Team:Arizona State/Project/CRISPR
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<p>'''C'''lustered '''R'''egularly '''I'''nterspaced '''S'''hort '''P'''alindromic '''R'''epeats (CRISPR) are a genomic feature of many prokaryotic and archaeal species. 40% of sequenced bacterial genomes and 90% of archaeal genomes contain at least one CRISPR array{{:Team:Arizona State/Templates/ref|20}}. It is possible that many laboratory strains of bacteria, which are the sources of many available genome sequences, have lost CRISPR due to a lack of exposure to phages{{:Team:Arizona State/Templates/ref|42}}.</p> | <p>'''C'''lustered '''R'''egularly '''I'''nterspaced '''S'''hort '''P'''alindromic '''R'''epeats (CRISPR) are a genomic feature of many prokaryotic and archaeal species. 40% of sequenced bacterial genomes and 90% of archaeal genomes contain at least one CRISPR array{{:Team:Arizona State/Templates/ref|20}}. It is possible that many laboratory strains of bacteria, which are the sources of many available genome sequences, have lost CRISPR due to a lack of exposure to phages{{:Team:Arizona State/Templates/ref|42}}.</p> | ||
<p>CRISPR functions as an adaptive and inheritable immune system{{:Team:Arizona State/Templates/ref|40}}{{:Team:Arizona State/Templates/ref|53}}{{:Team:Arizona State/Templates/ref|34}}{{:Team:Arizona State/Templates/ref|38}}{{:Team:Arizona State/Templates/ref|42}}. A CRISPR locus consists of a set of Cas (CRISPR associated) genes, a leader, or promoter, sequence, and an array. This array consists of repeating elements along with "spacers". These spacer regions direct the CRISPR machinery to degrade or otherwise inactivate a complementary sequence in the cell.</p> | <p>CRISPR functions as an adaptive and inheritable immune system{{:Team:Arizona State/Templates/ref|40}}{{:Team:Arizona State/Templates/ref|53}}{{:Team:Arizona State/Templates/ref|34}}{{:Team:Arizona State/Templates/ref|38}}{{:Team:Arizona State/Templates/ref|42}}. A CRISPR locus consists of a set of Cas (CRISPR associated) genes, a leader, or promoter, sequence, and an array. This array consists of repeating elements along with "spacers". These spacer regions direct the CRISPR machinery to degrade or otherwise inactivate a complementary sequence in the cell.</p> | ||
+ | |||
+ | == The CRISPR array == | ||
+ | <p>Genetic information from previous encounters is stored in the array as spacers. These spacers are consistent in length (30-40 bp), and are flanked by repeating elements (also 30-40 bp). The repeating elements are usually partially palindromic, and form secondary structures when transcribed into pre-crRNA. These structures may be necessary for recognition and cleavage.</p> | ||
== Engineered arrays == | == Engineered arrays == | ||
<p>By engineering a spacer complementary to T3 phage, increased survival was demonstrated{{:Team:Arizona State/Templates/ref|17}}{{:Team:Arizona State/Templates/ref|25}}{{:Team:Arizona State/Templates/ref|28}}{{:Team:Arizona State/Templates/ref|51}}{{:Team:Arizona State/Templates/ref|59}}. A customized spacer can prevent transformation of PC194 plasmids with a matching sequence{{:Team:Arizona State/Templates/ref|28}}.</p> | <p>By engineering a spacer complementary to T3 phage, increased survival was demonstrated{{:Team:Arizona State/Templates/ref|17}}{{:Team:Arizona State/Templates/ref|25}}{{:Team:Arizona State/Templates/ref|28}}{{:Team:Arizona State/Templates/ref|51}}{{:Team:Arizona State/Templates/ref|59}}. A customized spacer can prevent transformation of PC194 plasmids with a matching sequence{{:Team:Arizona State/Templates/ref|28}}.</p> | ||
- | == CRISPR in '' | + | == CRISPR in ''Escherichia coli K-12 substr. MG1655'' == |
- | <p>''E. coli'' contains a type I CRISPR system. There are four CRISPR loci in | + | '''[[Team:Arizona State/Project/E coli|Project page]]''' |
- | <p> | + | <p>''E. coli'' contains a type I CRISPR system. There are four CRISPR loci in this organism. CRISPR1, the largest, is associated with eight Cas genes{{:Team:Arizona State/Templates/ref|73}}. In the classification scheme presented by Haft et al{{:Team:Arizona State/Templates/ref|15}}, these genes form the Cse family: casA, casB, casC, casD, casE, aka cse1, cse2, cse3, cse4, cas5e{{:Team:Arizona State/Templates/ref|15}}. These 5 proteins combine to form the Cascade complex{{:Team:Arizona State/Templates/ref|63}}. This is a protein complex of all 5 Cse genes, resembling a seahorse in shape{{:Team:Arizona State/Templates/ref|63}}. Its full composition is 1x casA, 2x casB, 6x casC, 1x casD, 1x casE{{:Team:Arizona State/Templates/ref|63}}. Specifically, casE cleaves pre-crRNA{{:Team:Arizona State/Templates/ref|25}}, and casA and casB can be omitted without affecting crRNA generation, but are necessary for phage resistance{{:Team:Arizona State/Templates/ref|63}}. This complex binds double stranded target DNA without need or enhancement by cofactors such as metal ions or ATP{{:Team:Arizona State/Templates/ref|63}}. It also undergoes conformational changes when binding DNA{{:Team:Arizona State/Templates/ref|63}}{{:Team:Arizona State/Templates/ref|76}}.</p> |
+ | <p>Cas gene transcription is repressed by H-NS{{:Team:Arizona State/Templates/ref|70}}, and de-repressed by leuO{{:Team:Arizona State/Templates/ref|48}} or baeR{{:Team:Arizona State/Templates/ref|57}}</p>. | ||
[[Image:E coli crispr full.png|600px]]<small> | [[Image:E coli crispr full.png|600px]]<small> | ||
:Coordinates: | :Coordinates: | ||
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<p>Structure of the CRISPR I locus in ''E. coli''. 3 promoters have been characterized{{:Team:Arizona State/Templates/ref|43}}: Pcrispr1, Pcas, and anti-Pcas.</p> | <p>Structure of the CRISPR I locus in ''E. coli''. 3 promoters have been characterized{{:Team:Arizona State/Templates/ref|43}}: Pcrispr1, Pcas, and anti-Pcas.</p> | ||
- | == CRISPR in ''Pyrococcus | + | == CRISPR in ''Pyrococcus furiosus DSM 3638''== |
- | <p>''P. furiosus'' contains 7 CRISPR loci, along with 29 Cas genes in 2 gene clusters{{:Team:Arizona State/Templates/ref|35}}. All 6 core Cas genes (cas1-cas6), as well as genes from the Cmr (type III), Cst (type I), and Csa (type I) families are present. Cmr1-6 have been found to form a Cascade-like complex that targets RNA in in-vitro experiments{{:Team:Arizona State/Templates/ref|35}}.</p> | + | <p>This organism is notable due to the diversity of its Cas genes, as well as its possible RNA targeting. ''P. furiosus'' contains 7 CRISPR loci, along with 29 Cas genes in 2 gene clusters{{:Team:Arizona State/Templates/ref|35}}. All 6 core Cas genes (cas1-cas6), as well as genes from the Cmr (type III), Cst (type I), and Csa (type I) families are present. Cmr1-6 have been found to form a Cascade-like complex that targets RNA in in-vitro experiments{{:Team:Arizona State/Templates/ref|35}}.</p> |
- | + | ||
== CRISPR in ''Bacillus halodurans C-125''== | == CRISPR in ''Bacillus halodurans C-125''== | ||
- | <p>''B. halodurans'' contains 6 Cmr genes (Cmr1-6) in a single locus. This is a type III CRISPR system. The organism also contains Csd1 and Csd2 ( | + | '''[[Team:Arizona State/Project/B halodurans|Project page]]''' |
+ | <p>''B. halodurans'' contains 6 Cmr genes (Cmr1-6) in a single locus. This is a type III CRISPR system. The organism also contains Csd1 and Csd2 (Dvulg subtype I-C) along with Cas1, Cas2, Cas3, Cas4, and Cas5 in another locus.</p> | ||
[[Image:ASU B halodurans crispr.png|400px]]<br> | [[Image:ASU B halodurans crispr.png|400px]]<br> | ||
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</small> | </small> | ||
- | == CRISPR in ''Listeria innocua''== | + | == CRISPR in ''Listeria innocua Clip11262''== |
- | <p>''L. innocua'' contains a type II CRISPR system. A single gene (Cas9) has been shown to be necessary for the expression and inactivation stages of the pathway{{:Team:Arizona State/Templates/ref|65}}. A separate trans-encoded small RNA (tracrRNA) binds with the repeat segment of the pre-crRNA{{:Team:Arizona State/Templates/ref|62}}, followed by cleavage by RNase III and binding with Cas9.</p> | + | '''[[Team:Arizona State/Project/L innocua|Project page]]''' |
+ | <p>''L. innocua'' contains a type II CRISPR system. A single gene (Cas9 / Csn1) has been shown to be necessary for the expression and inactivation stages of the pathway{{:Team:Arizona State/Templates/ref|65}}. A separate trans-encoded small RNA (tracrRNA) binds with the repeat segment of the pre-crRNA{{:Team:Arizona State/Templates/ref|62}}, followed by cleavage by RNase III and binding with Cas9.</p> | ||
- | [[Image: | + | [[Image:ASU L innocua crispr.png|400px]]<br> |
+ | <small> | ||
+ | :Coordinates: | ||
+ | :: CrisprI: 2768992-2769687 | ||
+ | :: Leader: 2769687-2769814 | ||
+ | :: Cas2 (lin2742): 2769814-2770404 | ||
+ | :: Cas1 (lin2743): 2770410-2770706 | ||
+ | :: Csn1 (lin2744): 2770707-2774711 | ||
+ | :: TracrRNA: 2774711-2774865 | ||
+ | </small> | ||
== Stages of the CRISPR pathway == | == Stages of the CRISPR pathway == | ||
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=== Interference === | === Interference === | ||
- | <p>This stage requires bound crRNA, as well as | + | <p>This stage requires bound crRNA, as well as Cas3 in ''E. coli''{{:Team:Arizona State/Templates/ref|63}}. The interference stage targets DNA in most organisms{{:Team:Arizona State/Templates/ref|25}}{{:Team:Arizona State/Templates/ref|28}}{{:Team:Arizona State/Templates/ref|54}}, but RNA targeting has been demonstrated in the case of ''P. furiosus''{{:Team:Arizona State/Templates/ref|35}}. Recognition of target DNA is thought to take place by means of R-loops{{:Team:Arizona State/Templates/ref|63}}{{:Team:Arizona State/Templates/ref|73}}{{:Team:Arizona State/Templates/ref|1}}. An R-loop is an RNA strand that has base paired with a complementary DNA strand, displacing the other identical DNA strand{{:Team:Arizona State/Templates/ref|1}}. This base pairing between the crRNA spacer sequence and target strand may mark the region for interference by other proteins such as cas3{{:Team:Arizona State/Templates/ref|63}}.</p> |
<p>In ''Streptococcus thermophilus'', only Cas9 is necessary for CRISPR functionality{{:Team:Arizona State/Templates/ref|74}}. However, a specific sequence, known as a proto-adjacent-motif (PAM) was found to be required for interference. The predicted sequence is 5'-NGGNG-3'. This sequence is found several base pairs upstream of the proto-spacer (target DNA). Single base pair mutations in the PAM completely abolish CRISPR interference{{:Team:Arizona State/Templates/ref|74}}.</p> | <p>In ''Streptococcus thermophilus'', only Cas9 is necessary for CRISPR functionality{{:Team:Arizona State/Templates/ref|74}}. However, a specific sequence, known as a proto-adjacent-motif (PAM) was found to be required for interference. The predicted sequence is 5'-NGGNG-3'. This sequence is found several base pairs upstream of the proto-spacer (target DNA). Single base pair mutations in the PAM completely abolish CRISPR interference{{:Team:Arizona State/Templates/ref|74}}.</p> | ||
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=== Cas3 === | === Cas3 === | ||
<p>Cas3 is not regulated by H-NS{{:Team:Arizona State/Templates/ref|41}}. It cooperates with the Cascade complex{{:Team:Arizona State/Templates/ref|25}} in the interference stage. Cas3 has predicted ATP-dependent helicase activity{{:Team:Arizona State/Templates/ref|4}}, as well as demonstrated ATP independent annealing of RNA to DNA{{:Team:Arizona State/Templates/ref|73}}. It forms an R-loop with DNA, requiring magnesium or manganese as a co-factor{{:Team:Arizona State/Templates/ref|73}}, but has an antagonistic function in the presence of ATP, dissociating the R-loop.</p> | <p>Cas3 is not regulated by H-NS{{:Team:Arizona State/Templates/ref|41}}. It cooperates with the Cascade complex{{:Team:Arizona State/Templates/ref|25}} in the interference stage. Cas3 has predicted ATP-dependent helicase activity{{:Team:Arizona State/Templates/ref|4}}, as well as demonstrated ATP independent annealing of RNA to DNA{{:Team:Arizona State/Templates/ref|73}}. It forms an R-loop with DNA, requiring magnesium or manganese as a co-factor{{:Team:Arizona State/Templates/ref|73}}, but has an antagonistic function in the presence of ATP, dissociating the R-loop.</p> | ||
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== Prevention of self targeting (autoimmunity) == | == Prevention of self targeting (autoimmunity) == | ||
<p>The 5' handle of crRNA allows self / nonself discrimination in the csm subtype{{:Team:Arizona State/Templates/ref|39}}. In the Cse subtype, regions flanking the proto spacer contain PAMs{{:Team:Arizona State/Templates/ref|39}}{{:Team:Arizona State/Templates/ref|14}}{{:Team:Arizona State/Templates/ref|22}}{{:Team:Arizona State/Templates/ref|30}}{{:Team:Arizona State/Templates/ref|21}}, which may be necessary for interference. In general, it is thought that mismatches at positions outside of the spacer sequence allow for targeting, while extended base pairing with the surrounding repeats prevents targeting{{:Team:Arizona State/Templates/ref|39}}.</p> | <p>The 5' handle of crRNA allows self / nonself discrimination in the csm subtype{{:Team:Arizona State/Templates/ref|39}}. In the Cse subtype, regions flanking the proto spacer contain PAMs{{:Team:Arizona State/Templates/ref|39}}{{:Team:Arizona State/Templates/ref|14}}{{:Team:Arizona State/Templates/ref|22}}{{:Team:Arizona State/Templates/ref|30}}{{:Team:Arizona State/Templates/ref|21}}, which may be necessary for interference. In general, it is thought that mismatches at positions outside of the spacer sequence allow for targeting, while extended base pairing with the surrounding repeats prevents targeting{{:Team:Arizona State/Templates/ref|39}}.</p> | ||
- | == | + | == CRISPR regulation == |
<p>In E. coli (Cse subtype), transcription of the Cascade genes and CRISPR array is repressed by H-NS{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|44}}. H-NS is a global repressor of transcription in many gram negative bacteria that binds AT rich sequences{{:Team:Arizona State/Templates/ref|16}}. This repression is mediated by "DNA stiffening"{{:Team:Arizona State/Templates/ref|37}}, as well as formation of "DNA-protein-DNA" bridges{{:Team:Arizona State/Templates/ref|11}}. The creation of an H-NS knockout can be shown to increase expression of cas genes{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|5}}. This correlates with phage sensitivity{{:Team:Arizona State/Templates/ref|48}}.</p> | <p>In E. coli (Cse subtype), transcription of the Cascade genes and CRISPR array is repressed by H-NS{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|44}}. H-NS is a global repressor of transcription in many gram negative bacteria that binds AT rich sequences{{:Team:Arizona State/Templates/ref|16}}. This repression is mediated by "DNA stiffening"{{:Team:Arizona State/Templates/ref|37}}, as well as formation of "DNA-protein-DNA" bridges{{:Team:Arizona State/Templates/ref|11}}. The creation of an H-NS knockout can be shown to increase expression of cas genes{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|5}}. This correlates with phage sensitivity{{:Team:Arizona State/Templates/ref|48}}.</p> | ||
<p>Transcription is antagonistically{{:Team:Arizona State/Templates/ref|26}} de-repressed by LeuO{{:Team:Arizona State/Templates/ref|48}}, a protein of the lysR transcription factor family{{:Team:Arizona State/Templates/ref|26}} near the leuABCD (leucine synthesis{{:Team:Arizona State/Templates/ref|2}}) operon{{:Team:Arizona State/Templates/ref|13}}. LeuO expression is also repressed by H-NS{{:Team:Arizona State/Templates/ref|3}}{{:Team:Arizona State/Templates/ref|6}}. Expression of H-NS repressed proteins can be manipulated by plasmid-encoded leuO in a constitutive promoter{{:Team:Arizona State/Templates/ref|33}}. Plasmids: pCA24N (lac1 promoter), pKEDR13 (pTac promoter), pNH41 (IPTG). Increased LeuO expression leads to increased expression of casABCDE, cas1, and cas2{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|33}}, but does not affect cas3 expression{{:Team:Arizona State/Templates/ref|48}}. Constitutively expressing leuO had a stronger affect than knocking out H-NS{{:Team:Arizona State/Templates/ref|48}}.</p> | <p>Transcription is antagonistically{{:Team:Arizona State/Templates/ref|26}} de-repressed by LeuO{{:Team:Arizona State/Templates/ref|48}}, a protein of the lysR transcription factor family{{:Team:Arizona State/Templates/ref|26}} near the leuABCD (leucine synthesis{{:Team:Arizona State/Templates/ref|2}}) operon{{:Team:Arizona State/Templates/ref|13}}. LeuO expression is also repressed by H-NS{{:Team:Arizona State/Templates/ref|3}}{{:Team:Arizona State/Templates/ref|6}}. Expression of H-NS repressed proteins can be manipulated by plasmid-encoded leuO in a constitutive promoter{{:Team:Arizona State/Templates/ref|33}}. Plasmids: pCA24N (lac1 promoter), pKEDR13 (pTac promoter), pNH41 (IPTG). Increased LeuO expression leads to increased expression of casABCDE, cas1, and cas2{{:Team:Arizona State/Templates/ref|48}}{{:Team:Arizona State/Templates/ref|33}}, but does not affect cas3 expression{{:Team:Arizona State/Templates/ref|48}}. Constitutively expressing leuO had a stronger affect than knocking out H-NS{{:Team:Arizona State/Templates/ref|48}}.</p> | ||
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<p>For a comprehensive listing of Cas genes, see [ftp://ftp.ncbi.nih.gov/pub/wolf/_suppl/CRISPRclass/crisprPro.html].</p> | <p>For a comprehensive listing of Cas genes, see [ftp://ftp.ncbi.nih.gov/pub/wolf/_suppl/CRISPRclass/crisprPro.html].</p> | ||
<p>Haft (2005) {{:Team:Arizona State/Templates/ref|15}}: Recognition of core Cas genes (1-6). Organized remaining genes into 9 subtypes: Ecoli, Ypest, Nmeni, Dvulg, Tneap, Hmari, Apern, Mtube, RAMP.</p> | <p>Haft (2005) {{:Team:Arizona State/Templates/ref|15}}: Recognition of core Cas genes (1-6). Organized remaining genes into 9 subtypes: Ecoli, Ypest, Nmeni, Dvulg, Tneap, Hmari, Apern, Mtube, RAMP.</p> | ||
- | <p>Makarova (2011) {{:Team:Arizona State/Templates/ref| | + | <p>Makarova (2011) {{:Team:Arizona State/Templates/ref|65}}: Classification into I, II, and III subtypes, based on mechanism of action as well as homology. These subtypes correspond with the 9 given by Haft to a large extent: |
- | :* I-A: Apern | + | :* I-A: Apern (Csa) |
- | :* I-B: Tneap / Hmari | + | :* I-B: Tneap (Cst) / Hmari (Csh) |
- | :* I-C: Dvulg | + | :* I-C: Dvulg (Csd) |
:* I-D | :* I-D | ||
- | :* I-E: Ecoli | + | :* I-E: Ecoli (Cse) |
- | :* I-F: Ypest | + | :* I-F: Ypest (Csy) |
- | :* II-A: Nmeni | + | :* II-A: Nmeni (Csn) |
- | :* II-B: Nmeni | + | :* II-B: Nmeni (Csn) |
- | :* III-A: Mtube | + | :* III-A: Mtube (Csm) |
- | :* III-B: Polymerase-RAMP</p> | + | :* III-B: Polymerase-RAMP (Cmr)</p> |
=== Type I, II and III systems === | === Type I, II and III systems === | ||
- | <p>This classification takes into account differing mechanisms at all three stages of the pathway{{:Team:Arizona State/Templates/ref| | + | <p>This classification takes into account differing mechanisms at all three stages of the pathway{{:Team:Arizona State/Templates/ref|65}}.</p> |
:<p> Integration: In type I and II systems, the integration of proto-spacers depends on a proto-adjacent-motif. Cas1 and Cas2 are involved in this stage in all three subtypes.</p> | :<p> Integration: In type I and II systems, the integration of proto-spacers depends on a proto-adjacent-motif. Cas1 and Cas2 are involved in this stage in all three subtypes.</p> | ||
:<p> Expression: The CRISPR locus is transcribed into pre-crRNA. In type I systems, the Cascade complex binds to pre-crRNA, which is then cleaved by the Cas6e or Cas6f. Type II systems use a trans-encoded small RNA (tracrRNA) that binds with the repeat segment of pre-crRNA{{:Team:Arizona State/Templates/ref|62}}, followed by cleavage by RNase III with Cas9. Cas6 cleaves pre-crRNA in Type III systems. The crRNAs are then transferred to a distinct Cas complex (Csm in subtype III-A and Cmr in subtype III-B).</p> | :<p> Expression: The CRISPR locus is transcribed into pre-crRNA. In type I systems, the Cascade complex binds to pre-crRNA, which is then cleaved by the Cas6e or Cas6f. Type II systems use a trans-encoded small RNA (tracrRNA) that binds with the repeat segment of pre-crRNA{{:Team:Arizona State/Templates/ref|62}}, followed by cleavage by RNase III with Cas9. Cas6 cleaves pre-crRNA in Type III systems. The crRNAs are then transferred to a distinct Cas complex (Csm in subtype III-A and Cmr in subtype III-B).</p> |
Latest revision as of 02:53, 29 September 2011
|
See glossary for explanation of various abbreviations used on this page. Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) are a genomic feature of many prokaryotic and archaeal species. 40% of sequenced bacterial genomes and 90% of archaeal genomes contain at least one CRISPR array[20]. It is possible that many laboratory strains of bacteria, which are the sources of many available genome sequences, have lost CRISPR due to a lack of exposure to phages[42]. CRISPR functions as an adaptive and inheritable immune system[40][53][34][38][42]. A CRISPR locus consists of a set of Cas (CRISPR associated) genes, a leader, or promoter, sequence, and an array. This array consists of repeating elements along with "spacers". These spacer regions direct the CRISPR machinery to degrade or otherwise inactivate a complementary sequence in the cell. The CRISPR arrayGenetic information from previous encounters is stored in the array as spacers. These spacers are consistent in length (30-40 bp), and are flanked by repeating elements (also 30-40 bp). The repeating elements are usually partially palindromic, and form secondary structures when transcribed into pre-crRNA. These structures may be necessary for recognition and cleavage. Engineered arraysBy engineering a spacer complementary to T3 phage, increased survival was demonstrated[17][25][28][51][59]. A customized spacer can prevent transformation of PC194 plasmids with a matching sequence[28]. CRISPR in Escherichia coli K-12 substr. MG1655E. coli contains a type I CRISPR system. There are four CRISPR loci in this organism. CRISPR1, the largest, is associated with eight Cas genes[73]. In the classification scheme presented by Haft et al[15], these genes form the Cse family: casA, casB, casC, casD, casE, aka cse1, cse2, cse3, cse4, cas5e[15]. These 5 proteins combine to form the Cascade complex[63]. This is a protein complex of all 5 Cse genes, resembling a seahorse in shape[63]. Its full composition is 1x casA, 2x casB, 6x casC, 1x casD, 1x casE[63]. Specifically, casE cleaves pre-crRNA[25], and casA and casB can be omitted without affecting crRNA generation, but are necessary for phage resistance[63]. This complex binds double stranded target DNA without need or enhancement by cofactors such as metal ions or ATP[63]. It also undergoes conformational changes when binding DNA[63][76]. Cas gene transcription is repressed by H-NS[70], and de-repressed by leuO[48] or baeR[57] .
Structure of the CRISPR I locus in E. coli. 3 promoters have been characterized[43]: Pcrispr1, Pcas, and anti-Pcas. CRISPR in Pyrococcus furiosus DSM 3638This organism is notable due to the diversity of its Cas genes, as well as its possible RNA targeting. P. furiosus contains 7 CRISPR loci, along with 29 Cas genes in 2 gene clusters[35]. All 6 core Cas genes (cas1-cas6), as well as genes from the Cmr (type III), Cst (type I), and Csa (type I) families are present. Cmr1-6 have been found to form a Cascade-like complex that targets RNA in in-vitro experiments[35]. CRISPR in Bacillus halodurans C-125B. halodurans contains 6 Cmr genes (Cmr1-6) in a single locus. This is a type III CRISPR system. The organism also contains Csd1 and Csd2 (Dvulg subtype I-C) along with Cas1, Cas2, Cas3, Cas4, and Cas5 in another locus.
CRISPR in Listeria innocua Clip11262L. innocua contains a type II CRISPR system. A single gene (Cas9 / Csn1) has been shown to be necessary for the expression and inactivation stages of the pathway[65]. A separate trans-encoded small RNA (tracrRNA) binds with the repeat segment of the pre-crRNA[62], followed by cleavage by RNase III and binding with Cas9.
Stages of the CRISPR pathwayThere are 3 distinct stages of the CRISPR pathway: integration[17][54][22], expression, and adaptation. Integration / AdaptationIn this step, DNA, commonly derived from phages and plasmids[48], is recognized and processed by Cas proteins. Information from outside of the genome is recognized and incorporated into the leader end of an existing array. This involves cas1 and cas2[32][58]. The integration stage is currently the least understood aspect of the pathway. ExpressionIn the expression stage, the CRISPR array is transcribed in its entirety, yielding pre-crRNA. This pre-crRNA is cleaved at repeat regions[73][9][27][31] to yield crRNA. In E. coli, this crRNA is 61 bp long, consisting of a 31 bp spacer, flanked by repeat-derived segments on both ends[63] (8 bp at 5'[25][28][27], 21 bp forming a hairpin at 3', with a 5' hydroxyl group). crRNA is then typically bound to a protein complex (known as Cascade in E. coli[63]). InterferenceThis stage requires bound crRNA, as well as Cas3 in E. coli[63]. The interference stage targets DNA in most organisms[25][28][54], but RNA targeting has been demonstrated in the case of P. furiosus[35]. Recognition of target DNA is thought to take place by means of R-loops[63][73][1]. An R-loop is an RNA strand that has base paired with a complementary DNA strand, displacing the other identical DNA strand[1]. This base pairing between the crRNA spacer sequence and target strand may mark the region for interference by other proteins such as cas3[63]. In Streptococcus thermophilus, only Cas9 is necessary for CRISPR functionality[74]. However, a specific sequence, known as a proto-adjacent-motif (PAM) was found to be required for interference. The predicted sequence is 5'-NGGNG-3'. This sequence is found several base pairs upstream of the proto-spacer (target DNA). Single base pair mutations in the PAM completely abolish CRISPR interference[74]. Core Cas genesThere are 6 “core” Cas genes, found in a wide variety of organisms and here referred to as Cas1-Cas6[15]. Cas1, Cas2Cas1 is nearly universally conserved throughout organisms with CRISPR[32]. It is strongly implicated in the integration stage of the pathway[32][58]. Cas1 is a metal-dependent (Mg, Mn) DNA-specific endonuclease that generates an 80 bp fragment[32]. How this is converted into an ~32 bp spacer is unknown. Cas2 is also involved in integration[32][58], and is a metal dependent endoribonuclease[24]. Cas3Cas3 is not regulated by H-NS[41]. It cooperates with the Cascade complex[25] in the interference stage. Cas3 has predicted ATP-dependent helicase activity[4], as well as demonstrated ATP independent annealing of RNA to DNA[73]. It forms an R-loop with DNA, requiring magnesium or manganese as a co-factor[73], but has an antagonistic function in the presence of ATP, dissociating the R-loop. Prevention of self targeting (autoimmunity)The 5' handle of crRNA allows self / nonself discrimination in the csm subtype[39]. In the Cse subtype, regions flanking the proto spacer contain PAMs[39][14][22][30][21], which may be necessary for interference. In general, it is thought that mismatches at positions outside of the spacer sequence allow for targeting, while extended base pairing with the surrounding repeats prevents targeting[39]. CRISPR regulationIn E. coli (Cse subtype), transcription of the Cascade genes and CRISPR array is repressed by H-NS[48][44]. H-NS is a global repressor of transcription in many gram negative bacteria that binds AT rich sequences[16]. This repression is mediated by "DNA stiffening"[37], as well as formation of "DNA-protein-DNA" bridges[11]. The creation of an H-NS knockout can be shown to increase expression of cas genes[48][5]. This correlates with phage sensitivity[48]. Transcription is antagonistically[26] de-repressed by LeuO[48], a protein of the lysR transcription factor family[26] near the leuABCD (leucine synthesis[2]) operon[13]. LeuO expression is also repressed by H-NS[3][6]. Expression of H-NS repressed proteins can be manipulated by plasmid-encoded leuO in a constitutive promoter[33]. Plasmids: pCA24N (lac1 promoter), pKEDR13 (pTac promoter), pNH41 (IPTG). Increased LeuO expression leads to increased expression of casABCDE, cas1, and cas2[48][33], but does not affect cas3 expression[48]. Constitutively expressing leuO had a stronger affect than knocking out H-NS[48]. Classification of CRISPR systemsFor a comprehensive listing of Cas genes, see [1]. Haft (2005) [15]: Recognition of core Cas genes (1-6). Organized remaining genes into 9 subtypes: Ecoli, Ypest, Nmeni, Dvulg, Tneap, Hmari, Apern, Mtube, RAMP. Makarova (2011) [65]: Classification into I, II, and III subtypes, based on mechanism of action as well as homology. These subtypes correspond with the 9 given by Haft to a large extent:
Type I, II and III systemsThis classification takes into account differing mechanisms at all three stages of the pathway[65].
CRISPR resources
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