Utility of standard pharmacopeial and nonpharmacopeial methods in distinguishing folded, unfolded, and process variant forms of interferon α-2.

Standard pharmacopeial test methods for biologics broadly focus on identity (active substance and impurities) and function (activity and toxicity). However, it is less clear which, if any, of the methods can identify a subtle change in protein therapeutics such as misfolding, unusual product-related impurities, or sequence or folding variants that may result from differences in manufacturing processes. In this study, we test the ability of standard pharmacopeia monograph methods and other common physicochemical methods (including circular dichroism spectropolarimetry, fluorescence spectroscopy, thermal denaturation, mass spectrometry, and capillary electrophoresis) to differentiate folding variants [purposely denatured interferon (IFN) α-2] and sequence variants (deliberately truncated, or truncated and chemically modified) from the IFN α-2 reference standards. The results show that the standard pharmacopeial methods are of limited utility in detecting alterations in protein structure, even when those alterations include changes in primary structure. None of the pharmacopeial methods were clear probes of higher order structure. The nonpharmacopeial methods were somewhat more successful but not a single method was able to distinguish all variants tested from the authentic standard. Taken together, the data underscore the requirement to use several different and complementary methods and stress conditions to assess primary and higher order structure when assessing the comparability in potential biosimilar protein products.

Identification of N- and C-terminal residues involved in MAP kinase phosphatase 3 (MKP3) interdomain binding and auto-inhibition.

Interdomain binding has been shown to play an important role in the regulation of MAP kinase phosphatase 3 (MKP3), a phosphatase involved in control of ERK signalling pathways. In this study the residues in N- and C-terminal domains responsible for MKP3 interdomain binding are identified. Peptides from the N-terminal substrate-binding domain of MKP3 were assessed for their ability to bind the C-terminal catalytic domain using surface plasmon resonance. The data indicate that the residues 77-97 (the Post-KIM peptide) in the MKP3 N-terminal domain are responsible for its binding to the C-terminal catalytic domain. Residues in the C-terminal domain that might be important to interdomain binding were identified using data in the existing literature. Variants in which these residues had been altered were examined by circular dichroism and enzymatic assays to ensure retention of their structure and catalytic properties before being assessed for their ability to bind the Post-KIM peptide. The data show that glutamic acid 248, asparagine 267 and, to a lesser extent, arginine 299 are important for the interaction between the MKP3 C-terminal and the N-terminal domains. The identified residues map to a region on the surface of the C-terminal domain that appears complementary to the N-terminal domain surface defined by the Post-KIM peptide. This interdomain binding site is distinct from the substrate interaction sites.

Inhibition of mitogen-activated protein kinase phosphatase 3 activity by interdomain binding.

Mitogen-activated protein (MAP) kinase phosphatase 3 (MKP3) is a cytoplasmic dual specificity phosphatase that functions to attenuate signaling via dephosphorylation and subsequent deactivation of its substrate and allosteric regulator, extracellular signal-regulated protein kinase 2 (ERK2). Expression of MKP3 has been shown to be under the control of ERK2, thus providing an elegant feedback mechanism for regulating the rate and duration of proliferative signals. Previously published studies suggest that MKP3 might serve as a tumor suppressor; however, significantly elevated, rather than reduced, levels of this protein have been reported in early lesions. Because overexpression of this phosphatase is counterintuitive to a proposed tumor suppressor function, the observed cellular tolerance suggested a self-inactivation mechanism. Using surface plasmon resonance, we have provided direct evidence of physical interaction between the N- and C-terminal domains. Kinetic analysis using dimethyl sulfoxide to activate the C-terminal fragment in the absence of ERK2 showed that the isolated C-terminal domain had higher catalytic efficiency than the similarly activated full-length protein. Furthermore, when the isolated N-terminal domain was added to the activated C-terminal domain, a dose-dependant inhibition of catalytic activity was observed. The similarity between the K(I) and K(D) values obtained indicate that interdomain binding stabilizes the inactive conformation of the catalytic site and implies that the N-terminal domain functions as an allosteric inhibitor of phosphatase activity. Finally, we have provided evidence for oligomerization of MKP3 in pancreatic cancer cells expressing elevated levels of this phosphatase.

Over-expression and refolding of MAP kinase phosphatase 3.

MAP kinase phosphatase 3 (MKP3, also known as DUSP6 and PYST1) is involved in extracellular signal receptor kinase (ERK) regulation and functions as a specific phosphatase to the activated (phosphorylated) forms of ERK1 and ERK2. MKP3 displays allosteric activation, which aids in tightly regulating its function to ERK substrates, but not other related MAPKs. Due to MKP3's specificity for the ERK signaling pathway, the development of specific activators or inhibitors to the enzyme have been suggested in order to expressly influence the ERK1 and ERK2 pathways. To produce the high yields of MKP3 protein necessary for physico-chemical characterization of MKP3 and for high throughput screening of its small-molecule activators and inhibitors, we have cloned, purified and, and identified refolding conditions suitable for producing full-length, human MKP3 from Escherichia coli inclusion bodies. Furthermore, we demonstrate the use of a 96-well plate format refolding assay in which the ERK-induced activity of MKP3 is simulated by 33% DMSO. The assay allowed for rapid detection of MKP3's function following a refolding screen in the absence of ERK and thus provides quick and inexpensive testing of MKP3 activity. Following screening, the refolded product was confirmed to be correctly folded by steady-state kinetic analysis and by the CD spectroscopy-determined secondary structure content. CD data were consistent with 36% helix and 14% sheet, which compared to an expected 32.9% helix and 12.4% sheet. These data indicated that MKP3 was properly folded, making it a suitable protein for use in functional studies.