Your search keyword '"Nelson, B."' showing total 9 results

1. Biophysical Optimization of a Therapeutic Protein by Nonstandard Mutagenesis.

Author

Pandyarajan, Vijay, Phillips, Nelson B., Cox, Gabriela P., Yanwu Yang, Whittaker, Jonathan, Ismail-Beigi, Faramarz, and Weiss, Michael A.

Subjects

*PROTEIN engineering, *MOLECULAR pharmacology, *INSULIN, *DIABETES, *OLIGOMERS, *AMINO acids, *ALLOSTERIC proteins

Abstract

Insulin provides a model for the therapeutic application of protein engineering. A paradigm in molecular pharmacology was defined by design of rapid-acting insulin analogs for the prandial control of glycemia. Such analogs, a cornerstone of current diabetes regimens, exhibit accelerated subcutaneous absorption due to more rapid disassembly of oligomeric species relative to wild-type insulin. This strategy is limited by a molecular trade-off between accelerated disassembly and enhanced susceptibility to degradation. Here, we demonstrate that this trade-off may be circumvented by nonstandard mutagenesis. Our studies employed LysB28, ProB29-insulin ("lispro") as a model prandial analog that is less thermodynamically stable and more susceptible to fibrillation than is wild-type insulin. We have discovered that substitution of an invariant tyrosine adjoining the engineered sites in lispro (TyrB26) by 3-iodo-Tyr (i) augments its thermodynamic stability (ΔΔGu 0.5 ±0.2 kcal/ mol), (ii) delays onset of fibrillation (lag time on gentle agitation at 37 °C was prolonged by 4-fold), (iii) enhances affinity for the insulin receptor (1.5 ± 0.1-fold), and (iv) preserves biological activity in a rat model of diabetes mellitus. 1HNMRstudies suggest that the bulky iodo-substituent packs within a nonpolar interchain crevice. Remarkably, the 3-iodo-TyrB26 modification stabilizes an oligomeric form of insulin pertinent to pharmaceutical formulation (the R6 zinc hexamer) but preserves rapid disassembly of the oligomeric form pertinent to subcutaneous absorption (T6 hexamer). By exploiting this allosteric switch, 3-iodo-TyrB26-lispro thus illustrates how a nonstandard amino acid substitution can mitigate the unfavorable biophysical properties of an engineered protein while retaining its advantages. [ABSTRACT FROM AUTHOR]

Published

2014

2. An ultra-stable single-chain insulin analog resists thermal inactivation and exhibits biological signaling duration equivalent to the native protein.

Author

Glidden, Michael D., Aldabbagh, Khadijah, Phillips, Nelson B., Carr, Kelley, Yen-Shan Chen, Whittaker, Jonathan, Phillips, Manijeh, Wickramasinghe, Nalinda P., Rege, Nischay, Swain, Mamuni, Yi Peng, Yanwu Yang, Lawrence, Michael C., Yee, Vivien C., Ismail-Beigi, Faramarz, and Weiss, Michael A.

Subjects

*INSULIN, *BOLUS drug administration, *ELECTRON density, *NUCLEAR magnetic resonance spectroscopy, *PHARMACOKINETICS

Abstract

Thermal degradation of insulin complicates its delivery and use. Previous efforts to engineer ultra-stable analogs were confounded by prolonged cellular signaling in vivo, of unclear safety and complicating mealtime therapy. We therefore sought an ultra-stable analog whose potency and duration of action on intravenous bolus injection in diabetic rats are indistinguishable from wild-type (WT) insulin. Here, we describe the structure, function, and stability of such an analog, a 57-residue single-chain insulin (SCI) with multiple acidic substitutions. Cell-based studies revealed native-like signaling properties with negligible mitogenic activity. Its crystal structure, determined as a novel zinc-free hexamer at 2.8 Å, revealed a native insulin fold with incomplete or absent electron density in the C domain; complementary NMR studies are described in the accompanying article. The stability of the analog (ΔGU 5.0(±0.1) kcal/mol at 25 °C) was greater than that of WT insulin (3.3(±0.1) kcal/mol). On gentle agitation, the SCI retained full activity for >140 days at 45 °C and >48 h at 75 °C. These findings indicate that marked resistance to thermal inactivation in vitro is compatible with native duration of activity in vivo Further, whereas WT insulin forms large and heterogeneous aggregates above the standard 0.6 mm pharmaceutical strength, perturbing the pharmacokinetic properties of concentrated formulations, dynamic light scattering, and size-exclusion chromatography revealed only limited SCI self-assembly and aggregation in the concentration range 1-7 mm Such a combination of favorable biophysical and biological properties suggests that SCIs could provide a global therapeutic platform without a cold chain. [ABSTRACT FROM AUTHOR]

Published

2018

3. Extending Halogen-based Medicinal Chemistry to Proteins.

Author

El Hage, Krystel, Pandyarajan, Vijay, Phillips, Nelson B., Smith, Brian J., Menting, John G., Whittaker, Jonathan, Lawrence, Michael C., Meuwly, Markus, and Weiss, Michael A.

Subjects

*PHARMACEUTICAL chemistry, *INSULIN, *HALOGENS, *HOMEOSTASIS, *PROTEIN engineering

Abstract

Insulin, a protein critical for metabolic homeostasis, provides a classical model for protein design with application to human health. Recent efforts to improve its pharmaceutical formulation demonstrated that iodination of a conserved tyrosine (TyrB26) enhances key properties of a rapid-acting clinical analog. Moreover, the broad utility of halogens in medicinal chemistry has motivated the use of hybrid quantum- and molecular-mechanical methods to study proteins. Here, we (i) undertook quantitative atomistic simulations of 3-[iodo-TyrB26]insulin to predict its structural features, and (ii) tested these predictions by X-ray crystallography. Using an electrostatic model of the modified aromatic ring based on quantum chemistry, the calculations suggested that the analog, as a dimer and hexamer, exhibits subtle differences in aromatic-aromatic interactions at the dimer interface. Aromatic rings (TyrB16, PheB24, PheB25, 3-I-TyrB26, and their symmetry-related mates) at this interface adjust to enable packing of the hydrophobic iodine atoms within the core of each monomer. Strikingly, these features were observed in the crystal structure of a 3-[iodo-TyrB26]insulin analog (determined as an R6 zinc hexamer). Given that residues B24-B30 detach from the core on receptor binding, the environment of 3-I-TyrB26 in a receptor complex must differ from that in the free hormone. Based on the recent structure of a "micro-receptor" complex, we predict that 3-I-TyrB26 engages the receptor via directional halogen bonding and halogen-directed hydrogen bonding as follows: favorable electrostatic interactions exploiting, respectively, the halogen's electron-deficient σ-hole and electronegative equatorial band. Inspired by quantum chemistry and molecular dynamics, such "halogen engineering" promises to extend principles of medicinal chemistry to proteins. [ABSTRACT FROM AUTHOR]

Published

2016

4. Proinsulin Is Refractory to Protein Fibrillation.

Author

Kun Huang, Jian Dong, Phillips, Nelson B., Carey, Paul R., and Weiss, Michael A.

Subjects

*RESEARCH, *PROINSULIN, *INSULIN, *PANCREATIC beta cells, *PEPTIDES, *GUANIDINE, *PROTEINS, *SOMATOMEDIN, *GROWTH factors, *ENDOPLASMIC reticulum, *BIOCHEMISTRY

Abstract

Insulin is susceptible to fibrillation, a misfolding process leading to well ordered cross-β assembly. Protection from fibrillation in β cells is provided by sequestration of the susceptible monomer within zinc hexamers. We demonstrate that proinsulin is refractory to fibrillation under conditions that promote the rapid fibrillation of zinc-free insulin. Proinsulin fibrils, as probed by Raman microscopy, are nonetheless similar in structure to insulin fibrils. The connecting peptide, although not well ordered in native proinsulin, participates in a fibril-specific β-sheet. Native insulin and proinsulin exhibit similar free energies of unfolding as inferred from guanidine denaturation studies: relative amyloidogenicities are thus not correlated with global stability. Strikingly, the susceptibility of proinsulin to fibrillation is increased by scission of the connecting peptide at single sites. We thus propose that the connecting peptide constrains a large scale conformational change in the misfolded protein. A tethering mechanism is proposed based on a model of an insulin protofilament derived from electron-microscopic image reconstruction. The proposed relationship between cross-β assembly and protein topology is supported by studies of single-chain analogs (mini-proinsulin and insulin-like growth factor I) in which foreshortened connecting peptides further retard fibrillation. In addition to its classic function to facilitate disulfide pairing, the connecting peptide may protect β cells from toxic protein misfolding in the endoplasmic reticulum. [ABSTRACT FROM AUTHOR]

Published

2005

5. Insertion of a synthetic switch into insulin provides metabolite-dependent regulation of hormone-receptor activation.

Author

Yen-Shan Chen, Gleaton, Jeremy, Yanwu Yang, Dhayalan, Balamurugan, Phillips, Nelson B., Yule Liu, Broadwater, Laurie, Jarosinski, Mark A., Chatterjee, Deepak, Lawrence, Michael C., Hattier, Thomas, Michael, M. Dodson, and Weiss, Michael A.

Subjects

*INSULIN derivatives, *INSULIN, *CINNAMON, *HORMONE receptors, *METABOLIC regulation, *CURCUMIN, *GENETIC regulation, *FIREPROOFING agents

Abstract

Insulin-signaling requires conformational change: whereas the free hormone and its receptor each adopt autoinhibited conformations, their binding leads to structural reorganization. To test the functional coupling between insulin's "hinge opening" and receptor activation, we inserted an artificial ligand-dependent switch into the insulin molecule. Ligand-binding disrupts an internal tether designed to stabilize the hormone's native closed and inactive conformation, thereby enabling productive receptor engagement. This scheme exploited a diol sensor (meta-fluoro-phenylboronic acid at GlyA1) and internal diol (3,4-dihydroxybenzoate at LysB28). The sensor recognizes monosaccharides (fructose > glucose). Studies of insulin-signaling in human hepatoma-derived cells (HepG2) demonstrated fructose-dependent receptor autophosphorylation leading to appropriate downstream signaling events, including a specific kinase cascade and metabolic gene regulation (gluconeogenesis and lipogenesis). Addition of glucose (an isomeric ligand with negligible sensor affinity) did not activate the hormone. Similarly, metabolite-regulated signaling was not observed in control studies of 1) an unmodified insulin analog or 2) an analog containing a diol sensor without internal tethering. Although secondary structure (as probed by circular dichroism) was unaffected by ligand-binding, heteronuclear NMR studies revealed subtle local and nonlocal monosaccharide-dependent changes in structure. Insertion of a synthetic switch into insulin has thus demonstrated coupling between hinge-opening and allosteric holoreceptor signaling. In addition to this foundational finding, our results provide proof of principle for design of a mechanism-based metabolite-responsive insulin. In particular, replacement of the present fructose sensor by an analogous glucose sensor may enable translational development of a "smart" insulin analog to mitigate hypoglycemic risk in diabetes therapy. [ABSTRACT FROM AUTHOR]

Published

2021

6. Evolution of insulin at the edge of foldability and its medical implications.

Author

Rege, Nischay K., Ming Liu, Yanwu Yang, Dhayalan, Balamurugan, Wickramasinghe, Nalinda P., Yen-Shan Chen, Rahimi, Leili, Huan Guo, Haataja, Leena, Jinhong Sun, Ismail-Beigi, Faramarz, Phillips, Nelson B., Arvan, Peter, and Weiss, Michael A.

Subjects

*SOMATOMEDIN, *INSULIN derivatives, *INSULIN, *INSULIN receptors, *PROTEIN folding

Abstract

Proteins have evolved to be foldable, and yet determinants of foldability may be inapparent once the native state is reached. Insight has emerged from studies of diseases of protein misfolding, exemplified by monogenic diabetes mellitus due to mutations in proinsulin leading to endoplasmic reticulum stress and β-cell death. Cellular foldability of human proinsulin requires an invariant Phe within a conserved crevice at the receptor-binding surface (position B24). Any substitution, even related aromatic residue TyrB24, impairs insulin biosynthesis and secretion. As a seeming paradox, a monomeric TyrB24 insulin analog exhibits a native-like structure in solution with only a modest decrement in stability. Packing of TyrB24 is similar to that of PheB24, adjoining core cystine B19-A20 to seal the core; the analog also exhibits native self-assembly. Although affinity for the insulin receptor is decreased ~20-fold, biological activities in cells and rats were within the range of natural variation. Together, our findings suggest that the invariance of PheB24 among vertebrate insulins and insulin-like growth factors reflects an essential role in enabling efficient protein folding, trafficking, and secretion, a function that is inapparent in native structures. In particular, we envision that the para-hydroxyl group of TyrB24 hinders pairing of cystine B19-A20 in an obligatory on-pathway folding intermediate. The absence of genetic variation at B24 and other conserved sites near this disulfide bridge--excluded due to β-cell dysfunction--suggests that insulin has evolved to the edge of foldability. Nonrobustness of a protein's fitness landscape underlies both a rare monogenic syndrome and "diabesity" as a pandemic disease of civilization. [ABSTRACT FROM AUTHOR]

Published

2020

7. An Achilles' Heel in an Amyloidogenic Protein and Its Repair.

Author

Yanwu Yang, Petkova, Aneta, Kun Huang, Bin Xu, Qing-xin Hua, I-Ju Ye, Ying-Chi Chu, Shi-Quan Hu, Phillips, Nelson B., Whittaker, Jonathan, Ismail-Beigi, Faramarz, Mackin, Robert B., Katsoyannis, Panayotis G., Tycko, Robert, and Weiss, Michael A.

Subjects

*INSULIN, *PROTEINS, *MONOMERS, *HORMONES, *PANCREATIC beta cells

Abstract

Insulin fibrillation provides a model for a broad class of amyloidogenic diseases. Conformational distortion of the native monomer leads to aggregation-coupled misfolding. Whereas β-cells are protected from proteotoxicity by hexamer assembly, fibrillation limits the storage and use of insulin at elevated temperatures. Here, we have investigated conformational distortions of an engineered insulin monomer in relation to the structure of an insulin fibril. Anomalous 13C NMR chemical shifts and rapid 15N-detected ¹H-²H amide-proton exchange were observed in one of the three classical a-helices (residues A1-A8) of the hormone, suggesting a conformational equilibrium between locally folded and unfolded A-chain segments. Whereas hexamer assembly resolves these anomalies in accordance with its protective role, solid-state 13C NMR studies suggest that the A-chain segment participates in a fibril-specific β-sheet. Accordingly, we investigated whether helicogenic substitutions in the A1-A8 segment might delay fibrillation. Simultaneous substitution of three E-branched residues (IleA2 → Leu, ValA3 → Leu, and ThrA8 → His) yielded an analog with reduced thermodynamic stability but marked resistance to fibrillation. Whereas amide-proton exchange in the A1-A8 segment remained rapid, 13Cα chemical shifts exhibited a more helical pattern. This analog is essentially without activity, however, as IleA2 and ValA3 define conserved receptor contacts. To obtain active analogs, substitutions were restricted to A8. These analogs exhibit high receptor-binding affinity; representative potency in a rodent model of diabetes mellitus was similar to wild-type insulin. Although 13Cα chemical shifts remain anomalous, significant protection from fibrillation is retained. Together, our studies define an "Achilles' heel" in a globular protein whose repair may enhance the stability of pharmaceutical formulations and broaden their therapeutic deployment in the developing world. [ABSTRACT FROM AUTHOR]

Published

2010

8. Contribution of Residue B5 to the Folding and Function of Insulin and IGF-l: CONSTRAINTS AND FINE-TUNING IN THE EVOLUTION OF A PROTEIN FAMILY.

Author

Youhei Sohma, Qing-xin Hua, Ming Liu, Phillips, Nelson B., Shi-Quan Hu, Whittaker, Jonathan, Whittaker, Linda J., Ng, Aubree, Roberts Jr., Charles T., Arvan, Peter, Kent, Stephen B. H., and Weiss, Michael A.

Subjects

*INSULIN, *CARRIER proteins, *GROWTH factors, *ISOMERASES, *CYSTINOSIS, *BIOSYNTHESIS

Abstract

Proinsulin exhibits a single structure, whereas insulin-like growth factors refold as two disulfide isomers in equilibrium. Native insulin-related growth factor (IGF)-I has canonical cystines (A6-A11, A7-B7, and A20-B19) maintained by IGF-binding proteins; IGF-swap has alternative pairing (A7-A11, A6 -B7, and A20 -B19) and impaired activity. Studies of mini- domain models suggest that residue B5 (His in insulin and Thr in IGFs) governs the ambiguity or uniqueness of disulfide pairing. Residue B5, a site of mutation in proinsulin causing neonatal diabetes, is thus of broad biophysical interest. Here, we characterize reciprocal B5 substitutions in the two proteins. In insulin, HisB5 → Thr markedly destabilizes the hormone (ΔΔGu 2.0 ± 0.2 kcal/mol), impairs chain combination, and blocks cellular secretion of proinsulin. The reciprocal IGF-I substitution ThrB5 → His (residue 4) specifies a unique structure with native ¹H NMR signature. Chemical shifts and nuclear Overhauser effects are similar to those of native IGF-I. Whereas wild-type IGF-I undergoes thiol-catalyzed disulfide exchange to yield IGF-swap, HisB5-IGF-I retains canonical pairing. Chemical denaturation studies indicate that HisB5 does not significantly enhance thermodynamic stability (ΔΔGu 0.2 ± 0.2 kcal/mol), implying that the substitution favors canonical pairing by destabilizing competing folds. Whereas the activity of ThrB5-insulin is decreased 5-fold, HisB5-IGF-I exhibits 2-fold increased affinity for the IGF receptor and augmented post-receptor signaling. We propose that conservation of ThrB5 in IGF-I, rescued from structural ambiguity by IGF-binding proteins, reflects fine-tuning of signal transduction. In contrast, the conservation of HisB5 in insulin highlights its critical role in insulin biosynthesis. [ABSTRACT FROM AUTHOR]

Published

2010

9. Design of an Active Ultrastable Single-chain Insulin Analog SYNTHESIS, STRUCTURE, AND THERAPEUTIC IMPLICATIONS.

Author

Qing-xin Hua, Nakagawa, Satoe H., Wenhua Jia, Kun Huang, Phillips, Nelson B., Shi-quan Hu, and Weiss, Michael A.

Subjects

*INSULIN, *MOLECULAR structure, *BIOSYNTHESIS, *THERMODYNAMICS, *OVERHAUSER effect (Nuclear physics)

Abstract

Single-chain insulin (SCI) analogs provide insight into the inter-relation of hormone structure, function, and dynamics. Although compatible with wild-type structure, short connecting segments (<3 residues) prevent induced fit upon receptor binding and so are essentially without biological activity. Substantial but incomplete activity can be regained with increasing linker length. Here, we describe the design, structure, and function of a single-chain insulin analog (SCI-57) containing a 6-residue linker (GGGPRR). Native receptor-binding affinity (130 ± 8% relative to the wild type) is achieved as hindrance by the linker is offset by favorable substitutions in the insulin moiety. The thermodynamic stability of SCI-57 is markedly increased (ΔΔGu = 0.7 ± 0.1 kcal/mol relative to the corresponding two-chain analog and 1.9 ± 0.1 kcal/mol relative to wild-type insulin). Analysis of inter-residue nuclear Overhauser effects demonstrates that a native-like fold is maintained in solution. Surprisingly, the glycine-rich connecting segment folds against the insulin moiety: its central Pro contacts VaIA3 at the edge of the hydrophobic core, whereas the final Arg extends the A1-A8 α-helix. Comparison between SCI-57 and its parent two-chain analog reveals striking enhancement of multiple native-like nuclear Overhauser effects within the tethered protein. These contacts are consistent with wild-type crystal structures but are ordinarily attenuated in NMR spectra of two-chain analogs, presumably due to conformational fluctuations. Linker-specific damping of fluctuations provides evidence for the intrinsic flexibility of an insulin monomer. In addition to their biophysical interest, ultrastable SCIs may enhance the safety and efficacy of insulin replacement therapy in the developing world. [ABSTRACT FROM AUTHOR]

Published

2008