Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges

Balamurugan Dhayalan; Yen Shan Chen; Nelson B. Phillips; Mamuni Swain; Nischay K. Rege; Ali Mirsalehi; Mark Jarosinski; Faramarz Ismail-Beigi; Norman Metanis; Michael A. Weiss

doi:10.1002/chem.202000309

Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges

Balamurugan Dhayalan, Yen Shan Chen, Nelson B. Phillips, Mamuni Swain, Nischay K. Rege, Ali Mirsalehi, Mark Jarosinski, Faramarz Ismail-Beigi, Norman Metanis, Michael A. Weiss

Institute of Chemistry

The Hebrew University of Jerusalem

Research output: Contribution to journal › Article › peer-review

Abstract

Long-acting insulin analogues represent the most prescribed class of therapeutic proteins. An innovative design strategy was recently proposed: diselenide substitution of an external disulfide bridge. This approach exploited the distinctive physicochemical properties of selenocysteine (U). Relative to wild type (WT), Se-insulin[C7U^A, C7U^B] was reported to be protected from proteolysis by insulin-degrading enzyme (IDE), predicting prolonged activity. Because of this strategy's novelty and potential clinical importance, we sought to validate these findings and test their therapeutic utility in an animal model of diabetes mellitus. Surprisingly, the analogue did not exhibit enhanced stability, and its susceptibility to cleavage by either IDE or a canonical serine protease (glutamyl endopeptidase Glu-C) was similar to WT. Moreover, the analogue's pharmacodynamic profile in rats was not prolonged relative to a rapid-acting clinical analogue (insulin lispro). Although [C7U^A, C7U^B] does not confer protracted action, nonetheless its comparison to internal diselenide bridges promises to provide broad biophysical insight.

Original language	English
Pages (from-to)	4695-4700
Number of pages	6
Journal	Chemistry - A European Journal
Volume	26
Issue number	21
DOIs	https://doi.org/10.1002/chem.202000309
State	Published - 9 Apr 2020

Keywords

chemical protein synthesis
insulin
oxidative protein folding
selenocysteine
selenoprotein

All Science Journal Classification (ASJC) codes

General Chemistry
Catalysis
Organic Chemistry

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/chem.202000309

Cite this

Dhayalan, B., Chen, Y. S., Phillips, N. B., Swain, M., Rege, N. K., Mirsalehi, A., Jarosinski, M., Ismail-Beigi, F., Metanis, N., & Weiss, M. A. (2020). Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges. Chemistry - A European Journal, 26(21), 4695-4700. https://doi.org/10.1002/chem.202000309

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title = "Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges",

abstract = "Long-acting insulin analogues represent the most prescribed class of therapeutic proteins. An innovative design strategy was recently proposed: diselenide substitution of an external disulfide bridge. This approach exploited the distinctive physicochemical properties of selenocysteine (U). Relative to wild type (WT), Se-insulin[C7UA, C7UB] was reported to be protected from proteolysis by insulin-degrading enzyme (IDE), predicting prolonged activity. Because of this strategy's novelty and potential clinical importance, we sought to validate these findings and test their therapeutic utility in an animal model of diabetes mellitus. Surprisingly, the analogue did not exhibit enhanced stability, and its susceptibility to cleavage by either IDE or a canonical serine protease (glutamyl endopeptidase Glu-C) was similar to WT. Moreover, the analogue's pharmacodynamic profile in rats was not prolonged relative to a rapid-acting clinical analogue (insulin lispro). Although [C7UA, C7UB] does not confer protracted action, nonetheless its comparison to internal diselenide bridges promises to provide broad biophysical insight.",

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author = "Balamurugan Dhayalan and Chen, {Yen Shan} and Phillips, {Nelson B.} and Mamuni Swain and Rege, {Nischay K.} and Ali Mirsalehi and Mark Jarosinski and Faramarz Ismail-Beigi and Norman Metanis and Weiss, {Michael A.}",

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Dhayalan, B, Chen, YS, Phillips, NB, Swain, M, Rege, NK, Mirsalehi, A, Jarosinski, M, Ismail-Beigi, F, Metanis, N & Weiss, MA 2020, 'Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges', Chemistry - A European Journal, vol. 26, no. 21, pp. 4695-4700. https://doi.org/10.1002/chem.202000309

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T1 - Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges

AU - Dhayalan, Balamurugan

AU - Chen, Yen Shan

AU - Phillips, Nelson B.

AU - Swain, Mamuni

AU - Rege, Nischay K.

AU - Mirsalehi, Ali

AU - Jarosinski, Mark

AU - Ismail-Beigi, Faramarz

AU - Metanis, Norman

AU - Weiss, Michael A.

PY - 2020/4/9

Y1 - 2020/4/9

N2 - Long-acting insulin analogues represent the most prescribed class of therapeutic proteins. An innovative design strategy was recently proposed: diselenide substitution of an external disulfide bridge. This approach exploited the distinctive physicochemical properties of selenocysteine (U). Relative to wild type (WT), Se-insulin[C7UA, C7UB] was reported to be protected from proteolysis by insulin-degrading enzyme (IDE), predicting prolonged activity. Because of this strategy's novelty and potential clinical importance, we sought to validate these findings and test their therapeutic utility in an animal model of diabetes mellitus. Surprisingly, the analogue did not exhibit enhanced stability, and its susceptibility to cleavage by either IDE or a canonical serine protease (glutamyl endopeptidase Glu-C) was similar to WT. Moreover, the analogue's pharmacodynamic profile in rats was not prolonged relative to a rapid-acting clinical analogue (insulin lispro). Although [C7UA, C7UB] does not confer protracted action, nonetheless its comparison to internal diselenide bridges promises to provide broad biophysical insight.

AB - Long-acting insulin analogues represent the most prescribed class of therapeutic proteins. An innovative design strategy was recently proposed: diselenide substitution of an external disulfide bridge. This approach exploited the distinctive physicochemical properties of selenocysteine (U). Relative to wild type (WT), Se-insulin[C7UA, C7UB] was reported to be protected from proteolysis by insulin-degrading enzyme (IDE), predicting prolonged activity. Because of this strategy's novelty and potential clinical importance, we sought to validate these findings and test their therapeutic utility in an animal model of diabetes mellitus. Surprisingly, the analogue did not exhibit enhanced stability, and its susceptibility to cleavage by either IDE or a canonical serine protease (glutamyl endopeptidase Glu-C) was similar to WT. Moreover, the analogue's pharmacodynamic profile in rats was not prolonged relative to a rapid-acting clinical analogue (insulin lispro). Although [C7UA, C7UB] does not confer protracted action, nonetheless its comparison to internal diselenide bridges promises to provide broad biophysical insight.

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JO - Chemistry - A European Journal

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Reassessment of an Innovative Insulin Analogue Excludes Protracted Action yet Highlights the Distinction between External and Internal Diselenide Bridges

Abstract

Keywords

All Science Journal Classification (ASJC) codes

UN SDGs

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