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Polymer masked-unmasked protein therapy (PUMPT) employs polymer conjugation to protect therapeutic proteins during transit through the bloodstream and allow controlled release at a disease site via triggered degradation of the polymeric component. Most reported PUMPT systems are based on the specific enzymatic degradation of the polymeric component to release the protein and reinstate its activity. In these cases, therapeutic output is dependent on the presence of the required enzyme at the disease site at a sufficiently high concentration. The present study aims to overcome this design limitation by using pH as the protein release trigger. An acidic-pH triggered PUMPT system is described herein employing biodegradable polyacetals (PAs) and trypsin as a model protein. While this system protects trypsin activity at the neutral pH of the bloodstream, acidic pH (characteristic of disease sites, tissue damage, or lysosomal compartments) contributes to PA degradation and the "unmasking" of protein activity.

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The development of effective protease therapeutics requires that the proteases be more resistant to naturally occurring inhibitors while maintaining catalytic activity. A key step in developing inhibitor resistance is the identification of key residues in protease-inhibitor interaction. Given that majority of the protease therapeutics currently in use are trypsin-fold, trypsin itself serves as an ideal model for studying protease-inhibitor interaction. To test the importance of several trypsin-inhibitor interactions on the prime-side binding interface, we created four trypsin single variants Y39A, Y39F, K60A, and K60V and report biochemical sensitivity against bovine pancreatic trypsin inhibitor (BPTI) and M84R ecotin. All variants retained catalytic activity against small, commercially available peptide substrates [kcat /KM = (1.2 ± 0.3) × 10(7) M(-1 ) s(-1) . Compared with wild-type, the K60A and K60V variants showed increased sensitivity to BPTI but less sensitivity to ecotin. The Y39A variant was less sensitive to BPTI and ecotin while the Y39F variant was more sensitive to both. The relative binding free energies between BPTI complexes with WT, Y39F, and Y39A were calculated based on 3.5 µs combined explicit solvent molecular dynamics simulations. The BPTI:Y39F complex resulted in the lowest binding energy, while BPTI:Y39A resulted in the highest. Simulations of Y39F revealed increased conformational rearrangement of F39, which allowed formation of a new hydrogen bond between BPTI R17 and H40 of the variant. All together, these data suggest that positions 39 and 60 are key for inhibitor binding to trypsin, and likely more trypsin-fold proteases.

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A new method to prepare the cross-linked enzyme aggregates (CLEAs) was developed. Through cross-linking the enzyme (Trypsin) aggregates, which was precipitated from the CO2-expanded reverse micellar solutions, dendritic CLEAs were obtained. The sizes of the CLEAs prepared by this new method were nanometer order of magnitudes and could be tuned by changing the water-to-surfactant ratio (w0) and the concentration of enzyme in the reverse micellar solution. The diameter of CLEAs increased with increasing w0 value of reverse micelles and the concentration of Trypsin. The activity of CLEAs obtained by this method is improved in contrast to those obtained by the conventional method. This method has some advantages in applications and can be easily applied to the synthesis of other cross-linked enzyme aggregates.

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The polysaccharide O-carboxymethyl-poly-beta-cyclodextrin was synthesized (molecular mass 13,000 Da, 40% carboxy groups) and attached to the surface of bovine pancreatic trypsin. The resulting neoglycoenzyme retained high proteolytic and esterolytic activity and contained approx. 1.0 mol of polymer/mol of enzyme. The optimum temperature for trypsin activity was increased by 10 degrees C after this transformation. Thermostability of the polymer-enzyme complex was increased by about 14 degrees C over 10 min incubation. The conjugate was also more resistant to thermal inactivation at different temperatures, ranging from 45 to 60 degrees C, demonstrating the influence of supramolecular and polymer-protein electrostatic interactions on trypsin thermostabilization. Additionally, the conjugate was 36-fold more resistant to the action of the anionic surfactant SDS. This modification also protected the enzyme from autolysis at alkaline pH.

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Dextran modified with the mono-6-pentylene-diamino-6-deoxy-beta-cyclodextrin derivative was evaluated as a thermoprotectant additive for trypsin. The optimum temperature for trypsin activity was increased by 7 degrees C in the presence of this polymer. The enzyme thermostability was increased from 48.5 to 64 degrees C over 10 min of incubation, and the activation free energy of thermoinactivation at 50 degrees C was increased by 4.1 kJ/mol in the presence of the additive. Trypsin was 6-fold more resistant to autolytic inactivation at alkaline pH in the presence of the polymer.

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Selective incorporation of non-natural amino acid residues into proteins is a powerful approach to delineate structure-function relationships. Although many methodologies are available for chemistry-based protein engineering, more facile methods are needed to make this approach suitable for routine laboratory practice. Here, we describe a new strategy and provide a proof of concept for engineering semi-synthetic proteins. We chose a serine protease Streptomyces griseus trypsin (SGT) for this study to show that it is possible to efficiently couple a synthetic peptide containing a catalytically critical residue to a recombinant fragment containing the other active site residues. The 223-residue hybrid SGT molecule was prepared by fusing a chemically synthesized N-terminal peptide to a large C-terminal fragment of recombinant origin using native chemical ligation. This C-terminal polypeptide was produced from full-length SGT by cyanogen bromide cleavage at a genetically engineered Met57 position. This semi-synthetic hybrid trypsin is fully active, showing kinetics identical to the wild-type enzyme. Thus, we believe that it is an ideal model enzyme for studying the catalytic mechanisms of serine proteases by providing a straightforward approach to incorporate non-natural amino acids in the N-terminal region of the protein. In particular, this strategy will allow for replacement of the catalytic His57 residue and the buried N-terminus, which is thought to help align the active site, with synthetic analogs. Our approach relies on readily available recombinant proteins and small synthetic peptides, thus having general applications in chemical engineering of large proteins where the N-terminal region is the focal interest.

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Bovine pancreatic trypsin was chemically modified by a beta-cyclodextrin-carboxymethylcellulose polymer using 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide as coupling agent. The conjugate retained 110% and 95% of the initial esterolytic and proteolytic activity, respectively, and contained about 2 mol of polymer per mol of trypsin. The optimum temperature for trypsin was increased to 8 degrees C after conjugation. The thermostability of the enzyme was increased to about 16 degrees C after modification. The conjugate prepared was also more stable against thermal incubation at different temperatures ranging from 45 degrees C to 60 degrees C. In comparison with native trypsin, the polymer-enzyme complex was more resistant to autolytic degradation at pH 9.0, retaining about 65% of the initial activity after 3h incubation. In addition, modification protected trypsin against denaturation in the presence of sodium dodecylsulfate.

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Bovine pancreatic trypsin was modified by the mono-6-amino-6-deoxy derivatives of alpha-, beta-, and gamma-cyclodextrin through a transglutaminase-catalyzed reaction. The trypsin-cyclodextrin conjugates, containing about 3 mol of oligosaccharide per mole of protein, were tested for their catalytic and stability properties. The specific esterolytic activity and the kinetics constants of trypsin were significantly improved following the transglutaminase-induced structural modifications. Trypsin-cyclodextrin conjugates were also found markedly (sixfold) more resistant to autolytic degradation at alkaline pH, and their thermal stability profile was improved by about 16 degrees C. Moreover, they were particularly resistant to heat inactivation when treated at different temperatures ranging from 45 degrees C to 70 degrees C for different periods of time.

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The serine protease trypsin was converted into a site-specific protease which hydrolyzes peptides between dibasic residues. Trypsin exhibits a high S1 specificity for Arg and Lys residues. However, the S1' specificity of trypsin is very broad, with only a slight preference for hydrophobic residues in P1'. We replaced Lys60 with Glu and Asp to introduce a high specificity for basic residues into the S1' site of trypsin. Both mutations cause a dramatic increase in the S1' specificity for Arg and Lys as measured by acyl transfer reactions. In K60E, the preference for Arg increases 70-fold while the preference for P1'-Lys increases 12-fold. In contrast, the preferences for other P1' residues either decrease slightly or remain the same. Thus, K60E prefers P1'-Arg over most other P1' residues by 2 orders of magnitude. Similar results are obtained when P1' specificity is measured in peptide cleavage assays. K60D exhibits an S1' specificity profile very similar to that of K60E, although the P1'-Arg preference is reduced by a factor of 2.5. Molecular modeling studies suggest that the high S1' specificity for Arg in K60E may be due to the formation of a salt bridge between Glu60 and the P1'-Arg of the substrate.

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Two 29-residue peptides were prepared, one of which (ChPepz) was designed by surface-simulation synthesis to mimic the active site of alpha-chymotrypsin, and the other (TrPepz), which contained four substitutions relative to ChPepz, was fashioned after the active site of trypsin. Each peptide was cyclized by a disulfide bond. The ChPepz monomer effected hydrolysis of the ester group in N-benzoyl-L-tyrosine ethyl ester, an alpha-chymotrypsin substrate, with Km and kcat values that were comparable to those of alpha-chymotrypsin. ChPepz was completely inactivated by diisopropyl fluorophosphate (DIFP), L-1-p-tosylamino-2-phenylethyl chloromethyl ketone (TPCK), or reduction of the disulfide bond. It had no catalytic activity on N-tosyl-L-arginine methyl ester, a trypsin substrate. On the other hand, TrPepz, which had no effect on N-benzoyl-L-tyrosine ethyl ester, hydrolyzed N-tosyl-L-arginine methyl ester with a Km value that was essentially identical to that of trypsin, but its kcat value was almost half that of trypsin. TrPepz was fully inactivated by reduction of the disulfide bond, by DIFP, or by phenylmethylsulfonyl fluoride but not by TPCK. It was also completely inhibited by soybean trypsin inhibitor, bovine pancreatic trypsin inhibitor, and human alpha 1-antitrypsin. ChPepz and TrPepz hydrolyzed proteins (myoglobin and casein) to give panels of peptides that were similar to those of the same protein obtained with the respective enzyme. However, TrPepz was more efficient than trypsin at hydrolyzing the C bonds of two or more consecutive lysine and/or arginine residues. Like its esterase activity, the proteolytic activity of ChPepz was inhibited by either DIFP or TPCK whereas that of TrPepz was inhibited by either DIFP or phenylmethylsulfonyl fluoride but not by TPCK. Finally, ChPepz and TrPepz were each more active at low temperature than the respective enzyme. This ability to construct fully functional peptide enzymes (pepzymes) of chosen specificities should find many practical applications.

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By repeated treatments of trypsin with phenylmethylsulfonyl fluoride (PMSF), followed by base elimination of PMS from the PMS-trypsin, a catalytically inactive anhydrotrypsin preparation of low (less than 1%) active trypsin content was obtained. Inactive material was removed by affinity chromatography on trypsin inhibitor-Sepharose 4B and the purified anhydrotrypsin with full binding capacity for trypsin inhibitors was coupled to cyanogen bromide-activated Sepharose 4B. When used below its maximum capacity for trypsin inhibitors the anhydrotrypsin-Sepharose-4B affinity column absorbed both classes of inhibitors present in soybean. When overloaded, the Kunitz type was bound preferentially. Based on this observation, conditions for the partial separation of the two types of inhibitors were worked out.

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Trypsin modified by dextran preactivated with 2-amino-4,6-dichloro-1,3,5-triazine or ethyl chloroformate has been prepared. Properties of the resulting conjugates with respect to hydrolysis of synthetic substrates--methyl ester benzoyl L-arginine and n-nitrophenyl ester of n'-guanidine benzoic acid as well as high molecular weight substrates--casein and fibrin--have been studied. Stability of conjugates during autolysis and irreversible heat denaturation has been investigated.

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