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Lysine Methyl Transferase, Homo Sapiens

1 Introduction
- 1.1 Histone Methylation
2 The Substrate
3 The SAM Cofactor
4 KMT Structure
5 Inhibitors
6 References

Introduction

Histone Methylation

Histone proteins aid in the packing of DNA for the purpose of compacting the genome in the nucleus of the cell and regulating physical accessibility of genes for transcription. The protein itself is an octamer made of heterodimer core proteins H2a, H2b, H3, and H4, with H1 and H5 acting as linker proteins. About 145-157 base pairs wind around a histone core protein. (1) Modifications to histone core proteins can affect the accessibility of genes in the genome and their ability to be transcribed. Some of these modifications include methylation/demethylation, acetylation/deacetylation, and ubiquitination/deubiquitination. (2)

Specifically, histone methylation is associated with gene activation. (3) Many domain families fall under the Histone methylase family, one of these enzymes being the SET7 domain family, which can target H3, H4, or H2a; each of these methylation sites can have different effects on gene expression within the genome. Typically, methylation of some of these sites are always present on both active and inactive genes, extra methylations required for activity. (4) Some tumor related genes such as p53 are site specifically methylated to promote biological function (5), whereas hypomethylation of CpG is linked to tumor genesis. (2) A particular enzyme in the SET7 domain family is lysine methyltransferase, which acts on the histone by adding a methyl group to Lys4 on H3; the addition results in promotion of gene unwinding and gene transcription. (4,3)

The Substrate

The SAM Cofactor

KMT Structure

Composition

The secondary structure is composed of 10% and 37% . The helical composition includes 3 , with two residing in the SET domain and one in the C-terminal domain. The alpha helices in the SET domain are two turns while the C-terminal helix is by far the largest with 4 turns. There are also 2 in the SET domain which are each one turn. There are 21 total beta strands which reside in the N-terminal domain and the SET domain. The beta strands are primarily anti-parallel and multiple antiparallel strands are connected by and beta turns.

The C-Terminal Domain

The of lysine methyltransferase is essential for the catalytic activity of the enzyme. Hydrophobic packing of the C-terminal segment (residues 345-366) forms the lysine access channel. Residues 337-349 create a that stabilizes the orientation of two tyrosine residues Tyr 335 and Tyr337 that form the lysine access channel. The hydrophobic packing of the C-terminal against beta sheet 19 (specifically residue 299) orient the SAM cofactor so the methyl donating group is oriented toward the lysine access channel. donating group is oriented toward the lysine access channel.

The Active Site

The active site and binding pocket of KMT have several essential characteristics for the overall efficiency. First, the lysine of the histone enters the active site “with difficulty” which is facilitated by the faces of flanking . Once in the active site, the alkyl part of the histone chain is stabilized by the , and polar residues are stabilized by hydrogen bonding interactions on the surface. The Y335 and Y337 are also essential for stabilization of histone chain via hydrogen bonding. The itself contains the cofactor S-adenosyl methionine (SAM) which donates the methyl group in the reaction. The reaction is catalyzed by Y305, Y245, carbonyl oxygens of the main chain in residues 295 and 290. Y305 and the carbonyl oxygens stabilize and pull electron density off a water to pull on one of the hydrogens off the nitrogen of the lysine, while oxygen of Y245 pulls on the other hydrogen of the nitrogen. Both of these actions allow nitrogen to become more nucleophilic and attack the carbon of the methyl group on the SAM, which is attached to a positively charged sulfur. The methyl group is then transferred and the sulfur is neutral; SAM has been converted to S-adenosyl homocysteine (SAH).

Inhibitors

Sinefungin is a potent methyltransferase inhibitor. It is a structural analog of S-adenosylmethionine that is more stable due to the ability to create two additional hydrogen bonds to its amine group in the active site. It has been used experimentally to inhibit the SET 7/9 protein on peritoneal fibrosis in mice and in human peritoneal mesothelial cells. Tamura et al. (2018) found that sinefungin suppressed the cell accumulation and thickening in methylglyoxal peritoneal fibrosis.

References

Proteopedia Page Contributors and Editors (what is this?)

Madeleine Wilson

Retrieved from "http://52.214.119.220/wiki/index.php/User:Madeleine_Wilson/Sandbox_1"

@@ Line 1: / Line 1: @@
-==Human DNA lysine methyltransferase==
+=Lysine Methyl Transferase, ''Homo Sapiens''=
-<StructureSection load='1o9s' size='350' frame='true' side='right' caption='Human KMT 1o9s'>
+<StructureSection load='1O9S' size='350' frame='true' side='right' caption='Lysine Methyl Transferase' scene=’C_terminal_domain’>
-This is a default text for your page '''Madeleine Wilson/Sandbox 1'''. Click above on '''edit this page''' to modify. Be careful with the &lt; and &gt; signs.
+<references/>
-You may include any references to papers as in: the use of JSmol in Proteopedia <ref>DOI 10.1002/ijch.201300024</ref> or to the article describing Jmol <ref>PMID:21638687</ref> to the rescue.
-== Function ==
+== Introduction ==
-===binding===
-[[Image:Binding_w_lines.jpg|200 px|left|thumb|Figure Legend ]]
+===Histone Methylation===
-<scene name='81/811092/Set7spacefill/2'>SET7 space fill</scene>
+Histone proteins aid in the packing of DNA for the purpose of compacting the genome in the nucleus of the cell and regulating physical accessibility of genes for transcription. The protein itself is an octamer made of heterodimer core proteins H2a, H2b, H3, and H4, with H1 and H5 acting as linker proteins. About 145-157 base pairs wind around a histone core protein. (1) Modifications to histone core proteins can affect the accessibility of genes in the genome and their ability to be transcribed. Some of these modifications include methylation/demethylation, acetylation/deacetylation, and ubiquitination/deubiquitination. (2)
-===mechanism===
-== Disease ==
-===cancer===
-== Relevance ==
-== Structural highlights ==
+Specifically, histone methylation is associated with gene activation. (3) Many domain families fall under the Histone methylase family, one of these enzymes being the SET7 domain family, which can target H3, H4, or H2a; each of these methylation sites can have different effects on gene expression within the genome. Typically, methylation of some of these sites are always present on both active and inactive genes, extra methylations required for activity. (4) Some tumor related genes such as p53 are site specifically methylated to promote biological function (5), whereas hypomethylation of CpG is linked to tumor genesis. (2) A particular enzyme in the SET7 domain family is lysine methyltransferase, which acts on the histone by adding a methyl group to Lys4 on H3; the addition results in promotion of gene unwinding and gene transcription. (4,3)
-===SET7===
-This is a sample scene created with SAT to <scene name="/12/3456/Sample/1">color</scene> by Group, and another to make <scene name="/12/3456/Sample/2">a transparent representation</scene> of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.
+==The Substrate==
-<scene name='81/811092/Set7_rotate/3'>SET 7 Domain (orange)</scene>
+==The SAM Cofactor==
-<scene name='81/811092/Set7_rotate/4'>SET7 Domain (orange)</scene>
+==KMT Structure==
-<scene name='81/811092/Tyrosine_channel/2'>Tyrosine Channel</scene>
+===Composition===
-<scene name='81/811092/Hydrophobic_binding_pocket/1'>Hydrophobic Binding Pocket</scene>
+The secondary structure is composed of 10% <scene name='81/811086/Helices/3'>helices</scene> and 37% <scene name='81/811086/Beta_sheets/3'>beta sheets</scene>. The helical composition includes 3 <scene name='81/811086/Alpha_helices/4'>alpha helices</scene>, with two residing in the SET domain and one in the C-terminal domain. The alpha helices in the SET domain are two turns while the C-terminal helix is by far the largest with 4 turns. There are also 2 <scene name='81/811086/3-10_helices/4'>3-10 helices</scene> in the SET domain which are each one turn. There are 21 total beta strands which reside in the N-terminal domain and the SET domain. The beta strands are primarily anti-parallel and multiple antiparallel strands are connected by <scene name='81/811086/Type_i_beta_turns/3'>Type I</scene> and <scene name='81/811086/Type_ii_beta_turns/2'>Type II</scene> beta turns.
-<scene name='81/811092/Active_site_w_water/1'>Active site with water</scene>
+===The C-Terminal Domain===
-<scene name='81/811092/Active_site_w_water/2'>Active site with water</scene>
+The <scene name='81/811091/C_terminal_domain/1'>C-terminal segment</scene> of lysine methyltransferase is essential for the catalytic activity of the enzyme. Hydrophobic packing of the C-terminal segment (residues 345-366) forms the lysine access channel. Residues 337-349 create a <scene name='81/811086/Beta_hairpin/2'>beta hairpin structure</scene> that stabilizes the orientation of two tyrosine residues Tyr 335 and Tyr337 that form the lysine access channel. The hydrophobic packing of the C-terminal <scene name='81/811091/C_terminal_domain/7'>alpha helix</scene> against beta sheet 19 (specifically residue 299) orient the SAM cofactor so the methyl donating group is oriented toward the lysine access channel. donating group is oriented toward the lysine access channel.
-<scene name='81/811092/Full_binding_pocket/1'>Full binding pocket</scene>
+===The Active Site===
-<scene name='81/811092/Tyrosine_channel_2/1'>Tyrosine channel</scene>
+The active site and binding pocket of KMT have several essential characteristics for the overall efficiency. First, the lysine of the histone enters the active site “with difficulty” which is facilitated by the faces of flanking <scene name='81/811092/Tyrosine_channel_2/1'>Tyrosines (Y35, Y37)</scene>. Once in the active site, the alkyl part of the histone chain is stabilized by the <scene name='81/811092/Hydrophobic_binding_pocket/1'>Hydrophobic Binding Pocket</scene>, and polar residues are stabilized by hydrogen bonding interactions on the surface. The Y335 and Y337 are also essential for stabilization of histone chain via hydrogen bonding.
+The <scene name='81/811092/Active_site_w_water/2'>Active site</scene> itself contains the cofactor S-adenosyl methionine (SAM) which donates the methyl group in the reaction. The reaction is catalyzed by Y305, Y245, carbonyl oxygens of the main chain in residues 295 and 290. Y305 and the carbonyl oxygens stabilize and pull electron density off a water to pull on one of the hydrogens off the nitrogen of the lysine, while oxygen of Y245 pulls on the other hydrogen of the nitrogen. Both of these actions allow nitrogen to become more nucleophilic and attack the carbon of the methyl group on the SAM, which is attached to a positively charged sulfur. The methyl group is then transferred and the sulfur is neutral; SAM has been converted to S-adenosyl homocysteine (SAH).
+==Inhibitors==
+Sinefungin is a potent methyltransferase inhibitor. It is a structural analog of S-adenosylmethionine that is more stable due to the ability to create two additional hydrogen bonds to its amine group in the active site. It has been used experimentally to inhibit the SET 7/9 protein on peritoneal fibrosis in mice and in human peritoneal mesothelial cells. Tamura et al. (2018) found that sinefungin suppressed the cell accumulation and thickening in methylglyoxal peritoneal fibrosis.
-</StructureSection>
 == References ==
-<references/>