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Desaturation of Fatty Stearoyl-CoA by SCD1

1 Introduction
- 1.1 Overview
2 Structure
3 Function
- 3.1 Desaturation Mechanism
- 3.2 Product Conversion and Release
4 Related Disease
- 4.1 Diabetes and Obesity
- 4.2 Cancer

Introduction

Overview

Stearoyl-CoA Desaturase-1 (SCD1) is an integral membrane protein located in the endoplasmic reticulum and is conserved across all eukaryotes ^[1]. The SCD-1 pictured is expressed in Mus musculus (house mouse). The human homolog, SCD1, shares 85% sequence identity with all four SCD’s found in M. musculus (SCD1-SCD4). The expression of SCD1 is seen mainly in the liver and brain ^[2].

SCD is an enzyme which catalyzes desaturation of a double bond within a fatty acid hydrocarbon chain. The addition of a double bond is necessary for the biosynthesis of monounsaturated fatty acids such as: cholesterol, phospholipids, and triglycerides. The enzyme’s main function is lipid biosynthesis as well as regulating gene expression for lipogensis ^[1].

Saturated vs. Unsaturated Fatty Acid Chain

SCD1 is regulated by transcription and its promoter has multiple binding sites for transcription factors that assist with regulation of lipogenesis ^[2]. It was discovered that when mice were SCD1-deficient, there was no obesity seen in the mice ^[1] This is why SCD1 is a popular target in treating metabolic diseases. Functioning SCD1 creates the balance between the accumulation and use of fats in the body.

SCD-1 is interacts with either of the two different substrates: stearoyl-CoA or palmitoyl-CoA. When SCD1 interacts with stearoyl-CoA and performs desaturation, the product is oleoyl-CoAand has the first cis-double bond introduced into the fatty acid chain. The introduction of the cis-double bond into the hydrocarbon chain will increase fluidity of the lipid bilayer. The process of desaturation is tightly regulated by multiple transcription factors.

The desaturase enzyme also works in combat with inhibitors. SCD1 is affected by hormones, growth factors, and nutritional status ^[2]. Leptin is a hormone that plays a role in regulation of energy homeostasis and is also able to stop SCD-1 expression by activating specific transcription factors to bind to SCD1 promoter and overpower the insulin signals ^[2]. Other negative regulators of SCD include estrogen and glucagon. Interestingly enough, SCD1 can also be inhibited by one’s nutritional status because of the production of polyunsaturated fatty acids (PUFAs).

Structure

SCD1 has arranged in a “mushroom"-like shape ^[3]. The cytosolic domain makes up the crown of the enzyme and the TM domains make up the stem. There is a conserved and catalytic that coordinates two metal molecules (iron or zinc), and make up the di-metal center within the binding pocket.

Binding Pocket

SCD1 consists of a hydrophobic deep within the protein that the substrates will enter ^[4]. The tunnel is regioselective and stereospecific such that the substrate’s binding site lines up C9 and C10 at the kink of the V-shaped tunnel with the di-iron center that consists of an oxygen molecule bound to one of the metals. Precise placement of the atoms near the two iron metals provides the tunnel with regioselectivity and stereospecificity, stabilizing the substrate to allow for desaturation at carbons 9 and 10. The kink is formed by two conserved ^[1]. It is at this kink of the tunnel where desaturation occurs.

Metal Cations

Typically, SCD1 contains a in the core of the protein that contributes to its desaturation function. Crystallized structures of SCD1 indicated a substitution of Zinc as the di-metal center instead of ^[1]. It is proposed that the difference in size of Zinc and Iron (8.8 Å and 9.2 Å respectively) would not affect the structure of SCD (Figure containing all 3 of Treys photos?). However, the substitution of Zinc as the di-iron center is found to inhibit the function of SCD1 due to a farther distance between the two metals compared to iron (Figure containing all 3 of Treys photos) ^[1].

In other di-metal centered enzymes such as ACP desaturase and ribonucleotide reductase, the enzymatic mechanism involves an oxo-bridge: a water molecule that is recruited by the di-iron center to be directly involved in the desaturase mechanism. This water gets deprotonated by the two metal ions and it becomes nucleophilic enough to attack the substrate (Mechanism figure). Based on electron density mapping of SCD1, this oxo-bridge formation is suggested to be short-lived ^[3].

Mutations and Substrate Specificity

Different desaturases have varying catalytic rates depending on the carbon chain length of the substrate. For example, desaturase ChDes1 found in arctic copepod Calanus hyperboreus contains a threonine instead of a at position 104 in SCD1 and other desaturases which caused the loss of desaturase function in 26C substrates while retaining activity with 18C substrates. In SCD3, stacked mutations I112A and Q113L changed the enzyme’s specificity from a 16C to a 18C desaturase ^[1]. It is hypothesized that mutations that occur on TM2 near the substrate binding tunnel change the substrate specificity of SCD1. (Tell Trey to make this as a green link)

Function

Palmitoyl and Stearoyl CoA are substrates of SCD1. These substrates enter the hydrophobic V-shaped tunnel inside SCD1. Hydrogens are removed at the C9, then C10 to introduce the double bond through a desaturation mechanism.

Desaturation Mechanism

SCD Catalytic Mechanism

Due to the novel coordination of histidine residues and lack of presence of a stable oxo-bridge, the mechanism of desaturase activity for SCD1 is unknown. For typical desaturases, the elements involved in catalysis include the di-metal center, metal-bound water and oxygen, electrons from an Electron Transport Chain, and the acyl-CoA substrate. For the proposed mechanism, catalysis occurs in four phases: the binding of water and oxygen to the di-metal complex using Asn261, the nucleophilic activation of the water/oxygen using the ETC, the interaction of the complex with the substrate, and the recovery of the enzyme. The rate-limiting step of the mechanism is the primary elimination reaction on the substrate due to the nucleophilic attack occurring on an already stable C9-C10 sigma bond.

Product Conversion and Release

The acyl-CoA substrate, due to it containing all sigma bonds, is able to freely rotate around its carbon axes to fit into the deep, kinked binding pocket.

Gauche vs. Eclipsed Double Bond Conformation. Change in conformation from substrate to product. The green substrate represents the conformation as the reactant while the orange substrate represents the conformation as the product. Substrates are stacked on top of each other in Fischer projection, with the Fischer angles being formed from C8 to C11. The angle shown (69.4) represents the Fischer angle of the reactant substrate in Gauche conformation. The Fisher angle for the product substrate is 1.1o which indicates Eclipsed conformation.

Upon double bond formation between C9 and C10, the substrate rotates from Gauche conformation to eclipsed conformation across C9 and C10 (Figure). The double bond also restricts rotation along carbons 9 and 10 which likely prevents the substrate from exiting through the site that it entered. To allow for , it is hypothesized that a hydrogen bond between Gln143 and Thr257 is broken which creates a hole below the kink into the hydrophobic core of the enzyme. This would allow for the lateral transfer of the product out of the binding pocket without removing the double bond.

Related Disease

Diabetes and Obesity

Metabolic-related issues such as obesity and diabetes are linked to having a diet high in saturated fats and simple sugars ^[5]. SCD1 catalyzes the desaturation of fully saturated fatty to monounsaturated fatty acid chains and acts as the rate limiting step for this type of desaturation mechanism ^[6]. The deficiency and/or inhibition of SCD1 results in increased insulin sensitivity, reduced body obesity and resistance to diet-induced obesity.

With that being said, SCD1 is being used as a target for treatment of obesity, diabetes, and other metabolic diseases ^[1]. In previous research, a decrease in SCD1 has shown to decrease the expression of lipogenic genes such as fatty acid synthase (FAS), acetyl CoA carboxylase(ACC), and cholesterol 7 alpha-hydroxylase (CYP7A 1) ^[5]. SCD1-deficiency causing lowered expression of these fat-synthesizing genes also represses glycolysis and gluconeogenesis. SCD1 deficiency shows an increase in insulin sensitivity and increase resistance to diet-influenced obesity ^[7]. Overall, changes in cellular concentration of this enzyme can cause positive or negative affects to metabolic processes that are linked with diabetes and obesity.

Cancer

Increased expression levels of SCD1 has shown to enhance cancer cell proliferation. The concentration of monounsaturated fatty acids (MUFAs) is much higher in a cancer cell versus a healthy cell. When expression of SCD1 in breast cancer patients was examined, results indicated that increased expression of SCD1 was associated with shorter patient survival ^[8].

Inhibition of SCD1 can stop cancer cell propagation both directly and indirectly ^[2]. The enzyme directly regulates signaling pathways, and indirectly interrupts the ratio of monounsaturated to saturated fatty acids. SCD1 is proving as a positive potential anticancer therapy, considering the difficulty many patients face when going through multiple rounds of chemotherapy. The reason cancer cells often are able to become resistant to chemotherapeutic drugs is because they possess stem cell-like phenotypes ^[2]. SCD1 inhibition has shown to repress tumor growth from cancer stem cells (CSC) and prevent any new proliferation of the CSC ^[9].

References

↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 ^1.6 ^1.7 Bai Y, McCoy JG, Levin EJ, Sobrado P, Rajashankar KR, Fox BG, Zhou M. X-ray structure of a mammalian stearoyl-CoA desaturase. Nature. 2015 Jun 22. doi: 10.1038/nature14549. PMID:26098370 doi:http://dx.doi.org/10.1038/nature14549
↑ ^2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 Tracz-Gaszewska Z, Dobrzyn P. Stearoyl-CoA Desaturase 1 as a Therapeutic Target for the Treatment of Cancer. Cancers (Basel). 2019 Jul 5;11(7). pii: cancers11070948. doi:, 10.3390/cancers11070948. PMID:31284458 doi:http://dx.doi.org/10.3390/cancers11070948
↑ ^3.0 ^3.1 Shen J, Wu G, Tsai AL, Zhou M. Structure and Mechanism of a Unique Diiron Center in Mammalian Stearoyl-CoA Desaturase. J Mol Biol. 2020 May 27. pii: S0022-2836(20)30367-3. doi:, 10.1016/j.jmb.2020.05.017. PMID:32470559 doi:http://dx.doi.org/10.1016/j.jmb.2020.05.017
↑ Wang H, Klein MG, Zou H, Lane W, Snell G, Levin I, Li K, Sang BC. Crystal structure of human stearoyl-coenzyme A desaturase in complex with substrate. Nat Struct Mol Biol. 2015 Jul;22(7):581-5. doi: 10.1038/nsmb.3049. Epub 2015 Jun , 22. PMID:26098317 doi:http://dx.doi.org/10.1038/nsmb.3049
↑ ^5.0 ^5.1 Gutierrez-Juarez R, Pocai A, Mulas C, Ono H, Bhanot S, Monia BP, Rossetti L. Critical role of stearoyl-CoA desaturase-1 (SCD1) in the onset of diet-induced hepatic insulin resistance. J Clin Invest. 2006 Jun;116(6):1686-95. doi: 10.1172/JCI26991. PMID:16741579 doi:http://dx.doi.org/10.1172/JCI26991
↑ Yokoyama S, Hosoi T, Ozawa K. Stearoyl-CoA Desaturase 1 (SCD1) is a key factor mediating diabetes in MyD88-deficient mice. Gene. 2012 Apr 15;497(2):340-3. doi: 10.1016/j.gene.2012.01.024. Epub 2012 Feb 3. PMID:22326531 doi:http://dx.doi.org/10.1016/j.gene.2012.01.024
↑ Ntambi JM, Miyazaki M, Stoehr JP, Lan H, Kendziorski CM, Yandell BS, Song Y, Cohen P, Friedman JM, Attie AD. Loss of stearoyl-CoA desaturase-1 function protects mice against adiposity. Proc Natl Acad Sci U S A. 2002 Aug 20;99(17):11482-6. doi:, 10.1073/pnas.132384699. Epub 2002 Aug 12. PMID:12177411 doi:http://dx.doi.org/10.1073/pnas.132384699
↑ Holder AM, Gonzalez-Angulo AM, Chen H, Akcakanat A, Do KA, Fraser Symmans W, Pusztai L, Hortobagyi GN, Mills GB, Meric-Bernstam F. High stearoyl-CoA desaturase 1 expression is associated with shorter survival in breast cancer patients. Breast Cancer Res Treat. 2013 Jan;137(1):319-27. doi: 10.1007/s10549-012-2354-4. , Epub 2012 Dec 4. PMID:23208590 doi:http://dx.doi.org/10.1007/s10549-012-2354-4
↑ Li J, Condello S, Thomes-Pepin J, Ma X, Xia Y, Hurley TD, Matei D, Cheng JX. Lipid Desaturation Is a Metabolic Marker and Therapeutic Target of Ovarian Cancer Stem Cells. Cell Stem Cell. 2017 Mar 2;20(3):303-314.e5. doi: 10.1016/j.stem.2016.11.004., Epub 2016 Dec 29. PMID:28041894 doi:http://dx.doi.org/10.1016/j.stem.2016.11.004

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	====Product Conversion and Release====		====Product Conversion and Release====
-	The acyl-CoA substrate, due to it containing all sigma bonds, is able to freely rotate around its carbon axes to fit into the deep, kinked binding pocket.[[Image: Better_Gauch_vs._Eclipse.png\|280 px\|left\|thumb\|Gauche vs. Eclipsed Double Bond Conformation. Change in conformation from substrate to product. The green substrate represents the conformation as the reactant while the orange substrate represents the conformation as the product. Substrates are stacked on top of each other in Fischer projection, with the Fischer angles being formed from C8 to C11. The angle shown (69.4) represents the Fischer angle of the reactant substrate in Gauche conformation. The Fisher angle for the product substrate is 1.1o which indicates Eclipsed conformation.]]Upon double bond formation between C9 and C10, the substrate rotates from Gauche conformation to eclipsed conformation across C9 and C10 (Figure). The double bond also restricts rotation along carbons 9 and 10 which likely prevents the substrate from exiting through the site that it entered. To allow for <scene name='87/877510/Exit_of_substrate/3'>product exit</scene>, it is hypothesized that a hydrogen bond between Gln143 and Thr257 is broken which creates a hole below the kink into the hydrophobic core of the enzyme ~~(Green link)~~. This would allow for the lateral transfer of the product out of the binding pocket without removing the double bond.	+	The acyl-CoA substrate, due to it containing all sigma bonds, is able to freely rotate around its carbon axes to fit into the deep, kinked binding pocket.[[Image: Better_Gauch_vs._Eclipse.png\|280 px\|left\|thumb\|Gauche vs. Eclipsed Double Bond Conformation. Change in conformation from substrate to product. The green substrate represents the conformation as the reactant while the orange substrate represents the conformation as the product. Substrates are stacked on top of each other in Fischer projection, with the Fischer angles being formed from C8 to C11. The angle shown (69.4) represents the Fischer angle of the reactant substrate in Gauche conformation. The Fisher angle for the product substrate is 1.1o which indicates Eclipsed conformation.]]Upon double bond formation between C9 and C10, the substrate rotates from Gauche conformation to eclipsed conformation across C9 and C10 (Figure). The double bond also restricts rotation along carbons 9 and 10 which likely prevents the substrate from exiting through the site that it entered. To allow for <scene name='87/877510/Exit_of_substrate/3'>product exit</scene>, it is hypothesized that a hydrogen bond between Gln143 and Thr257 is broken which creates a hole below the kink into the hydrophobic core of the enzyme. This would allow for the lateral transfer of the product out of the binding pocket without removing the double bond.
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