Helle Birk Olsen

Solution Structure of an Engineered Insulin Monomer at Neutral pH

Insulin circulates in the bloodstream and binds to its specific cell-surface receptor as a 5808 Da monomeric species. However, studies of the monomer structure and dynamics in solution are severely limited by insulin self-association into dimers and higher oligomers. In the present work we use site-directed mutagenesis of the dimer- and hexamer-forming surfaces to yield the first insulin species amenable for structure determination at neutral pH by nuclear magnetic resonance (NMR) spectroscopy. The preferred insulin mutant, i.e., (B1, B10, B16, B27) Glu, des-B30 insulin retains 47% biological potency and remains monomeric at millimolar concentrations in aqueous solution at pH 6.5-7.5 as judged by NMR and near-UV circular dichroism (CD) spectroscopy. From a series of 2D 1H-NMR spectra collected at pH 6.5 and 34 degrees C, the majority of the resonances are assigned to specific residues in the sequence, and nuclear Overhauser enhancement (NOE) cross-peaks are identified. NOE-derived distance restraints in conjunction with torsion restraints based on measured coupling constants, 3JHNH alpha, are used for structure calculations using the hybrid method of distance geometry and simulated annealing. The calculated structures show that the major part of the insulin mutant is structurally well defined with an average root mean square (rms) deviation between the 25 calculated structures and the mean coordinates of 0.66 A for backbone atoms (A2-A19 and B4-B26) and 1.31 A for all backbone atoms. The A-chain consists of two antiparallel helices, A2-A7 and A12-A19, connected by a loop. The B-chain contains a loop region (B1-B8), an alpha-helix (B9-B19), and a type I turn (B20-B23) and terminates as an extended strand (B24-B29). The B1-B4 and B27-B29 regions are disordered in solution. The structure is generally similar to crystal structures and resembles a crystalline T-state more than an R-state in the sense that the B-chain helix is confined to residues B9-B19.

Chemical and Thermal Stability of Insulin: Effects of Zinc and Ligand Binding to the Insulin Zinc-Hexamer

PurposeTo study the correlation between the thermal and chemical stability of insulin formulations with various insulin hexamer ligands.Materials and MethodsThe thermal stability was investigated using differential scanning calorimetry (DSC) and near-UV circular dichroism (NUV-CD). The formation of chemical degradation products was studied with reversed-phase and size-exclusion chromatography and mass spectrometry.ResultsAn excellent correlation between the thermal stabilization by ligand binding and the deamidation of AsnB3 was observed. The correlation between thermal stability and the formation of covalent dimer and other insulin related products was less clear. Zinc was found to specifically increase the deamidation and covalent dimer formation rate when the insulin hexamer was not further stabilized by phenolic ligand. Thiocyanate alone had no effect on the thermal stability of the insulin zinc-hexamer but significantly improved the chemical stability at 37°C. At low temperatures thiocyanate induced a conformational change in the insulin hexamer. NUV-CD thermal scans revealed that this effect decreased with temperature; when the thermal denaturation temperature was reached, the effect was eliminated.ConclusionsThermal stability can be used to predict the rate of AsnB3 deamidation in human insulin. Chemical degradation processes that do not rely on the structural stability of the protein do not necessarily correlate to the thermal stability.

Structural signatures of the complex formed between 3-nitro-4-hydroxybenzoate and the Zn(II)-substituted R6 insulin hexamer

3‐Nitro‐4‐hydroxybenzoate (3N4H) is a probe of the structure and dynamics of the metal‐centered His B10 assembly sites of the insulin hexamer. Each His B10 site consists of a ∼12 Å‐long cavity situated on the threefold symmetry axis. These sites play an important role in the storage and release of insulin in vivo. The allosteric behavior of the insulin hexamer is modulated by ligand binding to the His B10 zinc sites and to the phenolic pockets. Binding to these sites drives transitions among three allosteric states, designated T6, T3R3, and R6. Although a wide variety of mono anions bind to the His B10 zinc sites of R3, X‐ray structures of ligands complexed to this site exist only for H2O, Cl–, and SCN–. This work combines one‐ and two‐dimensional 1H NMR and UV‐Vis absorbance studies of the structure and dynamics of the 3N4H complex, which establish the following: (1) relative to the NMR time scale, 3N4H exchange between free and bound states is slow, while flipping among three equivalent orientations about the site threefold axis is fast; (2) binding of 3N4H perturbs resonances within the His B10 zinc site and generates NOEs between ligand resonances and the insulin C‐α and side chain resonances of ValB2, AsnB3, LeuB6, and CysB7; and (3) 3N4H exchange for other ligands is limited by a protein conformational transition. These results are consistent with coordination of the 3N4H carboxylate to the His B10 zinc ion and van der Waals interactions with Val B2, Asn B3, Leu B6, and Cys A7.

Spectroscopic characterization of insulin and small molecule ligand binding to the insulin receptor

We have applied spectroscopic techniques to study two kinds of ligand binding to the insulin receptor. First, a fluo- rescently labelled insulin analogue is used to characterize the mechanism of reversible 1 : 1 complex formation with a fragment of the insulin receptor ectodomain. The receptor induced fluorescence enhancement of the labelled insulin analogue provides the basis for stopped flow kinetic experiments. The kinetic data are consistent with a bimolecular binding event followed by a conformational change. This emphasizes the importance of insulin induced conformational changes in the activation of the insulin receptor. Second, the binding of fluorescein derivatives to the insulin receptor is studied. These small molecule ligands displace insulin from its receptor with micromolar affinity. The binding is verified by transferred NOESY NMR experiments. Their chromophoric properties are used to measure the affinity by UV-vis and fluorescence difference spectroscopies and the resulting K d values are similar to those observed in the displacement receptor binding assay. However, these experiments and a stoichiometry determination indicate multiple binding sites, of which one overlaps with the insulin binding site. These two examples illustrate how spectroscopy complements biochemical receptor binding assays and provides information on ligand- insulin receptor interactions in the absence of three dimensional structures.