Spectroscopic and molecular dynamics simulation studies of the interaction of insulin with glucose (original) (raw)
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Biochemistry, 1991
The solution structure and dynamics of human insulin are investigated by 2D 'H N M R spectroscopy in reference to a previously analyzed analogue, des-pentapeptide(B26-B30) insulin (DPI; Hua, Q. X., & Weiss, M. A. (1990) Biochemistry 29,10545-10555). This spectroscopic comparison is of interest since (i) the structure of the C-terminal region of the B-chain has not been determined in the monomeric state and (ii) the role of this region in binding to the insulin receptor has been the subject of long-standing speculation. The present N M R studies are conducted in the presence of an organic cosolvent (20% acetic acid), under which conditions both proteins are monomeric and stably folded. Complete sequential assignment of human insulin is obtained and leads to the following conclusions. (1) The secondary structure of the insulin monomer (three a-helices and B-chain p-turn) is similar to that observed in the 2-Zn crystal state. (2) The folding of DPI is essentially the same as the corresponding portion of intact insulin, in accord with the similarities between their respective crystal structures. However, differences between insulin and DPI are observed in the extent of conformational broadening of amide resonances, indicating that the presence or absence of residues B26-B30 influences the overall dynamics of the protein on the millisecond time scale. (3) Residues B24-B28 adopt an extended configuration in the monomer and pack against the hydrophobic core as in crystallographic dimers; residues B29 and B30 are largely disordered. This configuration differs from that described in a more organic milieu (35% acetonitrile; Kline, A. D., & Justice, R. M., Jr. (1990) Biochemistry 29,2906-2913), suggesting that the conformation of insulin in the latter study may have been influenced by solvent composition. (4) The insulin fold is shown to provide a model for collective motions in a protein with implications for the mechanism of protein-protein recognition. To our knowledge, this paper describes the first detailed analysis of a protein N M R spectrum under conditions of extensive conformational broadening. Such an analysis is made possible in the present case by comparative study of an analogue (DPI) with more tractable spectroscopic properties. This work was supported in part by grants from the National Institutes of Health, American Diabetes Association, and Juvenile Diabetes Foundation International to M.A.W. M.A.W. is supported by the Wizer Scholars Program for New Faculty and the American Cancer Society.
The solution structure of a monomeric insulin
1991
The solution conformation of des-(B26-B30)-insulin (DPI) has been investigated by 'H-NMR spectroscopy. A set of 250 approximate interproton distance restraints, derived from two-dimensional nuclear Overhauser enhancement spectra, were used as the basis of a structure determination using distance geometry (DG) and distance-bound driven dynamics (DDD). Sixteen DG structures were optimized using energy minimization (EM) and submitted to short 5-ps restrained molecular dynamics (RMD) simulations. A further refinement of the DDD structure with the lowest distance errors was done by energy minimization, a prolonged RMD simulation in VUL'UO and a time-averaged RMD simulation. An average structure was obtained from a trajectory generated during 20ps RMD. The final structure was compared with the des-(B26 -B30)-insulin crystal structure refined by molecular dynamics and the 2-Zn crystal structure of porcine insulin. This comparison shows that the overall structure of des-(B26 -B30)-insulin is retained in solution with respect to the crystal structures with a high flexibility at the N-terminal part of the A chain and at the N-terminal and C-terminal parts of the B chain. In the RMD run a high mobility of Gly A l , Asn A21 and of the side chain of Phe B25 is noticed. One of the conformations adopted by des-(B26-B30)-insulin in solution is similar to that of molecule 1 (Chinese nomenclature) in the crystal structure of porcine insulin.
Influence of the Anomeric Conformation in the Intermolecular Interactions of Glucose
The journal of physical chemistry letters, 2017
Carbohydrates are, together with amino acids, DNA bases, and lipids, the building blocks of living beings. They play a central role in basic functions such as immunity and signaling, which are governed by noncovalent interactions between sugar units and other biomolecules. To get insights into such interactions between monosaccharide units, we used a combination of mass-resolved laser spectroscopy in supersonic expansions and molecular structure calculations. The results obtained clearly demonstrate that the small stability difference between the α/β anomers of glucopyranose derivatives is reversed and amplified during molecular aggregation, making the complexes of the β-anomers significantly more stable. The amplification mechanism seems to be formation of extensive hydrogen-bond networks extending through the two interacting molecules. The same mechanism must be at play in the interactions of biological and synthetic receptors with glycans, which exhibit, in general, a higher affi...
Binding of D-glucose to insulin
Biochimica et biophysica acta, 1975
Binding of D-glucose to insulin has been studied by equilibrium dialysis. The binding is not very specific and probably takes place in two steps. The average amount of glucose molecules bound per insulin molecule is eight, two molecules in the first and six during the second step of binding. The intrinsic binding constants for both steps are almost the same (6-10-2 M-minus 1 and 1-10-3 M-minus 1) which can be explained by assuming: (1) that after binding of the first two molecules a conformational change of insulin occurs which facilitates the binding of the next six molecules of D-glucose; or (2) that in the second step of binding the glucose binds to hydrophobic regions which are unmasked by dissociation of the insulin dimer. Using a three-dimensional model of the insulin molecule areas of the protein molecule where binding of glucose can occur were selected. The glucose-binding site very probably involves the area at the insulin surface where most of the invariant and modificatio...
Biochemical …, 1983
Covalently linked insulin dimers have been prepared by cross-linking two insulin monomers with a flexible suberoyl chain at either the B 1 phenylalanine or the B29 lysine residue. Binding potencies of dimers determined by inhibition of binding of 125I-insulin to isolated rat liver plasma membranes or adipocytes were 2.5-7-fold greater than their abilities to stimulate lipogenesis in adipocytes. Rates of liver plasma-membrane-associated degradation of labelled insulin and dimers, measured by gel filtration, were similar at 370C. Binding and lipogenesis potencies of dimers prepared by substitution of each monomeric half of an asymmetrical dimer with desoctapeptide insulin, an almost inactive derivative, implicated the B 1-cross-linked monomeric half as predominantly interacting with the insulin receptor. These results suggest that (1) dimers bind univalently to a bivalent insulin-receptor complex, in which the two individual binding subunits are arranged with anti-parallel symmetry and (2) the mechanism by which insulin binds and initiates its biological responses requires a conformational change within the insulin-receptor complex and/or in the insulin molecule for full biological expression. termini of both A and B chains and at residue B25 (Blundell et al., 1972; Peking Insulin Structure Research Group, 1974; Cutfield et al., 1981), indicate some degree of molecular flexibility. It is Vol. 216
Biochemistry, 1997
We have characterized the changes in intrinsic fluorescence that the insulin receptor undergoes upon ligand binding and autophosphorylation. The binding of insulin to its receptor results in an increase in the receptor's fluorescence intensity, emission energy and anisotropy. We monitored the time course of the anisotropy change, and these data, coupled with studies monitoring the energy transfer from insulin receptor tryptophan donors to a fluorescent-labeled insulin, allowed us to conclude that the change in anisotropy is due to a conformational change in the receptor induced by hormone binding. Since insulin association is very fast, the time course also allowed us to estimate the slower rate of formation of this conformationally-altered state. The time course of receptor autophosphorylation was measured under similar conditions and was found to be similar to the ligand-induced anisotropy time course. The simultaneous use of two fluorescent-labeled insulin analogs also allowed us to assess the maximum distance between the two hormones bound to the receptor. Addition of ATP produces a large, seemingly instantaneous increase in anisotropy. Our observation that ATP binds to the insulin receptor in the presence and absence of insulin supports the idea that the conformational change produced by insulin binding increases the rate of autophosphorylation rather than increases ATP affinity. A suggested model for these changes is presented.
Non-equivalent Role of Inter- and Intramolecular Hydrogen Bonds in the Insulin Dimer Interface
Journal of Biological Chemistry, 2011
Apart from its role in insulin receptor (IR) activation, the C terminus of the B-chain of insulin is also responsible for the formation of insulin dimers. The dimerization of insulin plays an important role in the endogenous delivery of the hormone and in the administration of insulin to patients. Here, we investigated insulin analogues with selective N-methylations of peptide bond amides at positions B24, B25, or B26 to delineate their structural and functional contribution to the dimer interface. All N-methylated analogues showed impaired binding affinities to IR, which suggests a direct IR-interacting role for the respective amide hydrogens. The dimerization capabilities of analogues were investigated by isothermal microcalorimetry. Selective N-methylations of B24, B25, or B26 amides resulted in reduced dimerization abilities compared with native insulin (K d ؍ 8.8 M).
Prediction of the association state of insulin using spectral parameters
Journal of Pharmaceutical Sciences, 2003
Human insulin exists in different association states, from monomer to hexamer, depending on the conditions. In the presence of zinc the ''normal'' state is a hexamer. The structural properties of 20 variants of human insulin were studied by near-UV circular dichroism, fluorescence spectroscopy, and small-angle X-ray scattering (SAXS). The mutants showed different degrees of association (monomer, dimers, tetramers, and hexamers) at neutral pH. A correlation was shown between the accessibility of tyrosines to acrylamide quenching and the degree of association of the insulin mutants. The near-UV CD spectra of the insulins were affected by protein association and by mutation-induced structural perturbations. However, the shape and intensity of difference CD spectra, obtained by subtraction of the spectra measured in 20% acetic acid (where all insulin species were monomeric) from the corresponding spectra measured at neutral pH, correlate well with the degree of insulin association. In fact, the near-UV CD difference spectra for monomeric, dimeric, tetrameric, and hexameric insulin are very distinctive, both in terms of intensity and shape. The results show that the spectral properties of the insulins reflect their state of association, and can be used to predict their oligomeric state.