Secretion incompetence of bovine pancreatic trypsin inhibitor expressed in Escherichia coli

Phage display and human disease detection

Phage display is a significant and active molecular method and has continued crucial for investigative sector meanwhile its unearthing in 1985. This practice has numerous benefits: the association among physiology and genome, the massive variety of variant proteins showed in sole collection and the elasticity of collection that can be achieved. It suggests a diversity of stages for manipulating antigen attachment; yet, variety and steadiness of exhibited library are an alarm. Additional improvements, like accumulation of non-canonical amino acids, resulting in extension of ligands that can be recognized through collection, will support in expansion of the probable uses and possibilities of technology. Epidemic of COVID-19 had taken countless lives, and while indicative prescriptions were provided to diseased individuals, still no prevention was observed for the contamination. Phage demonstration has presented an in-depth understanding into protein connections included in pathogenesis. Phage display knowledge is developing as an influential, inexpensive, quick, and effectual method to grow novel mediators for the molecular imaging and analysis of cancer.

Structure-function studies of an engineered scaffold protein derived from Stefin A. II: Development and applications of the SQT variant

Constrained binding peptides (peptide aptamers) may serve as tools to explore protein conformations and disrupt protein-protein interactions. The quality of the protein scaffold, by which the binding peptide is constrained and presented, is of crucial importance. SQT (Stefin A Quadruple Mutant-Tracy) is our most recent development in the Stefin A-derived scaffold series. Stefin A naturally uses three surfaces to interact with its targets. SQT tolerates peptide insertions at all three positions. Peptide aptamers in the SQT scaffold can be expressed in bacterial, yeast and human cells, and displayed as a fusion to truncated pIII on phage. Peptides that bind to CDK2 can show improved binding in protein microarrays when presented by the SQT scaffold. Yeast two-hybrid libraries have been screened for binders to the POZ domain of BCL-6 and to a peptide derived from PBP2', specific to methicillin-resistant Staphylococcus aureus. Presentation of the Noxa BH3 helix by SQT allows specific interaction with Mcl-1 in human cells. Together, our results show that Stefin A-derived scaffolds, including SQT, can be used for a variety of applications in cellular and molecular biology. We will henceforth refer to Stefin A-derived engineered proteins as Scannins.

Genetic selection for enhanced folding in vivo targets the Cys14-Cys38 disulfide bond in bovine pancreatic trypsin inhibitor

The periplasm provides a strongly oxidizing environment; however, periplasmic expression of proteins with disulfide bonds is often inefficient. Here, we used two different tripartite fusion systems to perform in vivo selections for mutants of the model protein bovine pancreatic trypsin inhibitor (BPTI) with the aim of enhancing its expression in Escherichia coli. This trypsin inhibitor contains three disulfides that contribute to its extreme stability and protease resistance. The mutants we isolated for increased expression appear to act by eliminating or destabilizing the Cys14-Cys38 disulfide in BPTI. In doing so, they are expected to reduce or eliminate kinetic traps that exist within the well characterized in vitro folding pathway of BPTI. These results suggest that elimination or destabilization of a disulfide bond whose formation is problematic in vitro can enhance in vivo protein folding. The use of these in vivo selections may prove a valuable way to identify and eliminate disulfides and other rate-limiting steps in the folding of proteins, including those proteins whose in vitro folding pathways are unknown.

Expression and purification of natural N-terminal recombinant bovine pancreatic trypsin inhibitor from Pichia pastoris

Bovine pancreatic trypsin inhibitor (BPTI) is a natural non-specific serine protease inhibitor and possesses the ability to inhibit trypsin, chymotrypsin, plasmin and plasma kallikrein. The expression of BPTI in Escherichia coli and other systems has been reported. However, the preparation of recombinant BPTI (rBPTI) with correct N-terminus in Pichia pastoris has not been successful. A previous study showed that the preBPTI with the prepro leader sequence of alpha mating factor (AMF) was not processed into natural BPTI in P. pastoris. Now, we introduce a new method to prepare rBPTI, which carries a natural N-terminal amino acid residue, Arg-Pro-Asp, in P. pastoris using human serum albumin signal peptide corresponding to the pre sequence. The concentration of rBPTI in an 80 l fermentor reached 900 mg/l. We also explored a rapid and simple purification protocol for rBPTI and the purity of rBPTI reached 95-98% as evaluated by SDS-PAGE analysis. The sequencing results showed that the sequence of N-terminal 15 amino acids of rBPTI was consistent with that of natural BPTI. The inhibitory activity of rBPTI against trypsin was the same as natural BPTI and its K(i) was 2.6+/-0.1 x 10(-9). The therapeutic effect of rBPTI on acute pancreatitis was identified in rats.

Production of human papillomavirus type 16 L1 virus-like particles by recombinant Lactobacillus casei cells

Infections with human papillomavirus type 16 (HPV-16) are closely associated with the development of human cervical carcinoma, which is one of the most common causes of cancer death in women worldwide. At present, the most promising vaccine against HPV-16 infection is based on the L1 major capsid protein, which self-assembles in virus-like particles (VLPs). In this work, we used a lactose-inducible system based on the Lactobacillus casei lactose operon promoter (plac) for expression of the HPV-16 L1 protein in L. casei. Expression was confirmed by Western blotting, and an electron microscopy analysis of L. casei expressing L1 showed that the protein was able to self-assemble into VLPs intracellularly. The presence of conformational epitopes on the L. casei-produced VLPs was confirmed by immunofluorescence using the anti-HPV-16 VLP conformational antibody H16.V5. Moreover, sera from mice that were subcutaneously immunized with L. casei expressing L1 reacted with Spodoptera frugiperda-produced HPV-16 L1 VLPs, as determined by an enzyme-linked immunosorbent assay. The production of L1 VLPs by Lactobacillus opens the possibility for development of new live mucosal prophylactic vaccines.

Phage display systems and their applications

Screening phage display libraries of proteins and peptides has, for almost two decades, proven to be a powerful technology for selecting polypeptides with desired biological and physicochemical properties from huge molecular libraries. The scope of phage display applications continues to expand. Recent applications and technical improvements driving further developments in the field of phage display are discussed.

A twin-arginine translocation (Tat)-mediated phage display system

The major limitation of conventional phage display is caused by its dependence on the Sec translocation pathway. All proteins displayed on filamentous phages must first be transported into the bacterial periplasm in an unfolded state via the Sec translocation machinery. Proteins that require a cytoplasmic environment and/or cytoplasmic components for folding, or that contain "stop transfer" signals, or reach their native state before they interact with the Sec proteins are not compatible with the Sec pathway. They can never be presented using conventional phage display. We have developed an alternative phage display system, termed the TPD system, which overcomes these limitations of conventional phage display by exploiting the properties of the twin-arginine translocation (Tat) pathway. The Tat pathway only exports folded proteins that have already attained their native conformation in the cytoplasm. We investigated the functional efficiency of the TPD system by displaying and panning for a mutant of the green fluorescent protein.

Improvement of downstream processing of recombinant proteins by means of genetic engineering methods

The rapid advancement of genetic engineering has allowed to produce an impressive number of proteins on a scale which would not have been achieved by classical biotechnology. At the beginning of this development research was focussed on elucidating the mechanisms of protein overexpression. The appearance of inclusion bodies may illustrate the success. In the meantime, genetic engineering is not only expected to achieve overexpression, but to improve the whole process of protein production. For downstream processing of recombinant proteins, the synthesis of fusion proteins is of primary importance. Fusion with certain proteins or peptides may protect the target protein from proteolytic degradation and may alter its solubility. Intracellular proteins may be translocated by means of fusions with signal peptides. Affinity tags as fusion complements may render protein separation and purification highly selective. These methods as well as similar ones for improving the downstream processing of proteins will be discussed on the basis of recent literature.

DnaK promotes the selective export of outer membrane protein precursors in SecA-deficient Escherichia coli

Consistent with many other results indicating that SecA plays an essential role in the translocation of presecretory proteins across the Escherichia coli inner membrane, we previously found that a approximately 95% depletion of SecA completely blocks the export of periplasmic proteins in vivo. Surprisingly, we found that about 25% of the outer membrane protein (OMP) OmpA synthesized after SecA depletion was gradually translocated across the inner membrane. In this study we analyzed the export of several other OMPs after SecA depletion. We found that 25-50% of each OMP as well as an OmpA-alkaline phosphatase fusion protein was exported from SecA-deficient cells. This partial export was completely abolished by the SecA inhibitor sodium azide and therefore still required the participation of SecA. Examination of a variety of OmpA derivatives, however, ruled out the possibility that OMPs are selectively translocated in SecA-deficient cells because SecA binds to their N termini with unusually high affinity. Export after SecA depletion was observed in cells that lack SecB, the primary targeting factor for OMPs, but was abolished by partial inactivation of DnaK. Furthermore, OmpA could be isolated in a stable complex with DnaK. The data strongly suggest that OMPs require only a relatively low level of translocase activity to cross the inner membrane because they can be preserved in a prolonged export-competent state by DnaK.

Improved expression characteristics of single-chain Fv fragments when fused downstream of the Escherichia coli maltose-binding protein or upstream of a single immunoglobulin-constant domain

The expression of single-chain Fv fragments (scFv) targeted to the periplasm of Escherichia coli often results in very low yields of soluble protein frequently accompanied by host cell growth arrest and sometimes lysis. Single-chain antibody fragments (scAb) are scFv with a human kappa light chain constant (HuCkappa) domain attached C-terminally and share similar problems of expression. By fusing the E. coli maltose-binding protein (mbp) gene either 3' or 5' to a scAb specific for the herbicide atrazine, a reduction in growth arrest was observed that was dependent on the order of gene fusion. The scAb-mbp fusion delayed the onset of growth arrest following induction while the mbp-scAb fusion appeared to ablate growth arrest completely. Cell fractionation revealed barely detectable levels of scAb-mbp in the periplasm while mbp-scAb was detected at equivalent levels as scAb in the periplasmic compartment, indicating that periplasmic scAb solubility is unrelated to propensity to cause growth arrest. IMAC purification of scAb and mbp-scAb proteins followed by liquid competition ELISA revealed the IC(50) for atrazine to be approximately 1 nM for both proteins demonstrating that 5'-mbp fusion does not alter antigen binding. The equivalent scFv and mbp-scFv vectors expressed far less material in both periplasmic and insoluble fractions indicating that the HuCkappa domain can have a positive effect on scFv expression when expressed either alone or as a mbp fusion. The ablation of growth arrest by a 5'-mbp fusion and enhancement of expression by a 3'-HuCkappa domain fusion were extended to a second scFv specific for the herbicide diuron. Therefore, by expressing scFv as tripartite fusions (mbp-scFv-HuCkappa) enhanced levels of soluble periplasmic expression can be achieved without causing growth arrest of the host cell, realizing the potential for constitutive expression of hapten-binding scFv in the E. coli periplasm.

Gene cloning, DNA sequencing, and expression of thermostable beta-mannanase from Bacillus stearothermophilus

A DNA genomic library constructed from Bacillus stearothermophilus, a gram-positive, facultative thermophilic aerobe that secretes a thermostable beta-mannanase, was screened for mannan hydrolytic activity. Recombinant beta-mannanase activity was detected on the basis of the clearing of halos around Escherichia coli colonies grown on a dye-labelled substrate, Remazol brilliant blue-locust bean gum. The nucleotide sequence of the mannanase gene, manF, corresponded to an open reading frame of 2,085 bp that codes for a 32-amino-acid signal peptide and a mature protein with a molecular mass of 76,089 Da. From sequence analysis, ManF belongs to glycosyl hydrolase family 5 and exhibits higher similarity to eukaryotic than to bacterial mannanases. The manF coding sequence was subcloned into the pH6EX3 expression plasmid and expressed in E. coli as a recombinant fusion protein containing a hexahistidine N-terminal sequence. The fusion protein has thermostability similar to the native enzyme and was purified by Ni2+ affinity chromatography. The values for the kinetic parameters Vmax and Km were 384 U/mg and 2.4 mg/ml, respectively, for the recombinant mannanase and were comparable to those of the native enzyme.

Aberrant processing of wild-type and mutant bovine pancreatic trypsin inhibitor secreted by Aspergillus niger

Bovine pancreatic trypsin inhibitor (BPTI) was secreted by Aspergillus niger at yields of up to 23 mg l-1 using a protein fusion strategy. BPTI was linked to part of the fungal glucoamylase protein (GAM) with a dibasic amino acid (KEX2) processing site at the fusion junction. Electrospray ionisation mass spectrometry and N-terminal protein sequencing revealed that, although biologically active in vitro, the purified products from a number of independent transformants consisted of a mixture of BPTI molecules differing at the N-terminus. Approximately 35-60% of this mixture was processed correctly. Aberrant processing of the GAM-BPTI fusion protein by the A. niger KEX2-like endoprotease was the most likely cause of this variation although the involvement of other fungal endoproteases could not be ruled out. In vitro studies have highlighted a weak interaction between BPTI and the Saccharomyces cerevisiae KEX2 endoprotease, suggesting that BPTI is not a potent inhibitor of KEX2p. A small proportion of the recombinant BPTI (10%) showed 'nicking' of the K15-A16 bond, indicating an interaction with a fungal trypsin-like enzyme. Mutant BPTI homologues designed to have anti-elastase activity, BPTI(K15V), BPTI(K15V,P13I) and BPTI(K15V,G12A), have also been expressed and secreted by A. niger. They also showed a similar spectrum of aberrant N-terminal processing but no 'nicking' of the K15-V16 bond was observed. Comparison of A. niger with other expression systems showed that it is an effective system for producing BPTI and its homologues, although not all molecules were correctly processed. This variation in processing efficiency may be useful in understanding the important determinants of protein processing in this fungus.

The role of the thioredoxin and glutaredoxin pathways in reducing protein disulfide bonds in the Escherichia coli cytoplasm

In Escherichia coli, two pathways use NADPH to reduce disulfide bonds that form in some cytoplasmic enzymes during catalysis: the thioredoxin system, which consists of thioredoxin reductase and thioredoxin, and the glutaredoxin system, composed of glutathione reductase, glutathione, and three glutaredoxins. These systems may also reduce disulfide bonds which form spontaneously in cytoplasmic proteins when E. coli is grown aerobically. We have investigated the role of both systems in determining the thiol-disulfide balance in the cytoplasm by determining the ability of protein disulfide bonds to form in mutants missing components of these systems. We find that both the thioredoxin and glutaredoxin systems contribute to reducing disulfide bonds in cytoplasmic proteins. In addition, these systems can partially substitute for each other in vivo since double mutants missing parts of both systems generally allow substantially more disulfide bond formation than mutants missing components of just one system. Some of these double mutants were found to require the addition of a disulfide reductant to the medium to grow well aerobically. Thus, E. coli requires either a functional thioredoxin or glutaredoxin system to reduce disulfide bonds which appear after each catalytic cycle in the essential enzyme ribonucleotide reductase and perhaps to reduce non-native disulfide bonds in cytoplasmic proteins. Our results suggest the existence of a novel thioredoxin in E. coli.

Localization of DnaK (chaperone 70) from Escherichia coli in an osmotic-shock-sensitive compartment of the cytoplasm

The chaperone DnaK can be released (up to 40%) by osmotic shock, a procedure which is known to release the periplasmic proteins and a select group of cytoplasmic proteins (including thioredoxin and elongation factor Tu) possibly associated with the inner face of the inner membrane. As distinct from periplasmic proteins, DnaK is retained within spheroplasts prepared with lysozyme and EDTA. The ability to isolate DnaK with a membrane fraction prepared under gentle lysis conditions supports a peripheral association between DnaK and the cytoplasmic membrane. Furthermore, heat shock transiently increases the localization of DnaK in the osmotic-shock-sensitive compartment of the cytoplasm. We conclude that DnaK belongs to the select group of cytoplasmic proteins released by osmotic shock, which are possibly located at Bayer adhesion sites, where the inner and outer membranes are contiguous.

Effect of modification of connecting peptide of proinsulin on its export

The production of a high yield of proinsulin using a secretion vector has been difficult, even with such modifications to the vector as a strong promoter and a good ribosome binding site. This investigation was therefore initiated to see whether modification of the connecting peptide of proinsulin has any effect on the export of proinsulin. We constructed three types of proinsulin secretion vectors: (a) pEZZ18-PI, by inserting the proinsulin gene into pEZZ18 vector; (b) pEZZ18-PI-C, by modifying ZZ-proinsulin by addition of the carboxy terminal peptide region of human insulin-like growth factor I (hIGFI) to the carboxy terminal end of proinsulin; and (c) pEZZ18-PI analogues, by sequentially deleting the connecting peptide region of proinsulin. The highest export yield of proinsulin was obtained when the connecting peptide region of the proinsulin was similar in size to that of hIGFI, or when most of the connecting peptide region of the proinsulin was deleted. The amount of exported ZZ-proinsulin analogues in these clones was over 25-times higher than that of ZZ-proinsulin with an unmodified connecting peptide in the secretion/expression vector pEZZ18-PI. On the basis of these observations, we conclude that modification of the mature domain of proinsulin is a critical factor for determination of the export of proinsulin.

Translocation and processing of various human parathyroid hormone peptides in Escherichia coli are differentially affected by protein-A-signal-sequence mutations

Two staphylococcal protein-A signal sequences were constructed and tested for function in Escherichia coli, after being linked to human parathyroid hormone (hPTH) cDNAS representing the intact form (1-84 amino acids) and two N-terminal (1-37 and 1-7 amino acids) peptides. One signal sequence was identical to the wild type, and the other signal contained a deletion of 12 bp at the 3' end. The truncated hPTH cDNAs were fused at their 3' ends to IgG-binding domains (ZZ) derived from protein A in order to facilitate purification and characterization. The expression plasmid pSPTH, containing the wild-type signal sequence, secreted efficiently the intact recombinant hPTH (1-84) into the medium. Plasmids containing the truncated hPTH genes after the wild-type signal, gave rise to hPTH-ZZ hybrid proteins which were correctly processed at the N-terminal, but the major fractions appeared in the periplasmic compartment. In contrast, the plasmid pS'PTH which harboured the 4-amino-acid signal deletion did not promote a uniform secretion of intact hPTH (1-84) to the medium, but released a non-processed form both into the periplasmic compartment and to the medium. The related plasmids pS'PTH37ZZ and pS'PTH7ZZ with the mutated signal sequence gave rise to small or trace amounts of unprocessed forms of fusion proteins in the medium and periplasm, thus the secretion competence was markedly reduced. Thus, for correct N-terminal processing, we conclude that the amino acid sequence in the signal adjacent to the expressed protein, is a key determinant. However, release into the medium or periplasmic space appeared to be dependent also on protein folding, irrespective of signal-sequence cleavage. Furthermore, we observed that the peptides with the wild-type signal sequence and correct N-terminal processing, were the only forms that showed internal cleavage of hPTH. Uncleaved signals may contribute to folding characteristics of the ensuing protein and e.g., prevent internal proteolysis.

Solubility and secretability

The solubility and secretability of proteins can often be affected by extremely small changes in their primary structure. Attempts to determine empirical rules for the alteration of protein structure to improve either of these characteristics have met with only partial success. Those (mostly serendipitous) improvements in solubility that have been obtained via mutagenesis cannot be considered to be 'protein engineering'. The most successful examples where directed mutagenesis has been used to alter protein solubility, hemoglobin and insulin, have relied on established crystal structures and a wealth of data about the relationship between sequence and structure of the targeted protein. Currently, optimizing culture growth conditions by trial and error remains the fastest way to improve expression.

Design, construction and function of a multicopy display vector using fusions to the major coat protein of bacteriophage M13

Incorporation of numerous copies of a heterologous protein (bovine pancreatic trypsin inhibitor; BPTI) fused to the mature major coat protein (gene VIII product; VIII) of bacteriophage M13 has been demonstrated. Optimization of the promoter, signal peptide and host bacterial strain allowed for the construction of a working vector consisting of the M13 genome, into which was cloned a synthetic gene composed of a lac (or tac) promoter, and sequences encoding the bacterial alkaline phosphatase signal peptide, mature BPTI and the mature coat protein. Processing of the BPTI-VIII fusion protein and its incorporation into the bacteriophage were found to be maximal in a host bacterial strain containing a prlA/secY mutation. Functional protein is displayed on the surface of M13 phage, as judged by specific interactions with antiserum, anhydrotrypsin, and trypsin. Such display vectors can be used for epitope mapping, production of artificial vaccines and the screening of diverse libraries of proteins or peptides having affinity for a chosen ligand. The VIII display phage system has practical advantages over the III display phage system in that many more copies of the fusion protein can be displayed per phage particle and the presence of the VII fusion protein has little or no effect on the infectivity of the resulting bacteriophage.

Escherichia coli alkaline phosphatase fails to acquire disulfide bonds when retained in the cytoplasm

The cysteines of the Escherichia coli periplasmic enzyme alkaline phosphatase, which are involved in disulfide bonds in the native enzyme, were found to be fully reduced when the protein was retained in the cytoplasm. Under these circumstances the cysteines remained reduced for at least several minutes after the synthesis of the protein was completed. This contrasted with the normally exported protein, wherein disulfide bonds formed rapidly. Disulfide bond formation accompanied export and processing. The implications of these findings for the inactivity of the enzyme in the cytoplasm are discussed.

BPTI and N-terminal extended analogues generated by factor Xa cleavage and cathepsin C trimming of a fusion protein expressed in Escherichia coli

A recombinant gene for BPTI (bovine pancreatic trypsin inhibitor) is expressed in Escherichia coli using a MBP (maltose-binding protein) fusion vector. BPTI is fused through an FXa (blood coagulation factor Xa protease) target sequence (Ile-Glu-Gly-Arg) to the C-terminus of MBP. The MBP moiety of the hybrid protein enables purification in one step utilizing MBP's affinity to cross-linked amylose, and the FXa target sequence allows specific cleavage of the hybrid protein. Effective FXa cleavage is achieved by spacing the FXa target sequence and Arg-1 of the BPTI sequence with four residues (Met-Glu-Ala-Glu). The resulting N-terminal extended BPTI is readily converted to the wild-type sequence by trimming with cathepsin C exopeptidase, for the activity of which the spacing tetrapeptide is optimized. FXa cleavage is prohibited when the target sequence is placed next to Arg-1. In this construction, off-target cleavage at a somewhat homologous sequence (Val-Pro-Gly-Arg) results in five- or six-residue extended BPTI, indicating new details of the FXa specificity. The yield of highly purified recombinant BPTI is 3-6 mg/liter of culture, making the MBP-BPTI expression system convenient for the production of sufficient amounts of protein for NMR studies. 1H NMR is used to analyze the N-extended BPTI analogues.