Sandbox Reserved 1066

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This Sandbox is Reserved from 02/09/2015, through 05/31/2016 for use in the course "CH462: Biochemistry 2" taught by Geoffrey C. Hoops at the Butler University. This reservation includes Sandbox Reserved 1051 through Sandbox Reserved 1080.

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Mycobacterium tuberculosis very-long-chain fatty acyl-CoA synthetase

1 Introduction
2 Mechanism
- 2.1 General mechanism for the activation of fatty acids
- 2.2 Structural basis for housing lipid substrates longer than the enzyme
3 Structure
4 Disease

Introduction

Mycobacterium tuberculosis very-long-chain fatty acyl-CoA synthetase, also known as FadD13, is unique within its class in regards to its ability to house lipid substrates longer than itself. Most FadD class proteins exist as integral membrane proteins involved in lipid transport into the cell. FadD13 is unique structurally in that it exists as a peripheral protein on the inside of the cell membrane. This feature is key in the mechanistic basis for FadD13's activation and transport of fatty acids of length C24-C26 through the two step addition of Coenzyme A(Figure 1).^[1]

FadD13 may be important in the virulence of Mycobacterium tuberculosis, the etiological agent of tuberculosis, and has emerged as possible target for novel therapeutic agents.^[2]

Mechanism

Figure 1: Mechanism for the activation of fatty acids (C24-C26) by FadD13. The N terminal domain (pink) is embedded in the membrane with the arginine rich lid-loop (dark blue), while the flexile linker (black) connects the C terminal domain (green) to the rest of the enzyme. Activation requires the binding of ATP (blue) which induces structural changes that promote the binding of the fatty acid chain. Formation of an acyl-adenylate intermediate induces a 140° rotation of the C terminal domain and the binding of CoA (orange).

Figure 2: Representation of the two-step reaction catalyzed by FadD13

General mechanism for the activation of fatty acids

FadD13 first activates the fatty acid through a reaction with ATP to form an acyl adenylate intermediate and release pyrophosphate. Following a conformational change of the enzyme, coenzyme A is able to bind and reaction with the acyl adenylate intermediate forming the acyl CoA product (Figure 2).

Structural basis for housing lipid substrates longer than the enzyme

The ability for FadD13 to transport and activate fatty acids of the maximum tested length C26, lies in it being a peripheral membrane protein with a hydrophobic tunnel. FadD13 is attached to the membrane via electrostatic interactions in the N-terminal domain. Of importance in the region is the arginine rich lid-loop which serves to block the transport of fatty acids into the enzyme. Once the lid-loop is opened, fatty acids may be pulled from the membrane into a hydrophobic tunnel, which is the main structural component by which fatty acids are transported from the membrane into the cell. Negatively charged residues at the active site of FadD13 are the driving factor in the attraction of the fatty acid from the membrane through the hydrophobic tunnel of the enzyme.

Structure

FadD13 is composed of 503 amino acid residues divided into three main regions: The (residues 1-395) and (residues 402-503) which are connected via a flexible (residues 396-401).^[1] Each region plays an important role in the activation of fatty acids. The large N-terminal domain has the most structural features, but it is ultimately the flexible linker that allows movement of the C-terminal domain to from the fully functioning active site (Figure 1).

Electrostatics

Figure Legend. Pmyol depiction of electrostatic interaction of FadD13.

The electrostatics of FadD13 as seen in (figure...) illustrate the hydrophobic and positively charged regions that compose this protein. Experimental results revealed that the peripheral FadD13 is attached to the membrane via electrostatic and hydrophobic regions located on the top portion of the N-terminal region (figure 3).^[1] Of key importance in this N-terminal domain region attached to the membrane is an area of notable arginine rich residues, known as the arginine rich lid-loop.

Arginine Rich Lid-loop

The functions to block entry of fatty acids into the hydrophobic tunnel of FadD13.This area on the top portion of the enzyme is also crucial in the association with the membrane as the positively charged arginine residues are attracted to the negative charge on the phospholipid heads.^[1]

Hydrophobic Tunnel

The hydrophobic tunnel of FadD13 is essential to the transport and accommodation of very long fatty acids from the membrane into the cell. This tunnel runs through the middle of FadD13 from the arginine rich lid loop to the ATP binding site and is situated between the and alpha helices α8-α9 and parallel beta sheet β9- β14.^[1]

Active Site

The active site on FadD13 is composed of two conserved regions, one of which serves as the binding site for ATP and the other for CoA. The adenine of ATP is bound to a group of that is structurally identically to other acyl-CoA synthetases. ^[1]

Disease

Mycobacterium tuberculosis is the causative agent involved in the disease tuberculosis.

Relevance

Inhibitors

Future Research

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References

↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 Andersson CS, Lundgren CA, Magnusdottir A, Ge C, Wieslander A, Molina DM, Hogbom M. The Mycobacterium tuberculosis Very-Long-Chain Fatty Acyl-CoA Synthetase: Structural Basis for Housing Lipid Substrates Longer than the Enzyme. Structure. 2012 May 2. PMID:22560731 doi:10.1016/j.str.2012.03.012
↑ Jatana N, Jangid S, Khare G, Tyagi AK, Latha N. Molecular modeling studies of Fatty acyl-CoA synthetase (FadD13) from Mycobacterium tuberculosis--a potential target for the development of antitubercular drugs. J Mol Model. 2011 Feb;17(2):301-13. doi: 10.1007/s00894-010-0727-3. Epub 2010 May, 8. PMID:20454815 doi:http://dx.doi.org/10.1007/s00894-010-0727-3

Similar Proteopedia Pages

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External Resources

Tuberculosis Wikipedia page

Mycobacterium tuberculosis Wikipedia page

Coenzyme A Wikipedia page

Mycolic Acid Wikipedia page

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@@ Line 7: / Line 7: @@
 = Introduction =
 ''Mycobacterium tuberculosis'' very-long-chain fatty acyl-CoA synthetase, also known as FadD13, is unique within its class in regards to its ability to house lipid substrates longer than itself. Most FadD class proteins exist as integral membrane proteins involved in lipid transport into the cell. FadD13 is unique structurally in that it exists as a peripheral protein on the inside of the cell membrane. This feature is key in the mechanistic basis for FadD13's activation and transport of fatty acids of length C24-C26 through the two step addition of [http://en.wikipedia.org/wiki/Coenzyme_A Coenzyme A](Figure 1).<ref name="Our Paper">PMID: 22560731</ref>
@@ Line 14: / Line 13: @@
 = Mechanism =
 [[Image:FadD13 edited image.jpg|400 px|left|thumb|Figure 1: Mechanism for the activation of fatty acids (C24-C26) by FadD13. The N terminal domain (pink) is embedded in the membrane with the arginine rich lid-loop (dark blue), while the flexile linker (black) connects the C terminal domain (green) to the rest of the enzyme. Activation requires the binding of ATP (blue) which induces structural changes that promote the binding of the fatty acid chain. Formation of an acyl-adenylate intermediate induces a 140° rotation of the C terminal domain and the binding of CoA (orange). ]]
 [[Image:acyl coa synthetase.jpg|400 px|left|thumb|Figure 2: Representation of the two-step reaction catalyzed by FadD13]]
 == General mechanism for the activation of fatty acids ==
-FadD13 first activates the fatty acid through a reaction with ATP to form an acyl adenylate intermediate and release pyrophosphate. Following a conformational change of the enzyme, coenzyme A is able to bind and reaction with the acyl adenylate intermediate forming the acyl CoA product (Figure 1).
+FadD13 first activates the fatty acid through a reaction with ATP to form an acyl adenylate intermediate and release pyrophosphate. Following a conformational change of the enzyme, coenzyme A is able to bind and reaction with the acyl adenylate intermediate forming the acyl CoA product (Figure 2).
 == Structural basis for housing lipid substrates longer than the enzyme ==
 The ability for FadD13 to transport and activate fatty acids of the maximum tested length C26, lies in it being a peripheral membrane protein with a hydrophobic tunnel. FadD13 is attached to the membrane via electrostatic interactions in the N-terminal domain. Of importance in the region is the arginine rich lid-loop which serves to block the transport of fatty acids into the enzyme. Once the lid-loop is opened, fatty acids may be pulled from the membrane into a hydrophobic tunnel, which is the main structural component by which fatty acids are transported from the membrane into the cell. Negatively charged residues at the active site of FadD13 are the driving factor in the attraction of the fatty acid from the membrane through the hydrophobic tunnel of the enzyme.
+=Structure =
-= Structure =
+FadD13 is composed of 503 amino acid residues divided into three main regions: The <scene name='69/694233/Domains/1'>N-terminal domain</scene> (residues 1-395) and <scene name='69/694233/C-terminal_domain/1'>C-terminal domain</scene>  (residues 402-503) which are connected via a flexible <scene name='69/694232/Linker_section/2'>linker</scene> (residues 396-401).<ref name="Our Paper"/> Each region plays an important role in the activation of fatty acids. The large N-terminal domain has the most structural features, but it is ultimately the flexible linker that allows movement of the C-terminal domain to from the fully functioning active site (Figure 1).
-== General overview ==
-This is the <scene name='69/698726/Overall_structure_cartoon/1'>overall structure of FadD13</scene>
-FadD13 is composed of 503 amino acid residues divided into three main regions: The <scene name='69/694233/Domains/1'>N-terminal domain</scene> (residues 1-395) and <scene name='69/694233/C-terminal_domain/1'>C-terminal domain</scene>  (residues 402-503) which are connected via a flexible <scene name='69/694232/Linker_section/2'>linker</scene> (residues 396-401).<ref name="Our Paper"/>
@@ Line 38: / Line 30: @@
 == Electrostatics ==
 [[Image:electrostatics fadD13.png|300 px|left|thumb|Figure Legend. Pmyol depiction of electrostatic interaction of FadD13.]]
-The electrostatics of FadD13 as seen in (figure...) illustrate the hydrophobic and positively charged regions that compose this protein. Experimental results from (Paper) revealed that the peripheral FadD13 attached to the membrane via positively charges interacting with the negatively charged cell membrane (image) located on the top portion of the N-terminal region. Of key importance in this N-terminal domain region attached to the membrane is an area of notable arginine rich residues, known as the arginine rich lid-loop.
+The electrostatics of FadD13 as seen in (figure...) illustrate the hydrophobic and positively charged regions that compose this protein. Experimental results revealed that the peripheral FadD13 is attached to the membrane via electrostatic and hydrophobic regions located on the top portion of the N-terminal region (figure 3).<ref name="Our Paper"/> Of key importance in this N-terminal domain region attached to the membrane is an area of notable arginine rich residues, known as the arginine rich lid-loop.
 == Arginine Rich Lid-loop ==
+The <scene name='69/694233/Arginine_rich_lid_loop/1'>arginine rich lid loop</scene> functions to block entry of fatty acids into the hydrophobic tunnel of FadD13.This area on the top portion of the enzyme is also crucial in the association with the membrane as the positively charged arginine residues are attracted to the negative charge on the phospholipid heads.<ref name="Our Paper"/>
-The <scene name='69/694233/Arginine_rich_lid_loop/1'>arginine rich lid loop</scene> functions to block entry of fatty acids into the hydrophobic tunnel of FadD13.
 == Hydrophobic Tunnel ==
 The hydrophobic tunnel of FadD13 is essential to the transport and accommodation of very long fatty acids from the membrane into the cell. This tunnel runs through the middle of FadD13 from the arginine rich lid loop to the ATP binding site and is situated between the and alpha helices α8-α9 and parallel beta sheet  β9- β14.<ref name="Our Paper"/>
 == Active Site ==
+The active site on FadD13 is composed of two conserved regions, one of which serves as the binding site for ATP and the other for CoA. The adenine of ATP is bound to a group of <scene name='69/694232/Adenine_binding_group/2'>six amino acids (300-305)</scene> that is structurally identically to other acyl-CoA synthetases. <ref name="Our Paper"/>
-The active site on FadD13 is composed of two conserved regions, one of which serves as the binding site for ATP and the other for CoA. The adenine of ATP is bound to a group of <scene name='69/694232/Adenine_binding_group/2'>six amino acids (300-305)</scene> that is structurally identically to other acyl-CoA synthetases (Citation for original paper).
 = Disease =
 ''Mycobacterium tuberculosis'' is the causative agent involved in the disease '''tuberculosis'''.