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Revision as of 12:05, 11 October 2022

STRUCTURE OF Cas9 IN STAPHYLOCOCCUS AUREUS IN COMPLEX WITH sgRNA

1 Cas9 Overview
2 Recognition of the sgRNA-target heteroduplex
3 Recognition of the PAM sequence
4 Recognition of the sgRNA scaffold
5 Endonuclease Activity of Cas9

Cas9 Overview

CRISPR is a bacterial immune response to bacteriophages to prevent subsequent infections and is a form of acquired immunity. Within the CRISPR system, Cas9 is a protein responsible for cutting the viral DNA, rendering it inert. structure in Staphylococcus aureus (SaCas9) utilizes a single-stranded guide RNA (sgRNA) to bind the target DNA that will be cut. Cas9 utilizes the sgRNA as an RNA guide to cut the target DNA sequence and binds complimentary to target DNA so Cas9 create a double-stranded DNA break in the proper location. The target DNA must also have a PAM sequence to bind for Cas9 to cut target DNA. The PAM sequence acts as a two-factor authentication in junction with the sgRNA that tells the Cas9 to cut this portion of DNA. The main domains in the are the REC lobe (residues 41–425) and NUC lobe (residues 1–40 and 435–1053). These lobes are connected by an arginine rich bridge helix (residues 41–73) and a linker loop (residues 426–434). The contains RuvC, HNH, WED, and PI domains in Cas9 ^[1]. The is responsible for recognizing the nucleic acids present causing a conformational change in the HNH locking the HNH into the cleavage site ^[2]. The RuvC nuclease domain (residues 1–40, 435–480 and 650–774) cleaves the strand of target DNA that is not bound complimentary to the sgRNA ^[3]. The HNH domain (residues 520–628) cleaves the target strand of DNA bound to the sgRNA ^[3]. The WED domain (residues 788–909) is responsible for recognizing the sgRNA scaffold and consists of a twisted five-stranded beta sheet flanked by four alpha helices ^[4]. The PI domain (residues 910–1053) recognizes the PAM sequence on the target DNA that is not complimentary to the sgRNA ^[5]. There are also two linker domains, L1 (residues 481–519) and L2 (residues 629–649), that connect the RuvC and HNH ^[1]. Furthermore, there is a phosphate lock loop (scene of loop) (residues 775–787) that connect the WED and RuvC domains. Cas9 has four main mechanisms that are important for successful cleavage, including recognition of the sgRNA-target heteroduplex, recognition of the PAM sequence, recognition of the sgRNA scaffold, and endonuclease activity by HNH and RuvC.

Recognition of the sgRNA-target heteroduplex

The recognition of the sgRNA-target heteroduplex in Cas9 begins by inserting itself into the central channel between the REC and NUC lobes. A heteroduplex is the binding of the complimentary strands of the sgRNA and target DNA. The REC lobe and bridge helix interacts with the seed region of the (C13-C20). The seed region is in the , so it can bind the target DNA. Only the REC lobe interacts with the PAM distal region pf the sgRNA (A3-U6) through the . The target DNA binds to the for the proper conformation for base paring between the target DNA and sgRNA^[1].

Recognition of the PAM sequence

For the recognition of the , the target DNA with the PAM sequence (5’-NNGRRN-3’) is bound to SaCas9 through hydrogen bonds as well as direct and water mediated hydrogen bonds through the major groove in the PI domain. This PAM sequence is differnt that other PAM sequences like the one found in SpCas9 (5'-NGG-3'). The WED domain recognizes the minor groove phosphate backbone of the duplex ^[1].

Recognition of the sgRNA scaffold

The SaCas9 recognizes the sgRNA scaffold within the . The WED contains five stranded beta sheets flanked with four alpha helices to allow binding of the repeat: anti-repeat duplex. REC lob binds the scaffold and secures it into the SaCas9 ^[1].

Endonuclease Activity of Cas9

Finally, are in endonuclease activity. RuvC uses a two-metal ion mechanism of manganese to cleave the non-target DNA and causes a conformational change in L1. This is modeled as manganese however, it is often magnesium in cell. The magnesium allows a histidine to become a general base and cleave the target DNA. This conformational change leads to the phosphate group of the target strand to be cleaved by HNH. HNH includes a beta beta alpha metal fold and uses a one metal ion mechanism to cleave the target DNA ^[1].

References

↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 Nishimasu H, Cong L, Yan WX, Ran FA, Zetsche B, Li Y, Kurabayashi A, Ishitani R, Zhang F, Nureki O. Crystal Structure of Staphylococcus aureus Cas9. Cell. 2015 Aug 27;162(5):1113-26. doi: 10.1016/j.cell.2015.08.007. PMID:26317473 doi:http://dx.doi.org/10.1016/j.cell.2015.08.007
↑ Palermo G, Chen JS, Ricci CG, Rivalta I, Jinek M, Batista VS, Doudna JA, McCammon JA. Key role of the REC lobe during CRISPR-Cas9 activation by 'sensing', 'regulating', and 'locking' the catalytic HNH domain. Q Rev Biophys. 2018;51. doi: 10.1017/S0033583518000070. Epub 2018 Aug 3. PMID:30555184 doi:http://dx.doi.org/10.1017/S0033583518000070
↑ ^3.0 ^3.1 Nishimasu H, Ran FA, Hsu PD, Konermann S, Shehata SI, Dohmae N, Ishitani R, Zhang F, Nureki O. Crystal structure of Cas9 in complex with guide RNA and target DNA. Cell. 2014 Feb 27;156(5):935-49. doi: 10.1016/j.cell.2014.02.001. Epub 2014 Feb, 13. PMID:24529477 doi:http://dx.doi.org/10.1016/j.cell.2014.02.001
↑ Morlot C, Pernot L, Le Gouellec A, Di Guilmi AM, Vernet T, Dideberg O, Dessen A. Crystal structure of a peptidoglycan synthesis regulatory factor (PBP3) from Streptococcus pneumoniae. J Biol Chem. 2005 Apr 22;280(16):15984-91. Epub 2004 Dec 13. PMID:15596446 doi:10.1074/jbc.M408446200
↑ Chen H, Choi J, Bailey S. Cut site selection by the two nuclease domains of the Cas9 RNA-guided endonuclease. J Biol Chem. 2014 May 9;289(19):13284-94. doi: 10.1074/jbc.M113.539726. Epub 2014, Mar 14. PMID:24634220 doi:http://dx.doi.org/10.1074/jbc.M113.539726

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 The recognition of the sgRNA-target heteroduplex in Cas9 begins by inserting itself into the central channel between the REC and NUC lobes. A heteroduplex is the binding of the complimentary strands of the sgRNA and target DNA. The REC lobe and bridge helix interacts with the seed region of the <scene name='92/925538/Lobes_and_linkers/17'>sgRNA</scene> (C13-C20). The seed region is in the <scene name='92/925538/Lobes_and_linkers/8'>A-form conformation</scene>, so it can bind the target DNA. Only the REC lobe interacts with the PAM distal region pf the sgRNA (A3-U6) through the <scene name='92/925538/Lobes_and_linkers/18'>phosphate backbone</scene>. The target DNA binds to the <scene name='92/925538/Lobes_and_linkers/9'>REC lobe and RuvC domain</scene> for the proper conformation for base paring between the target DNA and sgRNA<ref name="Cas9" />.
 == Recognition of the PAM sequence ==
-For the recognition of the <scene name='92/925538/Lobes_and_linkers/19'>PAM sequence</scene>, the target DNA with the PAM sequence (5’-NNGRRN-3’) is bound to SaCas9 through bidentate hydrogen bonds (scene of bonds) as well as direct and water mediated hydrogen bonds through the major groove in the PI domain. The WED domain recognizes the minor groove phosphate backbone of the duplex <ref name="Cas9" />.
+For the recognition of the <scene name='92/925538/Lobes_and_linkers/19'>PAM sequence</scene>, the target DNA with the PAM sequence (5’-NNGRRN-3’) is bound to SaCas9 through hydrogen bonds as well as direct and water mediated hydrogen bonds through the major groove in the PI domain. This PAM sequence is differnt that other PAM sequences like the one found in SpCas9 (5'-NGG-3'). The WED domain recognizes the minor groove phosphate backbone of the duplex <ref name="Cas9" />.
 == Recognition of the sgRNA scaffold ==
 The SaCas9 recognizes the sgRNA scaffold within the <scene name='92/925538/Lobes_and_linkers/20'>REC lobe and WED domain</scene>. The WED contains five stranded beta sheets flanked with four alpha helices to allow binding of the repeat: anti-repeat duplex. REC lob binds the scaffold and secures it into the SaCas9 <ref name="Cas9" />.
 == Endonuclease Activity of Cas9 ==
-Finally, <scene name='92/925538/Lobes_and_linkers/12'>RuvC and HNH</scene> are in endonuclease activity (Scene). RuvC uses a two-metal ion mechanism of manganese to cleave the non-target DNA and causes a conformational change in L1. This is modeled as manganese however, it is often magnesium in cell. The magnesium allows a histidine to become a general base and cleave the target DNA. This conformational change leads to the phosphate group of the target strand to be cleaved by HNH. HNH includes a beta beta alpha metal fold and uses a one metal ion mechanism to cleave the target DNA <ref name="Cas9" />.
+Finally, <scene name='92/925538/Lobes_and_linkers/12'>RuvC and HNH</scene> are in endonuclease activity. RuvC uses a two-metal ion mechanism of manganese to cleave the non-target DNA and causes a conformational change in L1. This is modeled as manganese however, it is often magnesium in cell. The magnesium allows a histidine to become a general base and cleave the target DNA. This conformational change leads to the phosphate group of the target strand to be cleaved by HNH. HNH includes a beta beta alpha metal fold and uses a one metal ion mechanism to cleave the target DNA <ref name="Cas9" />.
 </structuresection>
 ==References==
 <references />

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From Proteopedia

Revision as of 12:05, 11 October 2022

STRUCTURE OF Cas9 IN STAPHYLOCOCCUS AUREUS IN COMPLEX WITH sgRNA

Contents

Cas9 Overview

Recognition of the sgRNA-target heteroduplex

Recognition of the PAM sequence

Recognition of the sgRNA scaffold

Endonuclease Activity of Cas9

References

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