Allen H. Pekar scite author profile

The importance of ProB28 and LysB29 on the self-association of insulin was established by systematically truncating the C terminus of the B chain. The relationship between structure and association was further explored by making numerous amino acid replacements at B28 and B29. Association was studied by circular dichroism, size-exclusion chromatography and ultracentrifugation. Our results show that the location of a prolyl residue at B28 is critical for high-affinity self-association. Removal of ProB28 in a series of C-terminal truncated insulins, or amino acid replacement of ProB28, greatly reduced association. The largest disruption to association was achieved by replacing LysB29 with Pro and varying the amino acid at B28. Several of the analogs were predominantly monomers in solutions up to 3 mg/ml. These amino acid substitutions decreased association by primarily disrupting the formation of dimers. Such amino acid substitutions also substantially reduced the Zn-induced insulin hexamer formation. The formation of monomeric insulins through amino acid replacements was accompanied by conformational changes that may be the cause for decreased association. It is demonstrated that self-association of insulin can be drastically altered by substitution of one or two key amino acids.

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Conformation of proinsulin. Comparison of insulin and proinsulin self-association at neutral pH

Pekar¹,

Frank²

1972

Biochemistry

190

128

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The self-association of porcine insulin and proinsulin at pH 7.00 and 24.5°has been studied using sedimentation equilibrium techniques. We found that the apparent weight-average molecular weight of insulin in solution was less than 11,550 at a protein concentration of about 0.17 mg/ml. This finding indicates that the aggregates of insulin are in equilibrium with the 5775 molecular weight monomer of insulin. The molecular weight data can be fit with a model involving monomers, dimers, hexamers, and polymers of the hexamer units. Calculations based on the equilibrium constant for dimer formation show that the mole ratio of

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Quantitation of Aggregate Levels in a Recombinant Humanized Monoclonal Antibody Formulation by Size-Exclusion Chromatography, Asymmetrical Flow Field Flow Fractionation, and Sedimentation Velocity

Gabrielson

Brader

Pekar

et al. 2007

Journal of Pharmaceutical Sciences

167

125

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NMR and photo-CIDNP studies of human proinsulin and prohormone processing intermediates with application to endopeptidase recognition

Weiss¹,

Frank²,

Khait³

et al. 1990

Biochemistry

102

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The proinsulin-insulin system provides a general model for the proteolytic processing of polypeptide hormones. Two proinsulin-specific endopeptidases have been defined, a type I activity that cleaves the B-chain/C-peptide junction (Arg31-Arg32) and a type II activity that cleaves the C-peptide/A-chain junction (Lys64-Arg65). These endopeptidases are specific for their respective dibasic target sites; not all such dibasic sites are cleaved, however, and studies of mutant proinsulins have demonstrated that additional sequence or structural features are involved in determining substrate specificity. To define structural elements required for endopeptidase recognition, we have undertaken comparative 1H NMR and photochemical dynamic nuclear polarization (photo-CIDNP) studies of human proinsulin, insulin, and split proinsulin analogues as models of prohormone processing intermediates. The overall conformation of proinsulin is observed to be similar to that of insulin, and the connecting peptide is largely unstructured. In the 1H NMR spectrum of proinsulin significant variation is observed in the line widths of insulin-specific amide resonances, reflecting exchange among conformational substates; similar exchange is observed in insulin and is not damped by the connecting peptide. The aromatic 1H NMR resonances of proinsulin are assigned by analogy to the spectrum of insulin, and assignments are verified by chemical modification. Unexpectedly, nonlocal perturbations are observed in the insulin moiety of proinsulin, as monitored by the resonances of internal aromatic groups. Remarkably, these perturbations are reverted by site-specific cleavage of the connecting peptide at the CA junction but not the BC junction. These results suggest that a stable local structure is formed at the CA junction, which influences insulin-specific packing interactions. We propose that this structure (designated the "CA knuckle") provides a recognition element for type II proinsulin endopeptidase.

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

et al. 1996

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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, L y~~~~P r o~~~-h u m a n insulin (LysPro), to associate into a hexameric complex. Most importantly, this ligand-bound hexamer retains its rapid-acting pharmacokinetics and pharmacodynamics. The dissociation of the stabilized hexameric analogue has been studied in vitro using static light scattering as well as in vivo using a female pig pharmacodynamic model. Retention of rapid time-action is hypothesized to be due to altered subunit packing within the hexamer. Evidence for modified monomer-monomer interactions has been observed in the X-ray crystal structure of a zinc LysPro hexamer (Ciszak E et al., 1995, Structure 3:615-622). The solution state behavior of LysPro, reported here, has been interpreted with respect to the crystal structure results. In addition, the phenolic ligand binding differences between LysPro and insulin have been compared using isothermal titrating calorimetry and visible absorption spectroscopy of cobalt-containing hexamers. These studies establish that rapid-acting insulin analogues of this type can be stabilized in solution via the formation of hexamer complexes with altered dissociation properties.

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Allen H. Pekar

Altering the association properties of insulin by amino acid replacement

Conformation of proinsulin. Comparison of insulin and proinsulin self-association at neutral pH

Quantitation of Aggregate Levels in a Recombinant Humanized Monoclonal Antibody Formulation by Size-Exclusion Chromatography, Asymmetrical Flow Field Flow Fractionation, and Sedimentation Velocity

NMR and photo-CIDNP studies of human proinsulin and prohormone processing intermediates with application to endopeptidase recognition

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

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Allen H. Pekar

Altering the association properties of insulin by amino acid replacement

Conformation of proinsulin. Comparison of insulin and proinsulin self-association at neutral pH

Quantitation of Aggregate Levels in a Recombinant Humanized Monoclonal Antibody Formulation by Size-Exclusion Chromatography, Asymmetrical Flow Field Flow Fractionation, and Sedimentation Velocity

NMR and photo-CIDNP studies of human proinsulin and prohormone processing intermediates with application to endopeptidase recognition

Physicochemical basis for the rapid time‐action of LysB28ProB29‐insulin: Dissociation of a protein‐ligand complex

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Resources

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