Large-Scale Biophysical Evaluation of Protein PEGylation Effects: In Vitro Properties of 61 Protein Entities.

PEGylation is the most widely used method to chemically modify protein biopharmaceuticals, but surprisingly limited public data is available on the biophysical effects of protein PEGylation. Here we report the first large-scale study, with site-specific mono-PEGylation of 15 different proteins and characterization of 61 entities in total using a common set of analytical methods. Predictions of molecular size were typically accurate in comparison with actual size determined by size-exclusion chromatography (SEC) or dynamic light scattering (DLS). In contrast, there was no universal trend regarding the effect of PEGylation on the thermal stability of a protein based on data generated by circular dichroism (CD), differential scanning calorimetry (DSC), or differential scanning fluorimetry (DSF). In addition, DSF was validated as a fast and inexpensive screening method for thermal unfolding studies of PEGylated proteins. Multivariate data analysis revealed clear trends in biophysical properties upon PEGylation for a subset of proteins, although no universal trends were found. Taken together, these findings are important in the consideration of biophysical methods and evaluation of second-generation biopharmaceutical drug candidates.

The 'pair of sugar tongs' site on the non-catalytic domain C of barley alpha-amylase participates in substrate binding and activity.

Some starch-degrading enzymes accommodate carbohydrates at sites situated at a certain distance from the active site. In the crystal structure of barley alpha-amylase 1, oligosaccharide is thus bound to the 'sugar tongs' site. This site on the non-catalytic domain C in the C-terminal part of the molecule contains a key residue, Tyr380, which has numerous contacts with the oligosaccharide. The mutant enzymes Y380A and Y380M failed to bind to beta-cyclodextrin-Sepharose, a starch-mimic resin used for alpha-amylase affinity purification. The K(d) for beta-cyclodextrin binding to Y380A and Y380M was 1.4 mm compared to 0.20-0.25 mm for the wild-type, S378P and S378T enzymes. The substitution in the S378P enzyme mimics Pro376 in the barley alpha-amylase 2 isozyme, which in spite of its conserved Tyr378 did not bind oligosaccharide at the 'sugar tongs' in the structure. Crystal structures of both wild-type and S378P enzymes, but not the Y380A enzyme, showed binding of the pseudotetrasaccharide acarbose at the 'sugar tongs' site. The 'sugar tongs' site also contributed importantly to the adsorption to starch granules, as Kd = 0.47 mg.mL(-1) for the wild-type enzyme increased to 5.9 mg.mL(-1) for Y380A, which moreover catalyzed the release of soluble oligosaccharides from starch granules with only 10% of the wild-type activity. beta-cyclodextrin both inhibited binding to and suppressed activity on starch granules for wild-type and S378P enzymes, but did not affect these properties of Y380A, reflecting the functional role of Tyr380. In addition, the Y380A enzyme hydrolyzed amylose with reduced multiple attack, emphasizing that the 'sugar tongs' participates in multivalent binding of polysaccharide substrates.

Biased mutagenesis in the N-terminal region by degenerate oligonucleotide gene shuffling enhances secretory expression of barley alpha-amylase 2 in yeast.

Recombinant barley alpha-amylase 1 (rAMY1) and 2 (rAMY2), despite 80% sequence identity, are produced in very different amounts of 1.1 and <0.05 mg/l, respectively, by Saccharomyces cerevisiae strain S150-2B. The low yield of AMY2 practically excludes mutational analysis of structure-function relationships and protein engineering. Since different secretion levels of AMY1/AMY2 chimeras were previously ascribed to the N-terminal sequence, AMY1 residues were combinatorially introduced at the 10 non-conserved positions in His14-Gln49 of AMY2 using degenerate oligonucleotide gene shuffling (DOGS) coupled with homologous recombination in S.cerevisiae strain INVSc1. Activity screening of a partial library of 843 clones selected six having a large halo size on starch plates. Three mutants, F21M/Q44H, A42P/A47S and A42P rAMY2, also gave higher activity than wild-type in liquid culture. Only A42P showed wild-type stability and enzymatic properties. The replacement is located to a beta-->alpha loop 2 that interacts with domain B (beta-->alpha loop 3) protruding from the catalytic (beta/alpha)(8)-barrel. Most remarkably Pichia pastoris strain GS115 secreted 60 mg/l A42P compared with 3 mg/l of wild-type rAMY2. The crystal structure of A42P rAMY2 was solved and found to differ marginally from the AMY2 structure, suggesting that the high A42P yield stems from stabilization of the mature and/or intermediate form owing to the introduced proline residue. Moreover, the G to C substitution for the A42P mutation might have a positive impact on protein translation.

Self-association of long-acting insulin analogues studied by size exclusion chromatography coupled to multi-angle light scattering.

Two structurally very different insulin analogues analysed here, belong to a class of analogues of which two have been reported to have a protracted action through self-assembly to high molar mass in subcutis. The process of self-association of insulin analogues Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin and Lys(B29) (N(ε)-lithocholyl) des(B30) human insulin was investigated using size exclusion chromatography (SEC) in connection with multi-angle light-scattering. Self-assembly to high molar mass was obtained by exchanging the formulation containing phenolic preservatives with an isotonic eluent during SEC. It was shown that increasing amounts of zinc in the formulations of the two analogues increased the size of the self assemblies formed during gel filtration. The addition of 0.2 mM phenol to the elution buffer slowed down the self-association process of zinc containing formulations and shed light on the initial association process. The results indicated that a dihexamer is a possible building block during self-association of Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin. Surprisingly, in the absence of zinc the two analogues behaved very differently. Lys(B29) (N(ε)ω-carboxyheptadecanoyl) des(B30) human insulin was in equilibrium between oligomers smaller than a hexamer, whereas Lys(B29) (N(ε)-lithocholyl) des(B30) human insulin self-associated and formed even larger complexes than in the presence of zinc.

Structural and biochemical studies elucidate the mechanism of rhamnogalacturonan lyase from Aspergillus aculeatus.

We present here the first experimental evidence for bound substrate in the active site of a rhamnogalacturonan lyase belonging to family 4 of polysaccharide lyases, Aspergillus aculeatus rhamnogalacturonan lyase (RGL4). RGL4 is involved in the degradation of rhamnogalacturonan-I, an important pectic plant cell wall polysaccharide. Based on the previously determined wild-type structure, enzyme variants RGL4_H210A and RGL4_K150A have been produced and characterized both kinetically and structurally, showing that His210 and Lys150 are key active-site residues. Crystals of the RGL4_K150A variant soaked with a rhamnogalacturonan digest gave a clear picture of substrate bound in the -3/+3 subsites. The crystallographic and kinetic studies on RGL4, and structural and sequence comparison to other enzymes in the same and other PL families, enable us to propose a detailed reaction mechanism for the ß-elimination on [-,2)-α-l-rhamno-(1,4)-α-d-galacturonic acid-(1,-]. The mechanism differs significantly from the one established for pectate lyases, in which most often calcium ions are engaged in catalysis.

Crystal structure of the covalent intermediate of amylosucrase from Neisseria polysaccharea.

The alpha-retaining amylosucrase from the glycoside hydrolase family 13 performs a transfer reaction of a glucosyl moiety from sucrose to an acceptor molecule. Amylosucrase has previously been shown to be able to use alpha-D-glucopyranosyl fluoride as a substrate, which suggested that it could also be used for trapping the reaction intermediate for crystallographic studies. In this paper, the crystal structure of the acid/base catalyst mutant, E328Q, with a covalently bound glucopyranosyl moiety is presented. Sucrose cocrystallized crystals were soaked with alpha-D-glucopyranosyl fluoride, which resulted in the trapping of a covalent intermediate in the active site of the enzyme. The structure is refined to a resolution of 2.2 A and showed that binding of the covalent intermediate resulted in a backbone movement of 1 A around the location of the nucleophile, Asp286. This structure reveals the first covalent intermediate of an alpha-retaining glycoside hydrolase where the glucosyl moiety is identical to the expected biologically relevant entity. Comparison to other enzymes with anticipated glucosylic covalent intermediates suggests that this structure is a representative model for such intermediates. Analysis of the active site shows how oligosaccharide binding disrupts the putative nucleophilic water binding site found in the hydrolases of the GH family 13. This reveals important parts of the structural background for the shift in function from hydrolase to transglycosidase seen in amylosucrase.