Expression of bovine pancreatic ribonuclease A in Escherichia coli

Protein@Inorganic Nanodumpling System for High-Loading Protein Delivery with Activatable Fluorescence and Magnetic Resonance Bimodal Imaging Capabilities

Efficient protein delivery into the target cell is highly desirable for protein therapeutics. Current approaches for protein delivery commonly suffer from low-loading protein capacity, poor specificity for target cells, and invisible protein release. Herein, we report a protein@inorganic nanodumpling (ND) system as an intracellular protein delivery platform. Similar to a traditional Chinese food, the dumpling, ND consists of a protein complex "filling" formed by metal-ion-directed self-assembly of protein cargos fused to histidine-rich green fluorescent proteins (H₃₉GFPs), which are further encapsulated by an external surface "wrapper" of manganese dioxide (MnO₂) via in situ biomineralization. This ND structure allows for a high loading capacity (>63 wt %) for protein cargos with enhanced stability. NDs can be targeted and internalized into cancer cells specifically through folic acid receptors by surface-tailored folic acid. The protein cargo release is in a bistimuli-responsive manner, triggered by an either reductive or acidic intracellular microenvironment. Moreover, the MnO₂ nanowrapper is an efficient fluorescence quencher for inner fused GFPs and also a "switch-on" magnetic resonance imaging (MRI) agent via triggered release of Mn²⁺ ions, which enables activatable fluorescence/MRI bimodal imaging of protein release. Finally, the ND is highly potent and specific to deliver functional protein ribonuclease A (RNase A) into cultured target cells and the tumor site in a xenografted mouse model, eliminating the tumor cells with high therapeutic efficacy. Our approach provides a promising alternative to advance protein-based cancer therapeutics.

Guanine binding site of the Nicotiana glutinosa ribonuclease NW revealed by X-ray crystallography

Ribonuclease NW (RNase NW), the wound-inducible RNase in Nicotiana glutinosa leaves, preferentially cleaves guanylic acid. We expressed the cDNA encoding RNase NW in the methylotrophic yeast Pichia pastoris using the expression vector pPIC9K, and the resulting recombinant RNase NW (ryRNaseNW) secreted into medium was purified to apparent homogeneity using column chromatography. The crystal structure of ryRNase NW bound to 5'-GMP was determined at 1.5 A resolution by molecular replacement with tomato RNase LE as a search model. The RNase NW structurally belongs to the (alpha + beta) class of proteins, having eight helices (five alpha-helices and three 3(10) helices) and six beta-strands, and its structure is highly similar to those of other plant RNases, including a uridylic acid preferential RNase MC1 from bitter gourd seeds. The guanine ring of 5'-GMP lies in a hydrophobic pocket of the molecular surface composed of Tyr17, Tyr71, Ala80, Leu79, and Phe89: the guanine base is sandwiched between aromatic side chains of Tyr17 and Phe89. In addition, the guanine base is firmly stabilized by a network of hydrogen bonds of the side chains of Gln12 and Thr78, as well as of the main chain of Leu79. Therefore, Gln12, Tyr17, Thr78, Leu79, and Phe89 are responsible for recognition of the guanine base by RNase NW, findings which provide insight into the manner in which RNase NW preferentially cleaves guanylic acid.

Overexpression of bacterio-opsin in Escherichia coli as a water-soluble fusion to maltose binding protein: efficient regeneration of the fusion protein and selective cleavage with trypsin

Bacteriorhodopsin (bR) is a light-driven proton pump from Halobacterium salinarium and is a model system for studying membrane protein folding, stability, function, and structure. bR is composed of bacterio-opsin (bO), the 248-amino acid apo protein, and all-trans retinal, which is linked to lysine 216 via a protonated Schiff base. A bO gene (sbOd) possessing 29 unique restriction sites and a carboxyl-terminal purification epitope (1D4, nine amino acids) has been designed and synthesized. Overexpression of bO was achieved by fusion to the carboxyl terminus of maltose binding protein (MBP). The expressed fusion protein (MBP-sbO-1D4) formed inclusion bodies in Escherichia coli and, following solubilization with urea and removal of the urea by dialysis, approximately 170 mg of approximately 75% pure MBP-sbO-1D4 was obtained from 1 L of culture. MBP-sbO-1D4 formed high molecular weight (> or = 2,000 kDa) oligomers that were water-soluble. The synthetic bO with the 1D4 tag (sbO-1D4) was separated from MBP by trypsin cleavage at the factor Xa site between the MBP and sbO-1D4 domains. Selective trypsin cleavage at the factor Xa site, instead of at the 14 other potential trypsin sites within bO, was accomplished by optimization of the digestion conditions. Both MBP-sbO-1D4 and sbO-1D4 were regenerated with all-trans retinal and purified to homogeneity. In general, 6-10 mg of sbR-1D4 and 52 mg of MBP-sbR-1D4 were obtained from 1 L of cell culture. No significant differences in terms of UV/vis light absorbance, light/dark adaptation, and photocycle properties were observed among sbR-1D4, MBP-sbR-1D4, and bR from H. salinarium.

Reconstructing the evolutionary history of the artiodactyl ribonuclease superfamily

The sequences of proteins from ancient organisms can be reconstructed from the sequences of their descendants by a procedure that assumes that the descendant proteins arose from the extinct ancestor by the smallest number of independent evolutionary events ('parsimony'). The reconstructed sequences can then be prepared in the laboratory and studied. Thirteen ancient ribonucleases (RNases) have been reconstructed as intermediates in the evolution of the RNase protein family in artiodactyls (the mammal order that includes pig, camel, deer, sheep and ox). The properties of the reconstructed proteins suggest that parsimony yields plausible ancient sequences. Going back in time, a significant change in behaviour, namely a fivefold increase in catalytic activity against double-stranded RNA, appears in the RNase reconstructed for the founding ancestor of the artiodactyl lineage, which lived about 40 million years ago. This corresponds to the period when ruminant digestion arose in the artiodactyls, suggests that contemporary artiodactyl digestive RNases arose from a non-digestive ancestor, and illustrates how evolutionary reconstructions can help in the understanding of physiological function within a protein family.

Residues 36-42 of liver RNase PL3 contribute to its uridine-preferring substrate specificity. Cloning of the cDNA and site-directed mutagenesis studies

Within the superfamily of homologous mammalian ribonucleases (RNases) 4 distinct families can be recognized. Previously, representative members of three of these have been cloned and studied in detail. Here we report on the cloning of a cDNA encoding a member of the fourth family, RNase PL3 from porcine liver. The deduced amino acid sequence showed the presence of a signal peptide, confirming the notion that RNase PL3 is a secreted RNase. Expression of the cDNA in Escherichia coli yielded 1.5 mg of purified protein/liter of culture. The recombinant enzyme was indistinguishable from the enzyme isolated from porcine liver based on the following criteria: amino acid analysis, N-terminal amino acid sequence, molecular weight, specific activity toward yeast RNA, and kinetic parameters for the hydrolysis of uridylyl(3',5')adenosine and cytidylyl(3',5')adenosine. Interestingly, the kinetic data showed that RNase PL3 has a very low activity toward yeast RNA, i.e., 2.5% compared to pancreatic RNase A. Moreover, using the dinucleotide substrates and homopolymers it was found that RNase PL3, in contrast to most members of the RNase superfamily, strongly prefers uridine over cytidine on the 5' side of the scissile bond. Replacement, by site-directed mutagenesis, of residues 36-42 of RNase PL3 by the corresponding ones from bovine pancreatic RNase A resulted in a large preferential increase in the catalytic efficiency for cytidine-containing substrates. This suggests that this region of the molecule contains some of the elements that determine substrate specificity.

Renaturation of recombinant proteins produced as inclusion bodies

Expression of recombinant proteins in Escherichia coli often results in the formation of insoluble inclusion bodies. Within the last few years specific methods and strategies have been developed to prepare active proteins from these inclusion bodies. These methods include (i) isolation of inclusion bodies after disintegration of cells by mechanical forces and purification by washing with detergent solutions or low concentrations of denaturant, (ii) solubilization of inclusion bodies with high concentrations of urea or guanidine-hydrochloride in combination with reducing reagents, and (iii) renaturation of the proteins including formation of native disulphide bonds. Renatured and native disulphide bond formation are accomplished by (a) either air oxidation, (b) glutathione reoxidation starting from reduced material, or (c) disulphide interchange starting from mixed disulphides containing peptides. The final yield of renatured proteins can be increased by adding low concentrations of denaturant during renaturation.

Production of mature bovine pancreatic ribonuclease in Escherichia coli

The coding sequence for the bovine pancreatic ribonuclease (RNase) precursor has been cloned and produced in Escherichia coli using the polymerase chain reaction (PCR) technique. A PCR amplification has been carried out utilizing as template the recombinant plasmid, pQR138, which contains the coding sequence for the RNase precursor, and primers that allow for the addition of new sequences at the 5' and 3' ends of the coding sequence. The resultant fragment contains two coding sequences, one for a hexapeptide and the other for pre-RNase. This fragment has been cloned into the expression vector, pKK223.3, under the control of the tac promoter, to form a two-cistron vector. Upon induction with IPTG, E. coli cells harboring this construct generate a bicistronic mRNA which upon translation produces a hexapeptide and pre-RNase. The RNase precursor is efficiently translocated into the periplasmic space of E. coli. Upon translocation, the signal sequence is removed generating mature RNase. Formation of the disulfide bridges in RNase is facilitated by the oxidative environment of the periplasm and a fully active protein is obtained. RNase produced in E. coli has been purified to homogeneity by cation-exchange chromatography, and the removal of the signal sequence has been verified by N-terminal sequencing. The total process from inoculation of media to obtaining pure and fully active recombinant RNase is achieved in 48 h.

Secretion of mammalian ribonucleases from Escherichia coli using the signal sequence of murine spleen ribonuclease

A nucleotide sequence identical with that of the recently identified murine pancreatic ribonuclease (RNAase) was isolated from a murine spleen cDNA library. Active RNAase was expressed and secreted from Escherichia coli lon-htpr- transformed with a plasmid containing the E. coli trp promoter followed by the murine RNAase gene sequence, including the original eukaryotic 26-amino-acid signal sequence. Approx. 1 mg of properly matured RNAase protein/litre was secreted into the medium of a fermentor culture after the promotor was induced by tryptophan starvation. When the signal sequence was deleted from the plasmid, intracellular RNAase activity was very low and there was no significant supernatant RNAase activity. Even higher RNAase yields were obtained with a synthetic gene for bovine pancreatic ribonuclease cloned after the signal sequence of the murine gene. About 2 mg of correctly processed RNAase A/litre was isolated from the growth medium, and a further 8-10 mg of correctly processed RNAase/litre could be isolated from the soluble fraction of the cells. Thus this eukaryotic signal sequence is both recognized by the E. coli transport and processing apparatus and gives efficient secretion, as well as export, of active, mature mammalian RNAases.

Polymerization and solubility of recombinant hemoglobins alpha 2 beta 2 (6Val) (Hb S) and alpha 2 beta 2(6Leu) (Hb Leu)

In an effort to clarify the role of amino acid hydrophobicity at the beta 6 position in sickling we have made recombinant hemoglobin tetramers containing beta 6 Val (Hb S) and beta 6 Leu (Hb Leu). Recombinant Hb S and Hb Leu had the same electrophoretic mobility, chromatographic behavior, and absorption spectrum. The deoxy form of both tetramers polymerized in high phosphate buffer (1.8 M) and exhibited distinct delay times prior to polymerization. The kinetics of polymerization for recombinant and native Hb S were similar, while recombinant Hb Leu polymerized more readily. The solubility of deoxy Hb Leu was less than deoxy Hb S, indicating that rapid polymerization and decreased solubility of deoxyhemoglobin is accelerated with increasing hydrophobicity at the beta 6 position.

The ribonuclease from an extinct bovid ruminant

The sequence of the ribonuclease from the ancestor of swamp buffalo, river buffalo, and ox, corresponding approximately to Pachyportax latidens, an extinct ruminant known from the fossil record, has been reconstructed using the rule of 'maximum parsimony'. This protein and two sequences that may have been intermediates in the evolution of modern ribonuclease have been constructed in the laboratory by site-directed mutagenesis, and their properties examined.

An improved system for expressing pancreatic ribonuclease in Escherichia coli

An improved method for expressing and purifying bovine pancreatic ribonuclease from a synthetic gene using the lambda promoter controlled by a temperature-sensitive repressor is described. The procedure involves isolation in the presence of a refolding buffer containing oxidized and reduced glutathione, under conditions where RNase can refold, but where proteases presumably do not. Yields are approx. 2 mg purified protein per 1 ferment.

Expression of bovine pancreatic ribonuclease A coded by a synthetic gene in Bacillus subtilis

Two different hybrid genes were constructed which fuse the Bacillus amyloliquefaciens alkaline protease gene (apr[BamP]) promoter and signal peptide coding region to a synthetic bpr gene coding for the mature bovine pancreatic RNase A. The first gene fusion (apr-bpr1) contained the apr[BamP] signal peptide coding region fused to mature bpr through a linker coded 3-amino acid region and retained the signal processing site ala-ala of the alkaline protease. The second fusion (apr-bpr2) joined the end of the apr[BamP] signal peptide coding sequence to the mature bpr resulting in a hybrid signal processing site ala-lys. B. subtilis strains harboring these gene fusions secreted bovine pancreatic RNase A into the growth medium. Cleavage at the hybrid signal processing site ala-lys resulted in the secretion of bovine pancreatic RNase A from B. subtilis which had an N-terminal amino acid sequence that was identical to the native RNase A. Bovine pancreatic RNase A contains four disulfide bonds and the proper formation of these bonds is required for activity. RNase activity could be detected in the culture supernatants of strains carrying the apr-bpr gene fusions, which suggests that the proper disulfide bonds have formed spontaneously.

Expression of atrial natriuretic factor as a cleavable fusion protein with chloramphenicol acetyltransferase in Escherichia coli

Recombinant fusion proteins containing human atrial natriuretic factor, ANF(1-28) joined to chloramphenicol acetyltransferase (CAT) via cleavable linker sequences have been produced in Escherichia coli. The linker sequences were designed to allow the release of authentic ANF(1-28) following proteolytic cleavage by enterokinase or thrombin, or chemical cleavage with 2-(2-nitrophenylsulphenyl)-3-methyl-3'-bromoindolenine. Proteins, containing ANF(1-28) fused to the carboxyl-terminal region of CAT (using the ScaI restriction site in the cat gene), were largely soluble in E. coli and were obtained in higher yield than analogues containing ANF(1-28) linked to shorter CAT sequences. The longer derivatives also retained CAT activity allowing subsequent purification by affinity chromatography.

Expression of the chemically synthesized gene for ribonuclease T1 in Escherichia coli using a secretion cloning vector

The gene for ribonuclease T1 from Aspergillus oryzae has been chemically synthesized using the segmental support technique. An Escherichia coli clone producing the ribonuclease at high levels was constructed by linking the gene downstream to the region coding for the signal peptide of the OmpA protein (a major outer membrane protein of E. coli), using the secretion cloning vector pIN-III-ompA2. This strategy was employed in order to circumvent a possible toxic effect of the gene product on the host cell. Active ribonuclease containing four additional amino acids at the N-terminus could be isolated from the periplasmic fraction of the host. The final yield after purification was 20 mg enzyme/l liquid culture. With respect to immunological, catalytic and specific behaviour, no qualitative differences could be detected between the enzyme from the over-producing E. coli strain and ribonuclease T1 isolated from A. oryzae.

Expression of porcine pancreatic phospholipase A2. Generation of active enzyme by sequence-specific cleavage of a hybrid protein from Escherichia coli

The cDNA coding for the porcine pancreatic prophospholipase A2 (proPLA) has been cloned and expressed in E. coli. Expression of proPLA could only be obtained in the form of intracellular aggregates after fusing the 15 kDa proPLA to a large (greater than or equal to 45 kDa) bacterial peptide. The fusion protein was readily purified from cell lysates, and specifically cleaved. Cleavage of the fusion protein was achieved with either hydroxylamine (at Asn/Gly sequences in the denatured protein), or trypsin (between the pro- and the mature PLA in the renatured fusion protein). The former method releases a proPLA-like enzyme, while the latter directly yields PLA. Renaturation of the fusion protein was made possible by the use of a recently reported new S-sulphonation method. The released (pro)PLA was purified (yields of 2-3 mg/ltr of culture medium), and showed identical properties compared to native (pro)PLA.