4kpy

Structural highlights

Function

AGO_THET2 A DNA-guided ssDNA endonuclease. Uses short ssDNA sequences as guides (gDNA, also called small interfering DNA, siDNA) to bind complementary DNA target strands, resulting in cleavage of the target DNA (tDNA). The cleavage site is 10 nucleotides (nt) downstream of the target residue base-paired with the 5'-end of the gDNA (PubMed:24531762, PubMed:28911094). Plays a role in completion of DNA replication, participates in decatenating replicated DNA and plasmid. In situ purifies with 5'-phosphorylated long DNA (about 1160 nt, maps to the whole chromosome and plasmid), 25-35 nt RNAs that map to the whole chromosome and 15-18 nt DNA that maps to the replication terminus region (ter) on the chromosome and plasmid. Most short DNA starts with dC (PubMed:32846159). Has been shown to have guide sequence-independent dsDNase activity called 'chopping', which requires unstable DNA (high AT-content, multiple mismatches or low salt conditions), and could be used to generate gDNA. Preferentially binds tDNA with dC at its 3'-terminus (PubMed:28262506). Has also been shown to have no detectable guide sequence-independent dsDNase activity (PubMed:32846159). The latter study proposes TtAgo may acquire gDNA from nicked dsDNA, by binding to 5'-phosphorylated-dC nicks, then cleaving 10 nt away on the opposite strand; subsequently an exonuclease (maybe AddA-AddB helicase/nuclease) trims the ends to generate the gDNA (Probable) (PubMed:32846159).^{[1] [2] [3] [4] [5]} Involved in defense against invading mobile genetic elements (PubMed:24531762, PubMed:25331432, PubMed:25902012). TtAgo interferes with plasmid DNA, stimulates expression of specific endogenous genes, including various CRISPR loci and at least part of the CRISPR adaptation machinery, but only when exogenous plasmid DNA is present (PubMed:25902012). Upon purification from E.coli associates with gDNA 13-25 nt long with 5'-phosphorylated ends and with 10-150 nt RNA with 5'-OH. DNA corresponds to the expression plasmid rather than chromosomal DNA; 89% of gDNA starts with dC and 72% has dA in the second position. Endonucleolytically cleaves tDNA with 5'-phosphorylated gDNA but not 5'-phosphorylated gRNA; the active site is involved in processing or binding of ssDNA. Nicks or linearizes supercoiled plasmid target when it has the appropriate gDNA sequences, does not cleave linear tDNA (PubMed:24531762). Positions 4 to 16 of the tDNA need to be base paired to the gDNA for efficient tDNA cleavage (PubMed:19812667). Although the system can support single nucleotide insertions in either the gDNA or tDNA, in all cases cleavage activity is reduced, with a wide range of sequence- and position-specific effects (PubMed:28911094).^{[6] [7] [8] [9] [10]} First characterized as a DNA-guided RNA endonuclease. Uses gDNA to bind complementary RNA target strands, resulting in cleavage of the target RNA. The cleavage site is 10 nucleotides (nt) downstream of the target residue base-paired with the 5'-end of the guide DNA.^{[11] [12] [13] [14]}

References

1. ↑ Swarts DC, Jore MM, Westra ER, Zhu Y, Janssen JH, Snijders AP, Wang Y, Patel DJ, Berenguer J, Brouns SJJ, van der Oost J. DNA-guided DNA interference by a prokaryotic Argonaute. Nature. 2014 Mar 13;507(7491):258-261. PMID:24531762 doi:10.1038/nature12971
2. ↑ Swarts DC, Szczepaniak M, Sheng G, Chandradoss SD, Zhu Y, Timmers EM, Zhang Y, Zhao H, Lou J, Wang Y, Joo C, van der Oost J. Autonomous Generation and Loading of DNA Guides by Bacterial Argonaute. Mol Cell. 2017 Mar 16;65(6):985-998.e6. PMID:28262506 doi:10.1016/j.molcel.2017.01.033
3. ↑ Sheng G, Gogakos T, Wang J, Zhao H, Serganov A, Juranek S, Tuschl T, Patel DJ, Wang Y. Structure/cleavage-based insights into helical perturbations at bulge sites within T. thermophilus Argonaute silencing complexes. Nucleic Acids Res. 2017 Sep 6;45(15):9149-9163. doi: 10.1093/nar/gkx547. PMID:28911094 doi:http://dx.doi.org/10.1093/nar/gkx547
4. ↑ Jolly SM, Gainetdinov I, Jouravleva K, Zhang H, Strittmatter L, Bailey SM, Hendricks GM, Dhabaria A, Ueberheide B, Zamore PD. Thermus thermophilus Argonaute Functions in the Completion of DNA Replication. Cell. 2020 Sep 17;182(6):1545-1559.e18. PMID:32846159 doi:10.1016/j.cell.2020.07.036
5. ↑ Jolly SM, Gainetdinov I, Jouravleva K, Zhang H, Strittmatter L, Bailey SM, Hendricks GM, Dhabaria A, Ueberheide B, Zamore PD. Thermus thermophilus Argonaute Functions in the Completion of DNA Replication. Cell. 2020 Sep 17;182(6):1545-1559.e18. PMID:32846159 doi:10.1016/j.cell.2020.07.036
6. ↑ Wang Y, Juranek S, Li H, Sheng G, Wardle GS, Tuschl T, Patel DJ. Nucleation, propagation and cleavage of target RNAs in Ago silencing complexes. Nature. 2009 Oct 8;461(7265):754-61. PMID:19812667 doi:10.1038/nature08434
7. ↑ Swarts DC, Jore MM, Westra ER, Zhu Y, Janssen JH, Snijders AP, Wang Y, Patel DJ, Berenguer J, Brouns SJJ, van der Oost J. DNA-guided DNA interference by a prokaryotic Argonaute. Nature. 2014 Mar 13;507(7491):258-261. PMID:24531762 doi:10.1038/nature12971
8. ↑ Blesa A, César CE, Averhoff B, Berenguer J. Noncanonical cell-to-cell DNA transfer in Thermus spp. is insensitive to argonaute-mediated interference. J Bacteriol. 2015 Jan 1;197(1):138-46. PMID:25331432 doi:10.1128/JB.02113-14
9. ↑ Swarts DC, Koehorst JJ, Westra ER, Schaap PJ, van der Oost J. Effects of Argonaute on Gene Expression in Thermus thermophilus. PLoS One. 2015 Apr 22;10(4):e0124880. PMID:25902012 doi:10.1371/journal.pone.0124880
10. ↑ Sheng G, Gogakos T, Wang J, Zhao H, Serganov A, Juranek S, Tuschl T, Patel DJ, Wang Y. Structure/cleavage-based insights into helical perturbations at bulge sites within T. thermophilus Argonaute silencing complexes. Nucleic Acids Res. 2017 Sep 6;45(15):9149-9163. doi: 10.1093/nar/gkx547. PMID:28911094 doi:http://dx.doi.org/10.1093/nar/gkx547
11. ↑ Wang Y, Sheng G, Juranek S, Tuschl T, Patel DJ. Structure of the guide-strand-containing argonaute silencing complex. Nature. 2008 Nov 13;456(7219):209-13. Epub 2008 Aug 27. PMID:18754009 doi:10.1038/nature07315
12. ↑ Wang Y, Juranek S, Li H, Sheng G, Tuschl T, Patel DJ. Structure of an argonaute silencing complex with a seed-containing guide DNA and target RNA duplex. Nature. 2008 Dec 18;456(7224):921-6. PMID:19092929 doi:nature07666
13. ↑ Wang Y, Juranek S, Li H, Sheng G, Wardle GS, Tuschl T, Patel DJ. Nucleation, propagation and cleavage of target RNAs in Ago silencing complexes. Nature. 2009 Oct 8;461(7265):754-61. PMID:19812667 doi:10.1038/nature08434
14. ↑ Sheng G, Zhao H, Wang J, Rao Y, Tian W, Swarts DC, van der Oost J, Patel DJ, Wang Y. Structure-based cleavage mechanism of Thermus thermophilus Argonaute DNA guide strand-mediated DNA target cleavage. Proc Natl Acad Sci U S A. 2013 Dec 27. PMID:24374628 doi:http://dx.doi.org/10.1073/pnas.1321032111
15. ↑ Sheng G, Zhao H, Wang J, Rao Y, Tian W, Swarts DC, van der Oost J, Patel DJ, Wang Y. Structure-based cleavage mechanism of Thermus thermophilus Argonaute DNA guide strand-mediated DNA target cleavage. Proc Natl Acad Sci U S A. 2013 Dec 27. PMID:24374628 doi:http://dx.doi.org/10.1073/pnas.1321032111