Physicochemical basis for the rapid time‐action of Lys^B28Pro^B29‐insulin: Dissociation of a protein‐ligand complex

Abstract: The rate-limiting step for the absorption of insulin solutions after subcutaneous injection is considered to be the dissociation of self-associated hexamers to monomers. To accelerate this absorption process, insulin analogues have been designed that possess full biological activity and yet have greatly diminished tendencies to self-associate. Sedimentation velocity and static light scattering results show that the presence of zinc and phenolic ligands (m-cresol and/or phenol) cause one such insulin analogue, … Show more

“…The slight attenuation of this feature in the spectrum of the KP-insulin hexamer (thin black line in Fig. 6B; 12 Ϯ 1% lower at 574 nm in triplicate measurements) in relation to the wild-type hexamer (thick black line) has previously been described (9). The visible absorption spectrum of 3-I-Tyr B26 -KP-insulin as a metal-ionstabilized complex (open circles in Fig.…”

“…The molecular elegance of rapid-acting insulin analogs has come at a biophysical cost; such formulations are more susceptible to physical and chemical degradation (especially on dilution and above room temperature) 4 than is wild-type insulin (8,9). Such degradation reflects a trade-off intrinsic to the logic of their design as the same amino acid substitutions that enable accelerated hexamer disassembly in the subcutaneous depot also undermine the protective effects of these assemblies against degradation in the vial or delivery device.…”

“…1C) and a hexameric template wherein Tyr B26 packs at an aromatic-rich dimer interface (in the presence of Zn 2ϩ and phenol, metacresol, or cyclohexanol; Fig. 1, D and E) (9). The availability of these alternative templates facilitated comparative studies of biophysical properties pertinent to formulation and biological activity, including the TR allosteric transition 6 ( Fig.…”

“…These qualitative features do not exclude local reorganization of the B26-related substructure, determining the details of this structure will require more complete 1 H NMR analysis and molecular modeling. Insulin Self-assembly-Evidence that 3-I-Tyr B26 -KP-insulin and KP-insulin are each competent to form R 6 phenol-stabilized Co 2ϩ -insulin hexamers 9 was provided by observation of a characteristic d-d visible absorption band in each case. This blue band, which provides an optical signature of a tetrahedral binding site (Fig.…”

“…This blue band, which provides an optical signature of a tetrahedral binding site (Fig. 6A), is prominently observed in the spectrum 9 Insulin is capable of coordinating a variety of divalent metal ions to form hexamers in which the three His B10 side chains in each component trimer provide a coordination site (octahedral in T 3 sites and tetrahedral in R 3 or R f 3 sites) (1, 61). (Table 1) .…”

Biophysical Optimization of a Therapeutic Protein by Nonstandard Mutagenesis

“…The slight attenuation of this feature in the spectrum of the KP-insulin hexamer (thin black line in Fig. 6B; 12 Ϯ 1% lower at 574 nm in triplicate measurements) in relation to the wild-type hexamer (thick black line) has previously been described (9). The visible absorption spectrum of 3-I-Tyr B26 -KP-insulin as a metal-ionstabilized complex (open circles in Fig.…”

“…The molecular elegance of rapid-acting insulin analogs has come at a biophysical cost; such formulations are more susceptible to physical and chemical degradation (especially on dilution and above room temperature) 4 than is wild-type insulin (8,9). Such degradation reflects a trade-off intrinsic to the logic of their design as the same amino acid substitutions that enable accelerated hexamer disassembly in the subcutaneous depot also undermine the protective effects of these assemblies against degradation in the vial or delivery device.…”

“…1C) and a hexameric template wherein Tyr B26 packs at an aromatic-rich dimer interface (in the presence of Zn 2ϩ and phenol, metacresol, or cyclohexanol; Fig. 1, D and E) (9). The availability of these alternative templates facilitated comparative studies of biophysical properties pertinent to formulation and biological activity, including the TR allosteric transition 6 ( Fig.…”

“…These qualitative features do not exclude local reorganization of the B26-related substructure, determining the details of this structure will require more complete 1 H NMR analysis and molecular modeling. Insulin Self-assembly-Evidence that 3-I-Tyr B26 -KP-insulin and KP-insulin are each competent to form R 6 phenol-stabilized Co 2ϩ -insulin hexamers 9 was provided by observation of a characteristic d-d visible absorption band in each case. This blue band, which provides an optical signature of a tetrahedral binding site (Fig.…”

“…This blue band, which provides an optical signature of a tetrahedral binding site (Fig. 6A), is prominently observed in the spectrum 9 Insulin is capable of coordinating a variety of divalent metal ions to form hexamers in which the three His B10 side chains in each component trimer provide a coordination site (octahedral in T 3 sites and tetrahedral in R 3 or R f 3 sites) (1, 61). (Table 1) .…”

Biophysical Optimization of a Therapeutic Protein by Nonstandard Mutagenesis

Insulin and Hypoglycemic Agents

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