Robert B. Mackin

Expression, purification and characterization of recombinant human proinsulin

We have recently developed a method to produce native human proinsulin using a bacterial expression system. A proinsulin fusion protein was recovered from inclusion bodies and cleaved using cyanogen bromide. The released proinsulin polypeptide was S‐sulfonated and purified by anion exchange chromatography. Following refolding, proinsulin was purified by reversed‐phase high‐performance liquid chromatography. Combined peptide mapping and mass spectrometric analysis indicated that the proinsulin contained the correct disulfide bridging pattern. This proinsulin will be used to study the specificity of the furin/PC family of converting enzymes by using it as a substrate in a recently developed assay.

Solution Structure of Proinsulin CONNECTING DOMAIN FLEXIBILITY AND PROHORMONE PROCESSING

The folding of proinsulin, the single-chain precursor of insulin, ensures native disulfide pairing in pancreatic β-cells. Mutations that impair folding cause neonatal diabetes mellitus. Although the classical structure of insulin is well established, proinsulin is refractory to crystallization. Here, we employ heteronuclear NMR spectroscopy to characterize a monomeric analogue. Proinsulin contains a native-like insulin moiety (A- and B-domains); the tethered connecting (C) domain (as probed by {1H}-15N nuclear Overhauser enhancements) is progressively less ordered. Although the BC junction is flexible, residues near the CA junction exhibit α-helical-like features. Relative to canonical α-helices, however, segmental 13Cα/β chemical shifts are attenuated, suggesting that this junction and contiguous A-chain residues are molten. We propose that flexibility at each C-domain junction facilitates prohormone processing. Studies of protease SPC3 (PC1/3) suggest that C-domain sequences contribute to cleavage site selection. The structure of proinsulin provides a foundation for studies of insulin biosynthesis and its impairment in monogenic forms of diabetes mellitus.

Crystal structure of a "nonfoldable" insulin: impaired folding efficiency despite native activity.

Protein evolution is constrained by folding efficiency (“foldability”) and the implicit threat of toxic misfolding. A model is provided by proinsulin, whose misfolding is associated with β-cell dysfunction and diabetes mellitus. An insulin analogue containing a subtle core substitution (LeuA16 → Val) is biologically active, and its crystal structure recapitulates that of the wild-type protein. As a seeming paradox, however, ValA16 blocks both insulin chain combination and the in vitro refolding of proinsulin. Disulfide pairing in mammalian cell culture is likewise inefficient, leading to misfolding, endoplasmic reticular stress, and proteosome-mediated degradation. ValA16 destabilizes the native state and so presumably perturbs a partial fold that directs initial disulfide pairing. Substitutions elsewhere in the core similarly destabilize the native state but, unlike ValA16, preserve folding efficiency. We propose that LeuA16 stabilizes nonlocal interactions between nascent α-helices in the A- and B-domains to facilitate initial pairing of CysA20 and CysB19, thus surmounting their wide separation in sequence. Although ValA16 is likely to destabilize this proto-core, its structural effects are mitigated once folding is achieved. Classical studies of insulin chain combination in vitro have illuminated the impact of off-pathway reactions on the efficiency of native disulfide pairing. The capability of a polypeptide sequence to fold within the endoplasmic reticulum may likewise be influenced by kinetic or thermodynamic partitioning among on- and off-pathway disulfide intermediates. The properties of [ValA16]insulin and [ValA16]proinsulin demonstrate that essential contributions of conserved residues to folding may be inapparent once the native state is achieved.

Synthetic Small-Molecule Prohormone Convertase 2 Inhibitors

The proprotein convertases are believed to be responsible for the proteolytic maturation of a large number of peptide hormone precursors. Although potent furin inhibitors have been identified, thus far, no small-molecule prohormone convertase 1/3 or prohormone convertase 2 (PC2) inhibitors have been described. After screening 38 small-molecule positional scanning libraries against recombinant mouse PC2, two promising chemical scaffolds were identified: bicyclic guanidines, and pyrrolidine bis-piperazines. A set of individual compounds was designed from each library and tested against PC2. Pyrrolidine bis-piperazines were irreversible, time-dependent inhibitors of PC2, exhibiting noncompetitive inhibition kinetics; the most potent inhibitor exhibited a Ki value for PC2 of 0.54 μM. In contrast, the most potent bicyclic guanidine inhibitor exhibited a Ki value of 3.3 μM. Cross-reactivity with other convertases was limited: pyrrolidine bis-piperazines exhibited Ki values greater than 25 μM for PC1/3 or furin, whereas the Ki values of bicyclic guanidines for these other convertases were more than 15 μM. We conclude that pyrrolidine bis-piperazines and bicyclic guanidines represent promising initial leads for the optimization of therapeutically active PC2 inhibitors. PC2-specific inhibitors may be useful in the pharmacological blockade of PC2-dependent cleavage events, such as glucagon production in the pancreas and ectopic peptide production in small-cell carcinoma, and to study PC2-dependent proteolytic events, such as opioid peptide production.

Expression, purification, and PC1-mediated processing of (H10D, P28K, and K29P)-human proinsulin

Our previous methods for the generation of recombinant human proinsulin were inadequate in terms of reproducibility and yield. In addition, it was difficult to perform structure/function studies on proinsulin because of its tendency to form hexamers. We have developed an improved procedure, which overcomes many of the technical purification problems, and results in a potentially monomeric version of modified proinsulin. Inclusion bodies were prepared using a commercial bacterial lysis solution. The inclusion bodies were solubilized and the fusion proteins affinity tag was removed by chemical cleavage. The polypeptide was then reduced and transferred into a refolding buffer. Following an overnight incubation, only a single form of proinsulin was detected using analytical reversed-phase high-performance liquid chromatography. The refolded (H10D, P28K, and K29P)-human proinsulin (DKP-hPI) was subjected to a final purification step using reversed-phase chromatography. The method is reproducible and produces milligram quantities of purified DKP-hPI from a single liter of bacterial culture. The final product is greater than 95% pure and is suitable for use as a substrate for the propeptide convertase PC1.

Total error profiling of a proinsulin time-resolved fluorescence immunoassay

We applied total error profiling to evaluate the conversion of a known proinsulin (PI) enzyme-linked immunosorbent assay (ELISA) into a time-resolved fluorescence immunoassay (TRFIA). The formula and acceptance criteria proposed by the Ligand Binding Assay Bioanalytical Focus Group (LBABFG) of the American Association of Pharmaceutical Scientists (AAPS) were applied. We found that the expected dynamic range enlargement with TRFIA compared to ELISA ([0.5-240] versus resp. [0.7-98] pmol/L) is limited by an interference of C-peptide when present in the sample at high concentrations (>7000 pmol/L).

Expression, purification, and PC1-mediated processing of human proglucagon, glicentin, and major proglucagon fragment

To examine the cleavage specificity of different members of the furin/propeptide convertase (PC) family of enzymes, we have selected proglucagon (PG) as a model substrate. PG was selected because it is subject to differential processing in vivo. PG is thought to be cleaved initially at an interdomain site to produce glicentin and the major proglucagon fragment (MPGF). These intermediates are subsequently cleaved, most likely by the convertases PC2 and PC1, respectively. To determine the exact sites within PG that are cleaved by PC1 and PC2, we attempted to produce milligram quantities of human PG, glicentin, and MPGF for use in an in vitro conversion assay. A methionine residue was added to the N-terminus of each protein to initiate translation. Purification was achieved using cation exchange and reversed-phase chromatography, and the integrity of the methionylated proteins was confirmed by both electrospray ionization-mass spectrometry and amino acid analysis. The combined expression and purification scheme is fast, efficient, and results in milligram quantities of > or =95% pure proglucagon, > or =95% pure MPGF, and > or =93% pure glicentin. These prohormones are cleaved by PC1 to produce product peptides consistent with the processing of PG observed in vivo, and should therefore be suitable for further analysis of the post-translational processing of PG.

Alternative preparation of inclusion bodies excludes interfering non-protein contaminants and improves the yield of recombinant proinsulin.

Graphical abstract