Molecular Basis of Catalytic Chamber-assisted Unfolding and Cleavage of Human Insulin by Human Insulin-degrading Enzyme

Marika Manolopoulou,Qing Guo,Enrico Malito,Alexander B Schilling,Wei-Jen Tang

doi:10.1074/jbc.m900068200

Marika Manolopoulou, Qing Guo + Show 3 more

Open Access

https://doi.org/10.1074/jbc.m900068200

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Abstract

Insulin is a hormone vital for glucose homeostasis, and insulin-degrading enzyme (IDE) plays a key role in its clearance. IDE exhibits a remarkable specificity to degrade insulin without breaking the disulfide bonds that hold the insulin A and B chains together. Using Fourier transform ion cyclotron resonance (FTICR) mass spectrometry to obtain high mass accuracy, and electron capture dissociation (ECD) to selectively break the disulfide bonds in gas phase fragmentation, we determined the cleavage sites and composition of human insulin fragments generated by human IDE. Our time-dependent analysis of IDE-digested insulin fragments reveals that IDE is highly processive in its initial cleavage at the middle of both the insulin A and B chains. This ensures that IDE effectively splits insulin into inactive N- and C-terminal halves without breaking the disulfide bonds. To understand the molecular basis of the recognition and unfolding of insulin by IDE, we determined a 2.6-A resolution insulin-bound IDE structure. Our structure reveals that IDE forms an enclosed catalytic chamber that completely engulfs and intimately interacts with a partially unfolded insulin molecule. This structure also highlights how the unique size, shape, charge distribution, and exosite of the IDE catalytic chamber contribute to its high affinity ( approximately 100 nm) for insulin. In addition, this structure shows how IDE utilizes the interaction of its exosite with the N terminus of the insulin A chain as well as other properties of the catalytic chamber to guide the unfolding of insulin and allowing for the processive cleavages.

Highlights

IDE3 is an ϳ110-kDa zinc metalloprotease that is evolutionarily conserved from bacteria to humans [1, 2]
matrixassisted laser desorption ionization (MALDI)-TOF Analysis of the Degradation of Human Insulin by Human insulindegrading enzyme (IDE)—The determination of the precise cleavage sites and reaction products was originally derived from the HPLC profile of individually purified, reduced insulin fragments, and the termination of Edman degradation of porcine [125I]iodo-insulin cleaved by rat IDE [4, 15, 16]
The reaction products of cleaved A and B chains linked by disulfide bond(s) are inferred from the mass derived from cleavage sites of the reduced samples and not directly derived from the fragmentation of precursor ions

Summary

Introduction

IDE3 is an ϳ110-kDa zinc metalloprotease that is evolutionarily conserved from bacteria to humans [1, 2]. This structure shows how IDE utilizes the interaction of its exosite with the N terminus of the insulin A chain as well as other properties of the catalytic chamber to guide the unfolding of insulin and allowing for the processive cleavages. The molecular basis of how the catalytic chamber of IDE binds, unfolds, and cleaves insulin into pieces and how the flexibility of this substrate contributes to its cleavage by IDE remain elusive.

Results

Conclusion