4akj Citations

Ligand-controlled assembly of hexamers, dihexamers, and linear multihexamer structures by the engineered acylated insulin degludec.

Steensgaard DB, Schluckebier G, Strauss HM, Norrman M, Thomsen JK, Friderichsen AV, Havelund S, Jonassen I
Biochemistry 52 295-309 (2013)
Related entries: 4ajx, 4ajz, 4ak0

Cited: 38 times
EuropePMC logo PMID: 23256685

Abstract

Insulin degludec, an engineered acylated insulin, was recently reported to form a soluble depot after subcutaneous injection with a subsequent slow release of insulin and an ultralong glucose-lowering effect in excess of 40 h in humans. We describe the structure, ligand binding properties, and self-assemblies of insulin degludec using orthogonal structural methods. The protein fold adopted by insulin degludec is very similar to that of human insulin. Hexamers in the R(6) state similar to those of human insulin are observed for insulin degludec in the presence of zinc and resorcinol. However, under conditions comparable to the pharmaceutical formulation comprising zinc and phenol, insulin degludec forms finite dihexamers that are composed of hexamers in the T(3)R(3) state that interact to form an R(3)T(3)-T(3)R(3) structure. When the phenolic ligand is depleted and the solvent condition thereby mimics that of the injection site, the quaternary structure changes from dihexamers to a supramolecular structure composed of linear arrays of hundreds of hexamers in the T(6) state and an average molar mass, M(0), of 59.7 × 10(3) kg/mol. This novel concept of self-assemblies of insulin controlled by zinc and phenol provides the basis for the slow action profile of insulin degludec. To the best of our knowledge, this report for the first time describes a tight linkage between quaternary insulin structures of hexamers, dihexamers, and multihexamers and their allosteric state and its origin in the inherent propensity of the insulin hexamer for allosteric half-site reactivity.

Reviews - 4akj mentioned but not cited (1)

  1. How Structural Biologists and the Protein Data Bank Contributed to Recent FDA New Drug Approvals. Westbrook JD, Burley SK. Structure 27 211-217 (2019)

Articles - 4akj mentioned but not cited (1)

  1. Predicting binding sites from unbound versus bound protein structures. Clark JJ, Orban ZJ, Carlson HA. Sci Rep 10 15856 (2020)


Reviews citing this publication (17)

  1. A review of the pharmacological properties of insulin degludec and their clinical relevance. Haahr H, Heise T. Clin Pharmacokinet 53 787-800 (2014)
  2. Impact of the mode of protraction of basal insulin therapies on their pharmacokinetic and pharmacodynamic properties and resulting clinical outcomes. Heise T, Mathieu C. Diabetes Obes Metab 19 3-12 (2017)
  3. Insulin degludec results in lower rates of nocturnal hypoglycaemia and fasting plasma glucose vs. insulin glargine: A meta-analysis of seven clinical trials. Russell-Jones D, Gall MA, Niemeyer M, Diamant M, Del Prato S. Nutr Metab Cardiovasc Dis 25 898-905 (2015)
  4. Insulin degludec and insulin degludec/insulin aspart: a review of their use in the management of diabetes mellitus. Keating GM. Drugs 73 575-593 (2013)
  5. A Review of Insulin Degludec/Insulin Aspart: Pharmacokinetic and Pharmacodynamic Properties and Their Implications in Clinical Use. Haahr H, Fita EG, Heise T. Clin Pharmacokinet 56 339-354 (2017)
  6. Rationale for, Initiation and Titration of the Basal Insulin/GLP-1RA Fixed-Ratio Combination Products, IDegLira and IGlarLixi, for the Management of Type 2 Diabetes. Valentine V, Goldman J, Shubrook JH. Diabetes Ther 8 739-752 (2017)
  7. Are you ready for more insulin concentrations? Segal AR, El Sayed N. J Diabetes Sci Technol 9 331-338 (2015)
  8. Efficacy and safety of fixed-ratio combination of insulin degludec and liraglutide (IDegLira) for the treatment of type 2 diabetes. Vedtofte L, Knop FK, Vilsbøll T. Expert Opin Drug Saf 16 387-396 (2017)
  9. New developments in insulin therapy for type 2 diabetes. Sorli C. Am J Med 127 S39-48 (2014)
  10. Infinite Assembly of Folded Proteins in Evolution, Disease, and Engineering. Garcia-Seisdedos H, Villegas JA, Levy ED. Angew Chem Int Ed Engl 58 5514-5531 (2019)
  11. New and Evolving Techniques for the Characterization of Peptide Therapeutics. D'Addio SM, Bothe JR, Neri C, Walsh PL, Zhang J, Pierson E, Mao Y, Gindy M, Leone A, Templeton AC. J Pharm Sci 105 2989-3006 (2016)
  12. Structural principles of insulin formulation and analog design: A century of innovation. Jarosinski MA, Dhayalan B, Chen YS, Chatterjee D, Varas N, Weiss MA. Mol Metab 52 101325 (2021)
  13. Derivatization with fatty acids in peptide and protein drug discovery. Kurtzhals P, Østergaard S, Nishimura E, Kjeldsen T. Nat Rev Drug Discov 22 59-80 (2023)
  14. New Horizons: Next-Generation Insulin Analogues: Structural Principles and Clinical Goals. Jarosinski MA, Chen YS, Varas N, Dhayalan B, Chatterjee D, Weiss MA. J Clin Endocrinol Metab 107 909-928 (2022)
  15. United States experience of insulin degludec alone or in combination for type 1 and type 2 diabetes. Rendell M. Drug Des Devel Ther 11 1209-1220 (2017)
  16. Senna singueana (Delile) lock: Ethnomedicinal uses and medicinal properties. Ripanda A, Luanda A, Mtabazi GS, Makangara JJ. Heliyon 9 e14098 (2023)
  17. Premix insulins in type 1 diabetes: the coming of degludec/aspart. Rendell M. Expert Opin Drug Metab Toxicol 15 341-348 (2019)

Articles citing this publication (19)

  1. Investigation of the Physico-Chemical Properties that Enable Co-Formulation of Basal Insulin Degludec with Fast-Acting Insulin Aspart. Havelund S, Ribel U, Hubálek F, Hoeg-Jensen T, Wahlund PO, Jonassen I. Pharm Res 32 2250-2258 (2015)
  2. Cytotoxicity of 91 Kenyan indigenous medicinal plants towards human CCRF-CEM leukemia cells. Omosa LK, Midiwo JO, Masila VM, Gisacho BM, Munayi R, Francisca-Kamakama, Chemutai KP, Elhaboob G, Saeed ME, Hamdoun S, Kuete V, Efferth T, Efferth T. J Ethnopharmacol 179 177-196 (2016)
  3. Anti-diabetic effects of the acetone fraction of Senna singueana stem bark in a type 2 diabetes rat model. Ibrahim MA, Islam MS. J Ethnopharmacol 153 392-399 (2014)
  4. Insulin degludec/liraglutide (IDegLira) for the treatment of type 2 diabetes. Gough SC, Jain R, Woo VC. Expert Rev Endocrinol Metab 11 7-19 (2016)
  5. Computational and structural evidence for neurotransmitter-mediated modulation of the oligomeric states of human insulin in storage granules. Palivec V, Viola CM, Kozak M, Ganderton TR, Křížková K, Turkenburg JP, Haluŝková P, Žáková L, Jiráĉek J, Jungwirth P, Brzozowski AM. J Biol Chem 292 8342-8355 (2017)
  6. Degludec: the new ultra-long insulin analogue. Tambascia MA, Eliaschewitz FG. Diabetol Metab Syndr 7 57 (2015)
  7. Characterisation of insulin analogues therapeutically available to patients. Adams GG, Meal A, Morgan PS, Alzahrani QE, Zobel H, Lithgo R, Kok MS, Besong DTM, Jiwani SI, Ballance S, Harding SE, Chayen N, Gillis RB. PLoS One 13 e0195010 (2018)
  8. Improved Glycemic Control Achieved by Switching to Insulin Degludec in Insulin-Treated Patients with Type 2 Diabetes in a Real-World Setting: a Non-interventional, Retrospective Cohort Study. Melzer Cohen C, Thorsted BL, Wolden ML, Chodick G, Karasik A. Diabetes Ther 8 1047-1055 (2017)
  9. Time-action profiles of insulin degludec in healthy dogs and its effects on glycemic control in diabetic dogs. Oda H, Mori A, Ishii S, Shono S, Onozawa E, Sako T. J Vet Med Sci 80 1720-1723 (2018)
  10. Glargine and degludec: Solution behaviour of higher dose synthetic insulins. Adams GG, Alzahrani Q, Jiwani SI, Meal A, Morgan PS, Coffey F, Kok S, Rowe AJ, Harding SE, Chayen N, Gillis RB. Sci Rep 7 7287 (2017)
  11. A case of insulin allergy successfully managed using multihexamer-forming insulin degludec combined with liraglutide. Fujishiro M, Izumida Y, Takemiya S, Kuwano Y, Takamoto I, Suzuki R, Yamauchi T, Ueki K, Kadowaki T. Diabet Med 33 e26-e29 (2016)
  12. Expression, receptor binding, and biophysical characterization of guinea pig insulin desB30: a monomeric insulin variant. Engholm E, Hansen TH, Johansson E, Strauss HM, Vinther TN, Jensen KJ, Hubálek F, Kjeldsen TB. Chembiochem 16 954-958 (2015)
  13. Letter In response to: Heise T, Nørskov M, Nosek L, Kaplan K, Famulla S and Haahr H. L. (2017) Insulin degludec: Lower day-to-day and within-day variability in pharmacodynamic response compared to insulin glargine U300 in type 1 diabetes. Diabetes Obes Metab. 2017;19:1032-1039. Becker RHA. Diabetes Obes Metab 20 2043-2047 (2018)
  14. Letter Switching from insulin glargine to insulin degludec reduced HbA1c, daily insulin doses and anti-insulin antibody in anti-insulin antibody-positive subjects with type 1 diabetes. Hamasaki H, Yanai H. Diabetes Metab 40 481-482 (2014)
  15. Clinical and cost-effectiveness of insulin degludec: from clinical trials to clinical practice. Evans M, McEwan P. J Comp Eff Res 4 279-286 (2015)
  16. Letter Acylated-based long-acting insulin analogues: is “misfolding” the problem? Commentary letter on Hamasaki H and Yanai H. The switching from insulin glargine to insulin degludec reduced HbA1c, daily insulin doses and anti-insulin antibody in anti-insulin antibody-positive subjects with type 1 diabetes. Monnier L, Colette C, Owens D. Diabetes Metab 40 483-484 (2014)
  17. Clinically Relevant Insulin Degludec and its Interaction with Polysaccharides: A Biophysical Examination. Jiwani SI, Huang S, Beji O, Gyasi-Antwi P, Gillis RB, Adams GG. Polymers (Basel) 12 E390 (2020)
  18. Insulin Hexamer-Caged Gadolinium Ion as MRI Contrast-o-phore. Taylor SK, Tran TH, Liu MZ, Harris PE, Sun Y, Jambawalikar SR, Tong L, Stojanovic MN. Chemistry 24 10646-10652 (2018)
  19. Total Chemical Synthesis of Palmitoyl-Conjugated Insulin. Liu M, Li Q, Delaine C, Wu H, Arsenakis Y, White BF, Forbes BE, Chandrashekar C, Hossain MA. ACS Omega 8 13715-13720 (2023)


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