.