Sandbox Reserved 1106

From Proteopedia

(Difference between revisions)

Revision as of 15:02, 15 January 2020

This Sandbox is Reserved from 25/11/2019, through 30/9/2020 for use in the course "Structural Biology" taught by Bruno Kieffer at the University of Strasbourg, ESBS. This reservation includes Sandbox Reserved 1091 through Sandbox Reserved 1115.

To get started:

Click the edit this page tab at the top. Save the page after each step, then edit it again.
show the Scene authoring tools, create a molecular scene, and save it. Copy the green link into the page.
Add a description of your scene. Use the buttons above the wikitext box for bold, italics, links, headlines, etc.

More help: Help:Editing

Argonaute 1 (PDB 4KXT)

The AGO1 protein is part of the Argonaute family of proteins [Argonaute]. It is ubiquitously expressed in all higher eukaryotes. Similarly to other proteins of the family, it intervenes in the function of RNA interference through the binding of siRNA and the forming of RISC complexes. Unlike other Argonaute proteins, it can act by itself in the case of a “minimal RISC” by blocking instead of destroying the mRNA. For other proteins of the family, see Argonaute.

1 Structure
- 1.1 Length and domains
- 1.2 Mutations domains
  - 1.2.1 Restoration of slicing activity
2 Function
- 2.1 Non proteolytic activity
- 2.2 Role in RISC complex
3 Applications
- 3.1 Cancer Research

Structure

Length and domains

More details on the 3D structure domains, see the page Argonaute 3D structures in the rubrik Argonaute 1

Primary Structure

The Ago1 protein has the same 4 primary domains as all argonaut (N, PAZ, Mid, PIWI, describe in the page Argonaute) and the two linker regions L1 (also called DUF1785 domain) and L2. Indeed, there is 84% of similitudes between the primary sequence of hAgo1 and hAgo2. Besides the N domain is interacting with L1, L2 and PIWI domains via residues 18-48 and 138-173.

Besides, Argonaute 1 can be found in a lot of phylogenetic groups, with different structure. For example, in the plant Brachypodium distachyon, where 10 argonautes proteins have been discovered, BdAGO1 lacks the N and Mid domains. This particularity explains the small size of this protein with only 624 residues. Moreover, BdAGO1 is related to Ago1 since the catalytic tetrad in the PIWI domain doesn’t work for it, enabling an endonuclease activity due to a missing of the last D/H residue

However, the AtAGO1 (from Arabidopsis thaliana), which can be find in the nucleus and the cytoplasm of the plant, owns a Mid domain and its conformation is homologous to BdAO9, BdAGO11, BdAGO12, BdAGO15, and BdAGO16. On the other hand, BdAGO1 has AtAGO4 as its closest homolog (like BaAGO2, BdAGO3 and BdAGO4), even if the AtAGO4 possess a Mid Domain.

Associated Proteins with Ago1

The Argonaute 1 protein can be associated with others molecular components of the cell. Therefore, proteomic analysis has demonstrated that RNase III Dicer binds hAgo1 through the PIWI domain (see page on argonaute) and also, at least, four other proteins in specific association with hAgo1:

• TNRC6B isoform 1 / KIAA1093 (175kDa) which has RRM motif at C-term to recognize RNA, and also GW repeats (trinucleotide motifs)

• MOV10 (130kDa)

• PRMT5 (arginine methyl-transferase) (70kDa)

• And, with more doubts, the translation factor eEF1α (50kDa)

hAgo1 in a complex with let-7

The hAgo1 interact with an endogenous let-7 in a homologous manner as hAgo2 interact with miR20a, but with some slightly differences. From a domain point of view, the position of L1 linker is the same for hAgo1/let-7 and hAgo2/miR20a, as well as the N subdomain (from residues K49 to S137 of the N domain) interaction with the endogenous sequence is the globally the same for both Ago1 and hAgo2 except a 3A translation toward the PIWI domain in hAgo1. Besides the piece of information gets from the N subdomain may suggest an interaction with the guide-target duplexes. On the other hand, the PAZ domain is folded differently in hAgo1/let-7 in order to be placed away from the PIWI domain.

Then, from a nucleotide point of view, hAgo1 shows 6 RNA-specific interactions with ribose 2’OH of let-7 (U1, G2, G4, G5, A7 and A8). There are either direct or water-mediated through the side- or main- chain atoms of hAgo1 like for hAgo2/miR20a. However, there is one interaction presents in hAgo2/miR20a that is missing in hAgo1/let-7 ; it is the one with U6 since this base is slightly modified because of the shift of α7 in the L2 toward the N domain. Furthermore, the first adenine base has a syn conformation around the glycosidic bond and the last two bases are piled in the PAZ domain

Finally, one of the most important aspect is the non-5’ phosphorylated strand ; indeed the U1 base of let-7 and the 5’P of hAgo1 are interacted with protein residues of the Mid and PIWI domains which avoid an interaction between them, preventing a phosphorylation which is important for accurate slicing activity.

Knowing that the nine first 9 nucleotids of let-7 are: 5’AAUAUUAAA3’.

GW motifs

The hAGO1 protein has a single GW binding site. This site is able to bind to GW/WG motifs of other proteins, such as GW182. It is contained in the PIWI domain, also found in AGO2. Proteins like GW182 form with their GW motif a “hook” which interacts with the PIWI domain and enables the docking of the protein in a tryptophan-binding pocket of AGO1. This interaction is enhanced through the binding of an miRNA to AGO1, which ensures that mature RISC can be recruited efficiently for silencing. Through this kind of interaction, several AGO1 proteins can bind to a single protein with GW motifs.

DDB2 and Ago 1 complex

In the case of UV-irradiation response, it has been shown that AGO1 can form complexes with DNA Damage Binding (DDB) proteins and uviRNAs. The specific mechanisms of binding and binding sites have not yet been uncovered.

Mutations domains

Restoration of slicing activity

Among the four human Argonaute proteins, only hAGO2 is an active slicer. A conserved catalytic triad within the PIWI domain in hAGO2 is required for its slicing activity and hAGO1 has an arginine in place of the active site histidine in the DEDH tetrad. Yet, restoring an intact catalytic DEDH tetrad with a R805H mutation is not enough to activate slicing in hAGO1. Therefore, it appears more distant regions of the enzyme are determinant for slicer activity. Domain-swapping experiments revealed that the substitution of the hAGO1 and hAGO2 PIWI domain activates hAGO1 while hAGO2 slicing activity is being removed; providing new evidence that other factors, in addition to the incomplete DEDH tetrad, are responsible for the slicer defect in hAGO1. Indeed, an additional mutation of L674F on the PIWI loop 3 adjacent to the active site of hAGO1 leads to an active slicer with level comparable to that of the hAGO2 PIWI domain swap. Intriguingly, the elements that make hAGO1 an active slicer involve a sophisticated interplay between the active site and more distant regions of the enzyme.

Function

Non proteolytic activity

Unlike hAGO2, hAGO1 does not function as an endonuclease that can cleave mRNA molecules within regions that base pair with perfectly complementary siRNAs or miRNAs. The mechanism by which hAGO1 mediates translational repression is still a matter of debate. hAGO1 has been shown to act on translation initiation, on translation elongation and on the degradation of nascent polypeptides. Therefore, the mechanisms by which hAGO1 inhibit translation might depend on the target that is being regulated. Such a model, however, remains to be experimentally proven. It was shown very recently that upon cell-cycle arrest in human cells, hAGO1 bind to the 3’ UTRs of specific mRNAs and stimulate translation. Interestingly, hAGO1 proteins inhibit translation in proliferating cells and it has therefore been suggested that hAGO1-mediated translational regulation oscillates between repression and activation during the cell cycle.

Role in RISC complex

The AGO1 protein is part of the RNA-induced silencing complex RISC, which is required in the RNA interference process. In this case, the miRNAs, interacting with hAGO1, bind to partially complementary target sites located in the 3’ unstranslated regions (UTRs) of their specific target mRNAs. Imperfect base pairing between small RNAs and their target mRNAs leads to repression of translation and/or deadenylation (removal of the poly(A) tail) of the target, followed by destabilization of the target, which most probably occurs in P-bodies.

Applications

Cancer Research

Studies have linked a reduced amount of Argonaute proteins in cells with an increase in tumour development and progression in the case of melanoma. As important parts of miRNA processing, several key cellular processes linked to gene silencing are impacted by the amounts of AGO proteins in the cell. Additionally, although there is few research in the case of AGO1, another Argonaute protein, AGO2, was found to be overexpressed in carcinomas and to be interacting with well-studied tumour factors in regulating the metabolism of the cancer cells

References

[1] Gunter Meister, et al. (2005, December). Identification of Novel Argonaute-Associated Proteins. Current Biology, 2149-2155. [1]

[2] Bethany A Jawosky et al. (2006, September). Involvement of AGO1 and AGO2 in mammalian transcriptional silencing. Nature Structural and Molecular biology, 787-792.[2]

[3] Ligang Wu, et al. (2008, September). Importance of translation and Nonnucleolytic Ago Proteins for On- Target RNA Interference. Current Biology, 1327-1332.[3]

[4] Christopher R. Faehnle, et al. (2013, May). The making of a Slicer: Activation of Human Argonaute-1. Cell Reports. [4]

[5] Daniel Völler, et al. (2016, August). Argonaute family protein expression in normal tissue and cancer entities. Plos one.[5]

[6] Schalk C. et al. (2017, February). Small RNA-mediated repair of UV-induced DNA lesions by the DNA damagebinding protein 2 and Argonaute 1. Proc. Natl Acad. Sci. (PNAS) USA 114, E2965–E2974.[6]

[7] Elad Elkayam, et al. (2017, August). Multivalent recruitment of human argonaute by GW182. Molecular Cell, 646-658. [7]

[8] Lidiya Lisitskaya, et al. (2018). DNA Interference and beyond : Structure and Functions of Prokaryotic Argonaute Proteins. Nature Communications.[8]

[9] Ena Secic, et al. (2019, October). Further Elucidation of the argonaute and dicer protein families in the model grass species Brachypodium distachyon. Frontiers in Plant Science.[9]

JSmol in Proteopedia ^[1]

↑ Hanson, R. M., Prilusky, J., Renjian, Z., Nakane, T. and Sussman, J. L. (2013), JSmol and the Next-Generation Web-Based Representation of 3D Molecular Structure as Applied to Proteopedia. Isr. J. Chem., 53:207-216. doi:http://dx.doi.org/10.1002/ijch.201300024

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1106"

@@ Line 9: / Line 9: @@
 <scene name='82/829359/Domains_ago1/1'>domains</scene>
+More details on the 3D structure domains, see the page [[Argonaute 3D structures]] in the rubrik Argonaute 1
 ==== Primary Structure ====
@@ Line 74: / Line 75: @@
-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.
 </StructureSection>
@@ Line 98: / Line 96: @@
 [9] Ena Secic, et al. (2019, October). ''Further Elucidation of the argonaute and dicer protein families in the model grass species Brachypodium distachyon''. Frontiers in Plant Science.[https://www.frontiersin.org/articles/10.3389/fpls.2019.01332/full]
+JSmol in Proteopedia <ref>DOI 10.1002/ijch.201300024</ref>
 <references/>