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	METTL3 plays a role in alternative pre-mRNA splicing. Indeed, a lack of METTL3 leads to a changement of the gene expression and alternative splicing related to the P53 signaling pathway wich is a tumor protein.		METTL3 plays a role in alternative pre-mRNA splicing. Indeed, a lack of METTL3 leads to a changement of the gene expression and alternative splicing related to the P53 signaling pathway wich is a tumor protein.
	m6A influences the processing of micro-RNAs and long non-coding RNAs splicing, which both are translational controller, and that can garble cancer progression.		m6A influences the processing of micro-RNAs and long non-coding RNAs splicing, which both are translational controller, and that can garble cancer progression.
-	MeTTL3 is directly linked to lung cancer by promotting an increasing translation of mRNAs, and METTL14 is linked to Hepatocellular carcinoma because it	+	MeTTL3 is directly linked to lung cancer by promotting an increasing translation of mRNAs.
		+	METTL14 has a repressing effect in tumor metastasis, but by interacting with DGCR8 (a protein required for micro-RNAs processing) instead of METTL3, it decreases mature micro-RNAs which at first instance inhibits the repressing effect of METTL14 in tumor metastasis, so it promotes growth of cancer cells and espacially Hepatocellular carcinoma.
		+
	== Relevance ==		== Relevance ==

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Revision as of 12:55, 2 January 2019

This Sandbox is Reserved from 06/12/2018, through 30/06/2019 for use in the course "Structural Biology" taught by Bruno Kieffer at the University of Strasbourg, ESBS. This reservation includes Sandbox Reserved 1480 through Sandbox Reserved 1543.

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Contents 1 Crystal structure of the catalytic domains of Mettl3/Mettl14 complex 2 Structural highlights of the METTL3/METTL14 complex 3 Crystal structure 4 Complex METTL3/METTL14 enzymatic working process 5 Function of the modification within the cell 6 Disease and problems triggered by unfunctionnal METTL3/METTL14 complex 7 Relevance 8 References

Crystal structure of the catalytic domains of Mettl3/Mettl14 complex

spinqualitylabelsall models Crystal structure of the catalytic domains of Mettl3/Mettl14 complex Show:Asymmetric Unit Biological Assembly Drag the structure with the mouse to rotate   Export Animated Image

The complex METTL3/METTL14 is a heterodimer enzymatic complex involved into RNA post-transcriptional modifications by humans. This complex is abble to add a methyl group on adenosin of the RNA, by catalyzing a m6(A) modification.The N(6)-methyladenosine (m(6)A) is a quite common, reversible chemical modification of RNAs molecules, which plays a key role in several different biological fonctions. This post-transcriptional modification can be added by WRITERS, recognized by READERS and also removed byr ERASERS. The METTL3/METTL14 complex plays the role of writer.

This enzymatic complex belongs to the second class of enzymes, which are the transferases and to the group of N6A-MTases. The complex is formed by 574 amino acid residues, divided into two different proteins nammed as Methyltransferase Like number 3 and 14.

You may include any references to papers as in: the use of JSmol in Proteopedia ^[1] or to the article describing Jmol ^[2] to the rescue.

Structural highlights of the METTL3/METTL14 complex

[1]

Primary structure This complex is composed of two differents proteins forming two distinct but linked subunits of the enzymatic complex. Each of these two proteins is coded by one different gene. The mettl3 gene codes for the N6-adenosine-methyltransferase 70 kDa subunit, which is a 225 Amino acid chain, whereas the Mettl14 gene codes for the N6-adenosine-methyltransferase subunit METTL14, which is composed of 349 amino acids.

Each of these two proteins are corresponding to the A [2]or the B chain [3] of the complex and are neccessary to the functionning of the whole complex.

Secondary structure

Both polypeptides METTL3 and METTL14 are able to form some secondary structures thank to interchain and intrachain hydrogen bond formation. The core of METTL3 and METTL14 is shaped by Rossman fold domain,comprising a beta sheet edged by four alpha helices

Chain A METTL3'secondary structure, is mainly composed of 20% helical structures (7 helices; 46 residues) and 24% parallel and anti-parallel beta sheets (13 strands; 55 residues)

Chain B METTL14 is made of 24% helical structures (14 helices; 87 residues) and 18% parallel and anti-parallel beta sheets (16 strands; 63 residues)

Tertiary structure Thanks to their primary amino acid sequences both A and B chains have some specific conserved domains directly linked to their function and functionning.

Domains and specific site or sequences

MTD : Methyltransferase domain

METTL3 and MTTL14 have both a methyltranferase domain, which is the domain able to catalyze a methyltransferase reaction. But the complex METTL3/METTL14 has a better methyltransferase activity, than one single subunit activity. Moreover, a mutation in the catalytic center of METTL3 inhibits the hole methyltransferase activity of the complex, whereas a mutation in the catalytic center of METTL14 does not. Thus, METTL3 is the catalytic subunit of the complex and METTL14 enhances the methyltransferasese activity by stabilizing the complex structure and binding to messenger RNA by enabling the recognition of its consensus sequence, GGACU, which is the target for m6A modifications.

Both MTD have approximatly 25% sequence homology.Despite some common point, the methyltransferase domain of METTL14 has extra terminal extensions, with an unusual N-terminal extension which is approximately 50 amino acid long. In the one hand the N-terminal extension create along helix which go through the domain and allow a close contact with the MTD of the catalytic subunit of the complex. This contact is made by several loops and shorter helical segments. In other hand, the C-terminal helix of the MTD of METTL14 is antiparallel to the N-terminal extension helix in order to stabilize its position. This allows the formation of a broad interdomain binding interface,and also other contact point along the terminal extensions, which are stabilizing the positions of both domains neccesary for the function.

spinqualitylabelsall models The zinc finger domain of METTL3 subunit Show:Asymmetric Unit Biological Assembly Drag the structure with the mouse to rotate   Export Animated Image

Zinc finger binding domain of the METTL3 subunit or the CCCH sequence

Zinc finger domain of the METTL3 N6-methyladenosine methyltransferase, is a RNA binding domain of the complex. This perticular domain of the two proteins complex allow the protein to make interactions with the RNA molecule to modify through consensus sequences

The CCCH sequences corresponds to a Cys-Cys-Cys-His motif. This specific motif belongs to METTL3 and belongs to the family of zinc binding motifs There are two od these CCCH motifs near by the methyltransferase domain of METTL3. As zinc-binding motifs such as CCCHs are known for their abilities to bind nucleic acids such as RNA, their presence are required for RNA methylatransferase activity. In case of a punctual mutation in these sequences a loss of the methyltransferase activity is observed, confirming their importance.

METTL3 and METTL14 are linked to each other to form the functionnal complex. So as the METTL3 is responsible of the catalytic activity, the METTL14 allow the allosteric recognition of the RNA. The two subunit bindind creates a cavity in the center of the complex where the enzymatic reaction take place, it is the catalytic center. In these catalytic center some critical amino acid residues for the substrate recognition and specific binding are located.

Crystal structure

To study the crystal structure of the METTL3/METTL14 some crystalograghy experiments have been realized under the following experimental conditions to crystalyze the protein complex:

Method : Vapor Diffusion Hanging Drop

pH 8

Temperature : 291.0 K

Buffer: 0.1 M Tris pH 8.0, 20% PEG3350

After crytalization, crystal had been analyzed through X-Ray diffraction, at 100°C, with a single wavelength coming out of a synchrotron. Thanks to the experiment the following data have been collected to describe the cristal structure of the complex :

Unit Cell caracteristics : Length (Å) a = 101.86 b = 101.86 c = 117.66

Angle (°) α = 90 β = 90 γ = 90

Symmetry : Space Group P 41 21 2

The primitive cubic symmetry of the unit cell is driven by two 2-fold axis rotation. Moreover, within this space group which is acentric, chiral, and enantiomorphic with one single lattice translations, eight different representative symmetry operations are needed to get the whole unit cell.

The crystal structure analysis at 1,65 angstrom allow to collect precise and detailled informations about the whole structure like the side chains and also the hydrogen bonds. (Cristal analysis data at other resolution are available on [4].)

Complex METTL3/METTL14 enzymatic working process

The enzymatic complex of two proteins is abble to realize methylation reactions thanks to its sequence and specific which allow it to catalyze some perticular reactions at given sites.

The complex METTL3/METTL14 belongs to the writers group, which means that theses two proteins are taking part to the protein subunit able to realize the post transcriptional modification of the RNA within the humans cells.

The METTL3/METTL14 complex catalyze the methylation reaction which takes place in the nucleus.

As previously said, the METTL3 is the catalytic component of the methyltransferase complex. So it is responsible of the m6A modifications thanks to its ability to crosslink with an other essential protein the S-adenosylmethionine (SAM).SAM is the substrate donor of the reaction. It is bound in a specific site in METTL3, at the C-ter of beta 1, beta 7, and beta 8 strands. Moreover, METTL3 can be associated with METTL14, which contains its own methyltransferase domain. Even if the precise molecular interactions between the to subunits are unknown, it is known that the both have to associated with each other, but also that aditionnal factors are neccessary to allow the add of a methyl group on the targeted RNA.

After the formation of the minimal complex with the crystallized heterodimer of methyltransferase domains from METTL3 and METTL14 and two CCCH motifs of Mettl3, and the binding of all the factors the RNA modification reaction can take place.

Function of the modification within the cell

Specific, and well controlled methylation of the nucleic acids is essential for proper gene regulation, whatever the studied organism or modification’s type. However the precise molecular role of m6A is unknown, it is known that for most mRNAs, m6A modification appear in long exons, near stop codons, and in 3′ UTRs and that this modification could influence mRNA stability, induce RNA conformational changes, modulate protein-RNA interactions, and even modify microRNA processing One of the most prevalent modifications observed for mRNAs is N6-methyladenosine (m6A). Recent studies have intensely investigated how m6A-modification of RNA contributes to central events in biology. Nonfonctional m6A actors such as writers like METTL3 or METTL14, but also readers, and erasers are oftern linked to problems in self-renewal of stem cells, circadian clock and developmental defects, obesity, synaptic signaling, and cancers.

Disease and problems triggered by unfunctionnal METTL3/METTL14 complex

m6A is a process involved in stem cell differenciation, mamalian circadian clock and embryonic development. Thus, an unfunctional METTL3/METTL14 complex that impacts m6A impacts these mechanisms.

Inhibition of METTL3

m6A stimulates the RNA export out of the nucleus and eases mRNA translation by recruiting EIF3,involved in the initation machinery of translation. therefore, its inhibition could alter the translation process and lead to unfunctional proteins.

Inhibition of METTL14

WTAP splicing factor

Stem cell differenciation

A knockdown of METTL3/METTL14 in embryonic stem cells induces a loss of m6A and an inability of self-renewal. The loss of m6A stops the embryonic stem cell to leave the pluripotent state for differenciation.

Cancer progression

METTL3 plays a role in alternative pre-mRNA splicing. Indeed, a lack of METTL3 leads to a changement of the gene expression and alternative splicing related to the P53 signaling pathway wich is a tumor protein. m6A influences the processing of micro-RNAs and long non-coding RNAs splicing, which both are translational controller, and that can garble cancer progression. MeTTL3 is directly linked to lung cancer by promotting an increasing translation of mRNAs. METTL14 has a repressing effect in tumor metastasis, but by interacting with DGCR8 (a protein required for micro-RNAs processing) instead of METTL3, it decreases mature micro-RNAs which at first instance inhibits the repressing effect of METTL14 in tumor metastasis, so it promotes growth of cancer cells and espacially Hepatocellular carcinoma.

Relevance

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</StructureSection>

References

1. ↑ . PMID:216315890657
2. ↑ . PMID:216315890657

^{[1] [2] [3] [4] [5] [6]}/ ^{[7] [8] [9]}

POUR URSULA :)

m6A RNA Methylation Controls Neural Development and Is Involved in Human Diseases Kunzhao Du, Longbin Zhang[…]Tao Sun Molecular Neurobiology (2018)

The N6-methyladenosine (m6A)-forming enzyme METTL3 controls myeloid differentiation of normal hematopoietic and leukemia cells Ly P Vu, Brian F Pickering[…]Michael G Kharas Nature Medicine (2017)

ET CA AUSSI : ca vient de cette publi : https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4958592/

In an independent study, the Y406C mutation of Mettl3 was identified in large intestine cancer patients (Colon Adenocarcinoma - TCGA, US (reanalyzed by Cancer Genome Project, Sanger Institute); Study ID: COSU376) (Forbes et al., 2015). Thus, we tested how the Y406C mutation affects methyltransferase activity. When full-length Mettl3 with the Y406C mutation is in complex with wild type Mettl14, we can obtain stable protein complexes but cannot observe any significant level of methylation in vitro (Figures 5D, 5E, S1B and S6D). Loss of the tyrosine ring may prevent Mettl3 from interacting properly with the RNA substrate near the adenine to be methylated and catalyzing the methyl transfer.

In our structures, a highly basic patch is found on MTD14, near the MTD3/MTD14 junction close to the catalytic cavity (Figure 5F). One of these basic residues is the highly conserved arginine 298 of Mettl14, which is frequently mutated to proline in endometrial cancer (Uterine Corpus Endometrioid Carcinoma (TCGA, US) import from ICGC; Study ID: COSU419)(Bell, 2014; Forbes et al., 2015) (Figure S5E). Wild type Mettl3 in complex with full-length Mettl14 with the R298P mutation shows significantly decreased methylation activity (Figures 5D, 5E, S1B and S6D). In addition, these complexes can no longer distinguish the cognate RNA target from the mutant RNA substrate. R298 also lies close to the third “fence” loop discussed above, and may have a complex role to affect both rate and RNA specificity. Thus, Mettl14 seems to play a role in substrate recognition as well as structurally supporting the catalytic cavity in Mettl3.'