Disulfide-bridging PEGylation during refolding for the more efficient production of modified proteins.

Proteins that are modified by chemical conjugation require at least two separate purification processes. First the bulk protein is purified, and then after chemical conjugation, a second purification process is required to obtain the modified protein. In an effort to develop new enabling technologies to integrate bioprocessing and protein modification, we describe the use of disulfide-bridging conjugation to conduct PEGylation during protein refolding. Preliminary experiments using a PEG-mono-sulfone reagent with partially unfolded leptin and unfolded RNAse T1 indicated that the cysteine thiols underwent disulfide-bridging conjugation to give the PEGylated proteins. Interferon-ß1b (IFN-ß1b) was then expressed in E.coli as inclusion bodies and found to undergo disulfide bridging-conjugation during refolding. The PEG-IFN-ß1b was isolated by ion-exchange chromatography and displayed in vitro biological activity. In the absence of the PEGylation reagent, IFN-ß1b refolding was less efficient and yielded protein aggregates. No PEGylation was observed if the cysteines on IFN-ß1b were first modified with iodoacetamide prior to refolding. Our results demonstrate that the simultaneous refolding and disulfide bridging PEGylation of proteins could be a useful strategy in the development of affordable modified protein therapeutics.

Development of enzyme technology for Aspergillus oryzae, A. sojae, and A. luchuensis, the national microorganisms of Japan.

This paper describes the modern enzymology in Japanese bioindustries. The invention of Takadiastase by Jokiti Takamine in 1894 has revolutionized the world of industrial enzyme production by fermentation. In 1949, a new γ-amylase (glucan 1,4-α-glucosidase, EC 3.2.1.3) from A. luchuensis (formerly designated as A. awamori), was found by Kitahara. RNase T1 (guanyloribonuclease, EC 3.1.27.3) was discovered by Sato and Egami. Ando discovered Aspergillus nuclease S1 (single-stranded nucleate endonuclease, EC 3.1.30.1). Aspergillopepsin I (EC 3.4.23.18) from A. tubingensis (formerly designated as A. saitoi) activates trypsinogen to trypsin. Shintani et al. demonstrated Asp76 of aspergillopepsin I as the binding site for the basic substrate, trypsinogen. The new oligosaccharide moieties Man10GlcNAc2 and Man11GlcNAc2 were identified with α-1,2-mannosidase (EC 3.2.1.113) from A. tubingensis. A yeast mutant compatible of producing Man5GlcNAc2 human compatible sugar chains on glycoproteins was constructed. The acid activation of protyrosinase from A. oryzae at pH 3.0 was resolved. The hyper-protein production system of glucoamylase was established in a submerged culture.

X-ray crystallographic structure of RNase Po1 that exhibits anti-tumor activity.

RNase Po1 is a guanylic acid-specific ribonuclease member of the RNase T1 family from Pleurotus ostreatus. We previously reported that RNase Po1 inhibits the proliferation of human tumor cells, yet RNase T1 and other T1 family RNases are non-toxic. We determined the three-dimensional X-ray structure of RNase Po1 and compared it with that of RNase T1. The catalytic sites are conserved. However, there are three disulfide bonds, one more than in RNase T1. One of the additional disulfide bond is in the catalytic and binding site of RNase Po1, and makes RNase Po1 more stable than RNase T1. A comparison of the electrostatic potential of the molecular surfaces of these two proteins shows that RNase T1 is anionic whereas RNase Po1 is cationic, so RNase Po1 might bind to the plasma membrane electrostatically. We suggest that the structural stability and cationic character of RNase Po1 are critical to the anti-cancer properties of the protein.

Minimizing 18O/16O back-exchange in the relative quantification of ribonucleic acids.

The use of isotopically labeled endonuclease digestion products allows for the relative quantification of ribonucleic acids (RNAs). This approach utilizes ribonucleases such as RNase T1 to mediate the incorporation of 18O onto the 3'-terminus of the endonuclease digestion product from a solution containing heavy water (H2 18O). The accuracy and precision of relative quantification are dependent on the efficiency of isotope incorporation and minimizing any possible 18O to 16O back-exchange before or during mass spectral analysis. Here, we have investigated the stability of 18O-labeled endonuclease digestion products to back-exchange. In particular, the effects of pH, temperature and presence of RNase on the back-exchange process were examined using matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). We have found that back-exchange depends on the presence of the RNase--back-exchange was not observed once the enzyme was removed from the sample. With RNase present, at all pH values examined (from acidic to basic pH), back-exchange was detected at incubation above room temperature. The rates and extent of back-exchange were similar at all pH values. In contrast, back-exchange in the presence of RNase was found to be especially sensitive to incubation temperature--at temperatures below room temperature, minimal back-exchange was detected. However, back-exchange increased as the incubation temperature increased. Based on these findings, appropriate sample-handling and sample storage conditions for isotopically labeled endonuclease digestion products have been identified, and these conditions should improve the accuracy and precision of results from the relative quantification of RNAs obtained by this approach.

Addressing the challenge of changing the specificity of RNase T1 with rational and evolutionary approaches.

Although ribonuclease T1 (RNase T1) is one of the best-characterized proteins with respect to structure and enzymatic action, numerous attempts at altering the specificity of the enzyme to cleave single-stranded RNA at the 3'-side of adenylic instead of guanylic residues by rational approaches have failed so far. Recently we generated and characterized the RNase T1 variant RV with a 7200-fold increase in adenylyl-3',5'-cytidine (ApC)/guanylyl-3',5'-cytidine (GpC) preference, with the guanine-binding loop changed from 41-KYNNYE-46 (wt) to 41-EFRNWN-46. Now we have introduced the asparagine residue at position 46 of the wild-type enzyme as a single-point mutation in variant E46N and in combination with the Y45W exchange also occurring in RV. Both variants show an improved ApC/GpC preference with a 1450-fold increase for E46N and a 2100-fold increase for Y45W/E46N in comparison to wild-type activity. We also addressed the challenge of altering enzyme specificity with an evolutionary approach. We have randomly introduced point mutations into the RNase T1 wild-type gene and into the gene of the variant RV with different mutation rates. Altogether we have screened about 100,000 individual clones for activity on RNase indicator plates; 533 of these clones were active. A significant change in substrate specificity towards an ApC preference could not be observed for any of these active variants; this demonstrated the magnitude of the challenge to alter the specificity of this evolutionary perfected enzyme.

Probing functional perfection in substructures of ribonuclease T1: double combinatorial random mutagenesis involving Asn43, Asn44, and Glu46 in the guanine binding loop.

Combinatorial random mutageneses involving either Asn43 with Asn44 (set 1) or Glu46 with an adjacent insertion (set 2) were undertaken to explore the functional perfection of the guanine recognition loop of ribonuclease T(1) (RNase T(1)). Four hundred unique recombinants were screened in each set for their ability to enhance enzyme catalysis of RNA cleavage. After a thorough selection procedure, only six variants were found that were either as active or more active than wild type which included substitutions of Asn43 by Gly, His, Leu, or Thr, an unplanned Tyr45Ser substitution and Glu46Pro with an adjacent Glu47 insertion. Asn43His-RNase T(1) has the same loop sequence as that for RNases Pb(1) and Fl(2). None of the most active mutants were single substitutions at Asn44 or double substitutions at Asn43 and Asn44. A total of 13 variants were purified, and these were subjected to kinetic analysis using RNA, GpC, and ApC as substrates. Modestly enhanced activities with GpC and RNA involved both k(cat) and K(M) effects. Mutants having low activity with GpC had proportionately even lower relative activity with RNA. Asn43Gly-RNase T(1) and all five of the purified mutants in set 2 exhibited similar values of k(cat)/K(M) for ApC which were the highest observed and about 10-fold that for wild type. The specificity ratio [(k(cat)/K(M))(GpC)/(k(cat)/K(M))(ApC)] varied over 30 000-fold including a 10-fold increase [Asn43His variant; mainly due to a low (k(cat)/K(M))(ApC)] and a 3000-fold decrease (Glu46Ser/(insert)Gly47 variant; mainly due to a low (k(cat)/K(M))(GpC)) as compared with wild type. It is interesting that k(cat) (GpC) for the Tyr45Ser variant was almost 4-fold greater than for wild type and that Pro46/(insert)Glu47 RNase T(1) is 70-fold more active than the permuted variant (insert)Pro47-RNase T(1) which has a conserved Glu46. In any event, the observation that only 6 out of 800 variants surveyed had wild-type activity supports the view that functional perfection of the guanine recognition loop of RNase T(1) has been achieved.

Conformation of thermally denatured RNase T1 with intact disulfide bonds: a study by small-angle X-ray scattering.

Small-angle X-ray scattering of RNase T1 with intact disulfide bonds was measured at 20 degrees and 60 degrees C in order to get insight into the structural changes of the protein caused by thermal denaturation. The radius of gyration increases from R(G)= 1.43 nm to R(G) = 2.21 nm. The conformations of the molecules at 60 degrees C are similar to those of ring-shaped random walk chains. However, the molecules are more compact than one would expect under theta conditions due to attractive interactions between the chain segments. The volume needed for free rotation of the thermally unfolded protein molecules about any axis in solution is five times greater than in the native state whereas the hydrodynamic effective volume is increasing only two times.

Influence of primary sequence transpositions on the folding pathways of ribonuclease T1.

The slow folding of circularly permuted variants of ribonuclease T1 has been examined using steady-state and frequency-domain fluorescence spectroscopy. The sequence transpositions have previously been designed by eliminating a restrictive Cys2-Cys10 disulfide bond, adjoining the original termini with a three-peptide Gly-Gly-Gly linker, and conferring new termini to four different solvent-exposed beta-turns interposing secondary structural elements [Garrett, J. B., Mullins, L. S., & Raushel, F. M. (1996) Protein Sci. 5, 204-211]. Each of the mutant proteins continues to be rate-limited in folding by the slow trans to cis isomerizations of Pro39 and Pro55, giving rise to a branched mechanism populated by intermediates with mixed proline isomers. However, the overall rate of folding is increased in accordance with the general destabilizing effect of each circular permutation. Steric hindrances imposed by Trp59 on the isomerization around the Tyr38-Pro39 peptide bond have been implicated in decelerating the folding of RNase T1 [Kiefhaber, T., Grunert, H.-P., Hahn, U., & Schmid, F. X. (1992) Proteins: Struct., Funct., Genet. 12, 171-179]; it is this tertiary restraint which appears to be variably relieved by the sequence transpositions. A fluorescence characterization of Trp59 indicates little difference between fully folded RNase T1 and the variants in terms of its lifetime, accessibility to quenchers, and rotational properties. Yet, within protein that is "completely" denatured, Trp59 exhibits variable flexibility, greatest within the circularly permuted variants folding the fastest. Such differences in the dynamic properties of Trp59 between each denatured protein may be direct evidence for a relative loosening of the tertiary fold maintaining the "deleterious" Trp59-Pro39 interaction in the partially folded intermediates.

DsbA-mediated disulfide bond formation and catalyzed prolyl isomerization in oxidative protein folding.

The interrelationship between the acquisition of ordered structure, prolyl isomerization, and the formation of the disulfide bonds in assisted protein folding was investigated by using a variant of ribonuclease T1 (C2S/C10N-RNase T1) with a single disulfide bond and two cis-prolyl bonds as a model protein. The thiol-disulfide oxidoreductase DsbA served as the oxidant for forming the disulfide bond and prolyl isomerase A as the catalyst of prolyl isomerization. Both enzymes are from the periplasm of Escherichia coli. Reduced C2S/C10N-RNase T1 is unfolded in 0 M NaCl, but native-like folded in > or = 2 M NaCl. Oxidation of 5 microM C2S/C10N-RNase T1 by 8 microM DsbA (at pH 7.0, 25 degrees C) is very rapid with a t1/2 of about 10 s (the second-order rate constant is 7 x 10(3) s-1 M-1), irrespective of whether the reduced molecules are unfolded or folded. When they are folded, the product of oxidation is the native protein. When they are denatured, first the disulfide bond is formed in the unfolded protein chains and then the native structure is acquired. This slow reaction is limited in rate by prolyl isomerization and catalyzed by prolyl isomerase. The efficiency of this catalysis is strongly decreased by the presence of the disulfide bond. Apparently, the rank order of chain folding, prolyl isomerization, and disulfide bond formation can vary in the oxidative folding of ribonuclease T1. Such a degeneracy could generally be an advantage for protein folding both in vitro and in vivo.

Purification and primary structure of a new guanylic acid specific ribonuclease from Pleurotus ostreatus.

A guanine nucleotide-specific RNase (RNase Po1) was isolated from caps of the fruit bodies of Pleurotus ostreatus. RNase Po1 is most active towards RNA at pH 8.0. The effect of heating on the molar ellipticity at 210 nm of RNase Po1 showed that RNase Po1 is more stable than RNase T1. The primary structure of RNase Po1 was determined to be < ETGVRSCNCAGRSFTGTDVTNAIRSARAGGSGNYPHVYNNFEGFSFSCTPTFFEFPVFRGSVYSGGSPG ADRVIYD- QSGRFCACLTHTGAPSTNGFVECRF. It consisted of 101 amino acid residues, with a molecular weight of 10,760. RNase Po1 has relatively higher sequence homology with RNase T1 family RNase. It contains 6 half cystine residues. The locations of four of them are superimposable on those of RNase U1 and RNase U2. The amino acid residues forming the active site of RNase T1 were well conserved in this RNase. Therefore, RNase Po1 is a unique member of the RNase T1 family in respect of the location of one disulfide bridge, and its stability.

Preparation and properties of RNase T1 immobilized on aminoethyl Bio-Gel P-2.

The partially purified RNase T1, when coupled to glutaraldehyde activated aminoethyl Bio-Gel P-2, retained 22-24% activity of the soluble enzyme. Immobilization resulted in an increase in the optimum temperature and temperature stability, but it did not affect the pH optimum. Km and Vmax decreased as a result of immobilization. The bound enzyme showed high stability to repeated use and storage.

A purification method for labile variants of ribonuclease T1.

We present a new procedure for the rapid production of ribonuclease T1 variants with decreased stability which could not be purified in satisfying amounts by the existing methods. The major changes from the established procedures are the following. (i) The cells were grown at 28 degrees C rather than at 37 degrees C. (ii) The entire purification was performed at low temperatures (4 degrees C). (iii) Materials for chromatography with high flow rates were used to accelerate protein isolation. (iv) The pH was lowered from 7.5 to 6.0, a condition under which RNase T1 is much more stable. The use of this improved procedure allowed the purification of the labile P39G and P73V variants of RNase T1. By the same technique 300 mg of the wild-type protein could be isolated from 10 liters liquid culture within 3 days. The P39G and the P73V mutations strongly decrease the stability of RNase T1 and the midpoints of the reversible thermal unfolding transition are lowered by 16 and 6 degrees C, respectively, relative to that of the wild-type protein. The decrease in temperature during fermentation and the rapid purification at low temperature and under solvent conditions where the stability of the proteins is high are probably the major reasons for the dramatic increase in yield of these labile variants of RNase T1. Such an approach should be valuable for the production of recombinant proteins in general.

Isoelectric focusing by free solution capillary electrophoresis.

A reproducible, quantitative isoelectric focusing method using capillary electrophoresis that exhibits high resolution and linearity over a wide pH gradient was developed. RNase T1 and RNase ba are two proteins that have isoelectric points (pI's) at the two extremes of a pH 3-10 gradient. Site-directed mutants of the former were separated from the wild-type form and pI's determined in the same experiment. The pI's of RNase T1 wild-type, its three mutants, and RNase ba were determined for the first time as 2.9, 3.1, 3.1, 3.3, and 9.0, respectively. The paper describes the protocol for isoelectric focusing by capillary electrophoresis, as well as presenting data describing the linearity, resolution, limits of mass loading, and reproducibility of the method.

Improving purification of recombinant ribonuclease T1.

Purification of recombinant RNase T1 and its mutants has been improved by optimizing bacterial growth conditions, periplasmic fraction preparation and the use of a precolumn. The main part of the chromatographic separation could be automated due to the reproducibility of the procedure.

Studies on RNase T1 mutants affecting enzyme catalysis.

Using an Escherichia coli overproducing strain secreting Aspergillus oryzae RNase T1, we have constructed and characterized mutants where amino acid residues in the catalytic center have been substituted. The mutants are His40----Thr, Glu58----Asp, Glu58----Gln, His92----Ala and His92----Phe. His92----Ala and His92----Phe mutants are inactive. On the basis of their kcat/Km values, the mutants Glu58----Asp and Glu58----Gln show 10% and 7% residual activity, relative to wild-type RNase T1, whereas the His40----Thr mutant shows 2% activity. The effect of amino acid substitutions on the enzymatic activity of RNase T1 lends further support for a mechanism where Glu58 (possibly activated by His40 and His92 act as general base and acid respectively; this is discussed in terms of the known three-dimensional structure of the enzyme.

A guanyloribonuclease of mouse liver cytosol.

The acid RNase activity of mouse liver cytosol has been resolved into two different enzymes named acid RNase I and acid RNase II respectively. Acid RNase I is a typical pancreatic-type enzyme hydrolyzing CpN and UpN bonds. Acid RNase II, however, hydrolyzes GpN bonds in non-hydrogen-bonded regions of the substrate.

Secretion of recombinant ribonuclease T1 into the periplasmic space of Escherichia coli with the aid of the signal peptide of alkaline phosphatase.

The ribonuclease T1 (RNase T1) gene was ligated to a synthetic gene for the signal peptide of Escherichia coli alkaline phosphatase. When this fusion gene was expressed in E. coli under the control of the trp promoter, active RNase T1 having the correct N-terminal sequence was secreted into the periplasmic space, indicating that the heterologous signal peptide had been cleaved off correctly. The enzyme could be readily purified from the periplasmic fraction with a yield of 1.8 mg from 1 liter culture. Adopting the same strategy, it was possible to produce a labile mutant of RNase T1 (Glu-58----Ala mutant) in E. coli, the yield of the purified mutant enzyme being 2.0 mg from 1 liter culture.

Folding of ribonuclease T1. 1. Existence of multiple unfolded states created by proline isomerization.

It is our aim to elucidate molecular aspects of the mechanism of protein folding. We use ribonuclease T1 as a model protein, because it is a small single-domain protein with a well-defined secondary and tertiary structure, which is stable in the presence and absence of disulfide bonds. Also, an efficient mutagenesis system is available to produce protein molecules with defined sequence variations. Here we present a preliminary characterization of the folding kinetics of ribonuclease T1. Its unfolding and refolding reactions are reversible, which is shown by the quantitative recovery of the catalytic activity after an unfolding/refolding cycle. Refolding is a complex process, where native protein is formed on three distinguishable pathways. There are 3.5% fast-folding molecules, which refold within the millisecond time range, and 96.5% slow-folding species, which regain the native state in the time range of minutes to hours. These slow-folding molecules give rise to two major, parallel refolding reactions. The mixture of fast- and slow-folding molecules is produced slowly after unfolding by chain equilibration reactions that show properties of proline isomerization. We conclude that part of the kinetic complexity of RNase T1 folding can be explained on the basis of the proline model for protein folding. This is supported by the finding that the slow refolding reactions of this protein are accelerated in the presence of the enzyme prolyl isomerase. However, several properties of ribonuclease T1 refolding, such as the dependence of the relative amplitudes on the probes, used to follow folding, are not readily explained by a simple proline model.