Complete mapping of disulfide linkages for etanercept products by multi-enzyme digestion coupled with LC-MS/MS using multi-fragmentations including CID and ETD.

The disulfide linkages of two etanercept products, Enbrel® (innovator drug) and TuNEX®, were characterized and compared using a multi-fragmentation approach consisting of electron transfer dissociation (ETD) and collision induced dissociation (CID) in combination with multi-enzyme digestion protocols (from Lys-C, trypsin, Glu-C, and PNGase F). Multi-fragmentation approach allowed multi-disulfide linkages contained in a peptide to be un-ambiguously assigned based on the cleavage of both the disulfide and the backbone linkages in a MS3 schedule. New insights gained using this approach were discussed. A total of 29 disulfides, Cys18-Cys31, Cys32-Cys45, Cys35-Cys53, Cys56-Cys71, Cys74-Cys88, Cys78-Cys-96, Cys98-Cys104, Cys112-Cys121, Cys115-Cys139, Cys-142-Cys157, Cys163-Cys178 in TNFR portion and Cys240-Cys240, Cys246-Cys246, Cys249-Cys249, Cys281-Cys341, Cys387-Cys445 in IgG1 Fc domain, were completely assigned with the demonstration of the same disulfide linkages between the Enbrel® and TuNEX® products. The data showed the higher order structure was preserved throughout the recombinant manufacturing processes and consistent between the two products.

Characterization and comparability of stress-induced oxidation and deamidation on vulnerable sites of etanercept products.

An etanercept biosimilar, TuNEX(®), was compared to the innovator drug, Enbrel(®), for its reaction to stress-induced oxidation and deamidation, which may affect drug efficacy. A tryptic peptide map of both etanercept products was generated by liquid chromatography (LC) using mass spectrometry (MS) and ultraviolet (UV) spectrophotometry detection methods. The sequence of each modified or non-modified peptide peak was assigned based on accurate measurement of the mass of the protein and analysis utilizing tandem MS. Similar profiles of intrinsic oxidation on methionine (M) and deamidation on asparagine (N) were obtained for the two products, regardless of a two-amino acid (AA) residue variance in the heavy chain (Fc) between them. The level of oxidative stress exerted by tert-butyl hydroperoxide (tBHP), and alkaline stress exerted by a pH 10.4 solution, was examined using an LC-UV method. The results indicated that TuNEX(®) demonstrated a similar stress-induced modification profile compared to that of Enbrel(®). For both products, oxidative stress increased the oxidation from an intrinsically low (0-6.9%) to moderate or high (42-100%) level for almost all M residues (M30, M174, M187, M223, M272, and M448); alkaline stress increased the deamidation level of N404 from a low (0.0 or 1.7%) to moderate (19-26%) level. Based the results of a cell-based bioactivity assay, TuNEX(®) also exhibited a similar level of bioactivity as Enbrel(®) in unstressed, oxidative-stressed, or alkaline-stressed conditions. The bioactivity of both products remained unaltered by oxidative stress but was reduced by alkali stress. In conclusion, our data indicated that TuNEX(®) exhibits a similar chemical stress profile as that of Enbrel(®) in terms of oxidation and deamidation as well as bioactivity.

Structural basis of type II topoisomerase inhibition by the anticancer drug etoposide.

Type II topoisomerases (TOP2s) resolve the topological problems of DNA by transiently cleaving both strands of a DNA duplex to form a cleavage complex through which another DNA segment can be transported. Several widely prescribed anticancer drugs increase the population of TOP2 cleavage complex, which leads to TOP2-mediated chromosome DNA breakage and death of cancer cells. We present the crystal structure of a large fragment of human TOP2ß complexed to DNA and to the anticancer drug etoposide to reveal structural details of drug-induced stabilization of a cleavage complex. The interplay between the protein, the DNA, and the drug explains the structure-activity relations of etoposide derivatives and the molecular basis of drug-resistant mutations. The analysis of protein-drug interactions provides information applicable for developing an isoform-specific TOP2-targeting strategy.

Structures of prostacyclin synthase and its complexes with substrate analog and inhibitor reveal a ligand-specific heme conformation change.

Prostacyclin synthase (PGIS) is a cytochrome P450 (P450) enzyme that catalyzes production of prostacyclin from prostaglandin H(2). PGIS is unusual in that it catalyzes an isomerization rather than a monooxygenation, which is typical of P450 enzymes. To understand the structural basis for prostacyclin biosynthesis in greater detail, we have determined the crystal structures of ligand-free, inhibitor (minoxidil)-bound and substrate analog U51605-bound PGIS. These structures demonstrate a stereo-specific substrate binding and suggest features of the enzyme that facilitate isomerization. Unlike most microsomal P450s, where large substrate-induced conformational changes take place at the distal side of the heme, conformational changes in PGIS are observed at the proximal side and in the heme itself. The conserved and extensive heme propionate-protein interactions seen in all other P450s, which are largely absent in the ligand-free PGIS, are recovered upon U51605 binding accompanied by water exclusion from the active site. In contrast, when minoxidil binds, the propionate-protein interactions are not recovered and water molecules are largely retained. These findings suggest that PGIS represents a divergent evolution of the P450 family, in which a heme barrier has evolved to ensure strict binding specificity for prostaglandin H(2), leading to a radical-mediated isomerization with high product fidelity. The U51605-bound structure also provides a view of the substrate entrance and product exit channels.

Crystal structure of the human prostacyclin synthase.

Prostacyclin synthase (PGIS) catalyzes an isomerization of prostaglandin H(2) to prostacyclin, a potent mediator of vasodilation and anti-platelet aggregation. Here, we report the crystal structure of human PGIS at 2.15 A resolution, which represents the first three-dimensional structure of a class III cytochrome P450. While notable sequence divergence has been recognized between PGIS and other P450s, PGIS exhibits the typical triangular prism-shaped P450 fold with only moderate structural differences. The conserved acid-alcohol pair in the I helix of P450s is replaced by residues G286 and N287 in PGIS, but the distinctive disruption of the I helix and the presence of a nearby water channel remain conserved. The side-chain of N287 appears to be positioned to facilitate the endoperoxide bond cleavage, suggesting a functional conservation of this residue in O-O bond cleavage. A combination of bent I helix and tilted B' helix creates a channel extending from the heme distal pocket, which seemingly allows binding of various ligands; however, residue W282, placed in this channel at a distance of 8.4 A from the iron with its indole side-chain lying parallel with the porphyrin plane, may serve as a threshold to exclude most ligands from binding. Additionally, a long "meander" region protruding from the protein surface may impede electron transfer. Although the primary sequence of the PGIS cysteine ligand loop diverges significantly from the consensus, conserved tertiary structure and hydrogen bonding pattern are observed for this region. The substrate-binding model was constructed and the structural basis for prostacyclin biosynthesis is discussed.