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Human Sterol O-acyltransferase

1 Introduction
2 Structure
3 Inhibitors
4 Biological Relevance

Introduction

Figure 1. Esterification Reaction of Oleoyl-CoA and Cholesterol catalyzed by SOAT

Sterol O-acyltransferase(SOAT), otherwise known as Acyl-coenzyme A:cholesterol acyltransferase(ACAT), is the first discovered member of the membrane-bound O-acyl transferase or MBOAT enzyme group. MBOAT enzymes are responsible for the transfer of acyl chains onto multiple types of substrates within the cell. There are 11 MBOAT enzyme types that can be found in humans, all of which serve a different function in the overall makeup of human biology.^[1]

SOAT specifically catalyzes the esterification of cholesterol for efficient storage within the cell. Cholesterol is a type of membrane lipid that is responsible for controlling the fluidity and integrity of the membrane, along with other important biological processes. When there are high concentrations of cholesterol in the cell, cholesteryl esters can be formed for storage within the membrane.^[1]

Structure

Tertiary Structure

Figure 2. Tetramer unit of SOAT shown with membrane markers

The overall structure of the enzyme is a structure or a dimer of dimers. The functional building block of SOAT is a which is made up of two identical units. The residues that form the dimer interface are mostly hydrophobic and interact with each other in a shape-complementary manner. Mutating residues within the dimer interface reduced the dimers to monomer fractions, indicating that the dimeric architecture is important for the activity of the enzyme. Each monomer is organized into 9 . The dimerization of SOAT is mainly mediated by extensive van der Waals interactions between TM1 in one protomer and the lumenal segment of TM6 and the cytosolic segment of TM9 in the other. TM1, TM5, TM6 and TM9 from the two protomers enclose a deep hydrophobic pocket that is open to the lumenal side. Numerous hydrophobic residues on TM6 and TM9 from one protomer contact those on TM1 from the other protomer. On the intracellular side, hydrophobic residues on IH1 of each protomer interact with each other to stabilize the dimer. ^[2]

Figure 3. Labeled helices of SOAT within the membrane

Tunnel System

Figure 4. Tunnel system of SOAT

A main structural element of this enzyme is the tunnel systems. There are 3 main tunnels in each monomer: the cytosolic (C) tunnel opening to the cytosol, the transmembrane(T) tunnel opening to the membrane, and the lumenal(L) tunnel opens to the lumen. The C tunnel opens to the cytosol of the cell and is the entrance site for the Acyl CoA into the active site. Surface representations of SOAT indicate that there are 2 alpha helices that block the entrance to the C tunnel, therefore a conformational change needs to occur to move the 2 helices so the substrate can enter the tunnel. The T tunnel opens into the membrane and is where cholesterol enters to have access to the active site. The two substrates are catalyzed by the H460 in the active site to form the cholesteryl ester. The products then leave via different pathways. The CoA-SH in the C tunnel leaves via that tunnel and is released back into the cytosol. The cholesteryl ester then leaves via either the T tunnel into the membrane or through the L tunnel into the lumen of the cell. ^[2]

Active Site

The substrate is shown bound to SOAT to visualize the binding pocket and the 3 main residues that are essential for the catalytic activity. work to stabilize the substrates as well as serve other roles in the mechanism of action. Histidine is commonly used as the catalytic base for many acyl transferase reactions. H460 is highly conserved across a variety of species and is essential for SOAT catalysis. It is assumed to be the most important catalytic residue.^[1] Mutating this histidine at position 460 to alanine completely abolishes enzymatic activity, indicating its essential role in the catalytic mechanism.^[2] SOAT activity also relies on several other highly conserved residues within the interior of the central cavitity. This high preservation of residues suggests that the local environment plays a major role in SOAT activity.

Catalytic Mechanism

The distal-most nitrogen on H460 acts as a base catalyst to deprotonate the hydroxyl group of a cholesterol molecule. This leaves the cholesterol oxygen with a negative charge, making it a good nucleophile. The nucleophilic oxygen attacks the Acyl CoA substrate at the carbonyl carbon, kicking electron density up to the carbonyl oxygen. Shown in brackets, the transition state is stabilized by N421 and newly protonated H460.

Figure 5. Esterification Reaction of SOAT with arrow pushing

From the transition state, excess electron density on the carbonyl oxygen is collapsed back into a double bond. This causes the bond between the carbonyl carbon and sulfur to break, shifting electron density to the sulfur atom. To complete the mechanism, the negatively charged sulfur would reclaim the hydrogen from protonated H460. Acyl CoA would exit the active site as a leaving group, leaving its R group attached to cholesterol in the form of a cholesterol ester.

It should be noted that this mechanism is largely hypothesized. Further analysis is needed to confirm the proposed steps. Additionally, mutations of W420A rendered the SOAT enzyme nonfunctional, indicating that it must be essential for catalytic activity. However, its role in the mechanism was not explicitly hypothesized. We believe that it plays a role in substrate binding through with CoenzymeA.

Inhibitors

CI-976 inhibits SOAT activity in a dose-dependent manner. The location of CI-976 is found right in the with its large trimethoxyphenyl head sandwiched right between the catalytic residues . This suggests that CI-976 inhibits the enzyme by preventing the loading of the substrate into the catalytic center, which makes sense given the competitive behavior of CI-976. Mutations of CI-976 interaction residues, N421A, H460A, and H460N greatly diminish the enhancement effect of CI976 on the thermostability of the SOAT dimer.

Biological Relevance

SOAT can actually use multiple sterols as substrates and activators. Because of its functional importance, SOAT is a potential drug target for Alzheimer’s disease, atherosclerosis, and several types of cancers. Alzheimer’s disease (AD) is a progressive disease that severely hinders a person’s memory and other cognitive functions. AD is the result of a significant increase in beta-amyloid (Aβ) peptide concentration. ^[3] Previous studies have found that the amount and distribution of intracellular cholesterol plays an important role in regulating Aβ production.^[4] Therefore, SOAT inhibition could be an effective therapy for treating AD because it would reduce cholesteryl ester formation in the brain and help lower Aβ generation as well. ^[3] ^[4] Another disease SOAT inhibition could help treat is atherosclerosis. Buildup of cholesteryl esters from SOAT catalysis has been shown to be partially responsible for foam cell formation, one of the major indicators of atherosclerosis. Consequently, SOAT inhibitors have been studied as potential drug targets for this disease.^[5] Increased expression of SOAT and abnormal accumulation of cholesteryl esters has also been found in multiple cancers including ovarian cancer. Therefore, inhibiting SOAT and exhausting cholesteryl ester concentrations has shown to have anti-tumor effects in terms of monitoring apoptosis, cell proliferation, and migration and invasion properties. Therapies that target SOAT regulation and expression levels could thus lead to potential treatments for ovarian and other types of cancer.^[6] In general, targeting SOAT could be an effective means for treating various diseases. Aberrant quantities of cholesteryl esters seem to hinder various cellular processes; thus, inhibiting SOAT expression and functionality could help reduce these adverse effects. Overall, SOAT plays an important role in cholesterol homeostasis and future research of this enzyme could lead to the discovery of therapeutic treatments for different illnesses.

References

↑ ^1.0 ^1.1 ^1.2 Guan C, Niu Y, Chen SC, Kang Y, Wu JX, Nishi K, Chang CCY, Chang TY, Luo T, Chen L. Structural insights into the inhibition mechanism of human sterol O-acyltransferase 1 by a competitive inhibitor. Nat Commun. 2020 May 18;11(1):2478. doi: 10.1038/s41467-020-16288-4. PMID:32424158 doi:http://dx.doi.org/10.1038/s41467-020-16288-4
↑ ^2.0 ^2.1 ^2.2 Qian H, Zhao X, Yan R, Yao X, Gao S, Sun X, Du X, Yang H, Wong CCL, Yan N. Structural basis for catalysis and substrate specificity of human ACAT1. Nature. 2020 May;581(7808):333-338. doi: 10.1038/s41586-020-2290-0. Epub 2020 May, 13. PMID:32433614 doi:http://dx.doi.org/10.1038/s41586-020-2290-0
↑ ^3.0 ^3.1 Bhattacharyya R, Kovacs DM. ACAT inhibition and amyloid beta reduction. Biochim Biophys Acta. 2010 Aug;1801(8):960-5. doi: 10.1016/j.bbalip.2010.04.003. , Epub 2010 Apr 14. PMID:20398792 doi:http://dx.doi.org/10.1016/j.bbalip.2010.04.003
↑ ^4.0 ^4.1 Huttunen HJ, Kovacs DM. ACAT as a drug target for Alzheimer's disease. Neurodegener Dis. 2008;5(3-4):212-4. doi: 10.1159/000113705. Epub 2008 Mar 6. PMID:18322393 doi:http://dx.doi.org/10.1159/000113705
↑ Chang C, Dong R, Miyazaki A, Sakashita N, Zhang Y, Liu J, Guo M, Li BL, Chang TY. Human acyl-CoA:cholesterol acyltransferase (ACAT) and its potential as a target for pharmaceutical intervention against atherosclerosis. Acta Biochim Biophys Sin (Shanghai). 2006 Mar;38(3):151-6. doi:, 10.1111/j.1745-7270.2006.00154.x. PMID:16518538 doi:http://dx.doi.org/10.1111/j.1745-7270.2006.00154.x
↑ Ayyagari VN, Wang X, Diaz-Sylvester PL, Groesch K, Brard L. Assessment of acyl-CoA cholesterol acyltransferase (ACAT-1) role in ovarian cancer progression-An in vitro study. PLoS One. 2020 Jan 24;15(1):e0228024. doi: 10.1371/journal.pone.0228024., eCollection 2020. PMID:31978092 doi:http://dx.doi.org/10.1371/journal.pone.0228024

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@@ Line 20: / Line 20: @@
 === Catalytic Mechanism ===
-The distal-most nitrogen on H460 acts as a base catalyst to deprotonate the hydroxyl group of a cholesterol molecule. This leaves the cholesterol oxygen with a negative charge, making it a good nucleophile. The [https://en.wikipedia.org/wiki/Nucleophile nucleophilic] oxygen attacks the Acyl CoA substrate at the carbonyl carbon, kicking electron density up to the carbonyl oxygen. Shown in brackets, the transition state is stabilized by N421 and newly protonated H460.
+The distal-most nitrogen on H460 acts as a base catalyst to deprotonate the hydroxyl group of a cholesterol molecule. This leaves the cholesterol oxygen with a negative charge, making it a good nucleophile. The [https://en.wikipedia.org/wiki/Nucleophile nucleophilic] oxygen attacks the Acyl CoA substrate at the carbonyl carbon, kicking electron density up to the carbonyl oxygen. Shown in brackets, the transition state is stabilized by N421 and newly protonated H460. [[Image:6p2pMechanism.png|600 px|right|thumb|'''Figure 5.''' Esterification Reaction of SOAT with arrow pushing]]
 From the transition state, excess electron density on the carbonyl oxygen is collapsed back into a double bond. This causes the bond between the carbonyl carbon and sulfur to break, shifting electron density to the sulfur atom. To complete the mechanism, the negatively charged sulfur would reclaim the hydrogen from protonated H460. Acyl CoA would exit the active site as a [https://en.wikipedia.org/wiki/Leaving_group leaving group], leaving its R group attached to cholesterol in the form of a cholesterol ester.
-[[Image:6p2pMechanism.png|700 px|right|thumb|'''Figure 5.''' Esterification Reaction of SOAT with arrow pushing]]
 It should be noted that this mechanism is largely hypothesized. Further analysis is needed to confirm the proposed steps. Additionally, mutations of W420A rendered the SOAT enzyme nonfunctional, indicating that it must be essential for catalytic activity. However, its role in the mechanism was not explicitly hypothesized. We believe that it plays a role in substrate binding through <scene name='87/879459/W420_intx/1'>hydrophobic interactions</scene> with CoenzymeA.