Journal:CHEMBIOINT:1

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The four-helix bundle in cholinesterase dimers: structural and energetic determinants of stability

Dana A. Novichkova, Sofya V. Lushchekina, Orly Dym, Patrick Masson, Israel Silman and Joel L. Sussman ^[1]

Molecular Tour
The crystal structures of truncated forms of cholinesterases provide good models for assessing the role of non-covalent interactions in dimer assembly in the absence of cross-linking disulfide bonds. These structures identify the four-helix bundle that serves as the interface for formation of acetylcholinesterase and butyrylcholinesterase dimers. Here we performed a theoretical comparison of the structural and energetic factors governing dimerization. This included identification of inter-subunit and intra-subunit hydrogen bonds and hydrophobic interactions, evaluation of solvent-accessible surfaces, and estimation of electrostatic contributions to dimerization. To reveal the contribution to dimerization of individual amino acids within the contact area, free energy perturbation alanine screening was performed. Markov state modelling shows that the loop between the α13 and α14 helices in BChE is unstable, and occupies 4 macro-states. The order of magnitude of mean first passage times between these macrostates is ~10-8 seconds. Replica exchange molecular dynamics umbrella sampling calculations revealed that the free energy of human BChE dimerization is -15.5 kcal/mol, while that for human AChE is -26.4 kcal/mol. Thus, the C-terminally truncated human butyrylcholinesterase dimer is substantially less stable than that of human acetylcholinesterase.

: pink, hAChE (PDB ID 4ey4); gray, mAChE (PDB ID 1j06); blue, TcAChE (PDB ID 1w76); green, DmAChE (PDB ID 1qo9). .

All crystal structures of AChE deposited in the PDB (https://www.rcsb.org) display dimers in which the monomers associate through an antiparallel four-helix bundle. With respect to BChE, crystal structures have been obtained only for monomeric forms of hBChE. In the first hBChE crystal structure obtained (PDB ID 1p0i), of partially glycosylated enzyme expressed in CHO cells, dimers assembling via a . Subsequently, however, a (PDB ID 4aqd) was obtained for fully glycosylated hBChE expressed in Drosophila S2 cells. This dissimilarity of the two crystal structures reveals the high sensitivity of hBChE dimerization to the expression system and crystallization conditions.

In silico alanine screening, (FEP method), for hAChE. . The amino acids, which substitution by alanine led |ΔΔG|>1 kcal/mol are shown and colored in green or red. . These scenes show that in the case of hAChE, stabilization occurs with both hydrophobic residues of helices, and the salt bridge, and electrostatic interactions on helices.

This study was supported by Russian Foundation for Basic Research (project №19-03-00043).

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 All crystal structures of AChE deposited in the PDB (https://www.rcsb.org) display dimers in which the monomers associate through an antiparallel four-helix bundle. With respect to BChE, crystal structures have been obtained only for monomeric forms of hBChE. In the first hBChE crystal structure obtained (PDB ID [[1p0i]]), of partially glycosylated enzyme expressed in CHO cells, dimers assembling via a <scene name='81/817522/Cv/6'>four-helix bundle were not observed</scene>. Subsequently, however, a <scene name='81/817522/Cv/5'>crystal structure in which the dimers did assemble via a four-helix bundle</scene> (PDB ID [[4aqd]]) was obtained for fully glycosylated hBChE expressed in ''Drosophila S2'' cells. This dissimilarity of the two crystal structures reveals the high sensitivity of hBChE dimerization to the expression system and crystallization conditions.
-''In silico'' alanine screening, (FEP method), for hAChE. <scene name='81/817522/Cv/10'>Top view of the dimerization interface of dimer</scene>. The amino acids, which substitution by alanine led |ΔΔG|>1 kcal/mol are shown and colored in green or red. <scene name='81/817522/Cv/11'>Side view of the dimerization interface of one of the monomers</scene>.
+''In silico'' alanine screening, (FEP method), for hAChE. <scene name='81/817522/Cv/10'>Top view of the dimerization interface of dimer</scene>. The amino acids, which substitution by alanine led |ΔΔG|>1 kcal/mol are shown and colored in green or red. <scene name='81/817522/Cv/11'>Side view of the dimerization interface of one of the monomers</scene>. These scenes show that in the case of hAChE, stabilization occurs with both hydrophobic residues of helices, and the salt bridge, and electrostatic interactions on helices.
 This study was supported by Russian Foundation for Basic Research (project №19-03-00043).

Journal:CHEMBIOINT:1

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Revision as of 12:25, 2 June 2019

The four-helix bundle in cholinesterase dimers: structural and energetic determinants of stability

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