Difference between revisions of "General Information/The casposases"

From TnPedia
Jump to navigation Jump to search
 
(26 intermediate revisions by the same user not shown)
Line 1: Line 1:
 
==The casposases==
 
==The casposases==
More recently, TE related to CRISPRs, Casposons have been identified<ref><nowiki><pubmed>24884953</pubmed></nowiki></ref> and a reassement of their ends has led to the identification of an 14-15 bp target duplication. Moreover, the purified Cas1 enzyme encoded by these ancestral transposons has been demonstrated to catalyse strand transfer of a pre-cleaved transposon in vitro but does not appear to promote transposon strand cleavage in this assay<ref><nowiki><pubmed>26573596</pubmed></nowiki></ref>. Cas1 "casposases" use similar chemistry to that used by the CRISPR Cas1-Cas2 complex but with opposite substrate specificities since CRISPR Cas1-Cas2 integrates "random" sequences into a specific site in the CRISPR locus whereas casposases integrate specific site (the casposon ends) into random target sequences [[:Image:1.44.png|(Fig.1.44)]].
+
More recently, TE related to [[wikipedia:CRISPR|CRISPRs]], Casposons have been identified<ref><pubmed>24884953</pubmed></ref> and a reassement of their ends has led to the identification of an 14-15 bp target duplication <ref><pubmed>PMC4150552</pubmed></ref>. Moreover, the purified [[wikipedia:Cas1|Cas1]] enzyme encoded by these ancestral transposons has been demonstrated to catalyse strand transfer of a pre-cleaved transposon ''in vitro'' but does not appear to promote transposon strand cleavage in this assay<ref><pubmed>26573596</pubmed></ref>. [[wikipedia:Cas1|Cas1]] "casposases" use similar chemistry to that used by the CRISPR [[wikipedia:Cas1|Cas1]]-[[wikipedia:Cas2|Cas2]] complex but with opposite substrate specificities since CRISPR [[wikipedia:Cas1|Cas1]]-[[wikipedia:Cas2|Cas2]] integrates "random" sequences into a specific site in the CRISPR locus whereas casposases integrate a specific site (the casposon ends) into random target sequences [[:Image:1.44.png|(Fig.24.1)]].        
  
[[Image:1.44.png|thumb|center|510x510px|'''Fig 1.44.''' Organization of the ''A. boonei'' casposon. The casposon is shown as an unfilled box. Black filled arrow-heads represent the terminal inverted repeats (TIR); green arrows, the target site duplication (TSD); the genes areas follows: type B DNA polymerase (red box); HNH endonuclease (green); transcriptional regulator with HTH domain (pink); hypothetical protein with HTH domain (orange); cas1 (dark blue) with a c-terminal HTH (light blue); N6-methyltransferase (yellow). From Hickman and Dyda (2015). Non-CRISPR-associated cas1 form two distinct clades. One contains three distinct casposon families (1, 2 and 3) which share features with eukaryotic Polinton/Maverick eukaryotic transposons labelled ‘self-synthesizing’ since they include B family DNA polymerase genes. Members of the three families differ in gene content and evolutionary provenance of the DNA polymerases (protein-primed or RNA-primed).|alt=]]
+
[[Image:1.44.png|thumb|center|510x510px|'''Fig.24.1.''' Organization of the ''[[wikipedia:Aciduliprofundum_boonei|Aciduliprofundum boonei]]'' casposon. The casposon is shown as an unfilled box. Black filled arrow-heads represent the terminal inverted repeats (TIR); green arrows, the target site duplication (TSD); the genes are as follows: type B DNA polymerase (red box); HNH endonuclease (green); transcriptional regulator with HTH domain (pink); hypothetical protein with HTH domain (orange); cas1 (dark blue) with a c-terminal HTH (light blue); N6-methyltransferase (yellow). From Hickman and Dyda (2015). Non-CRISPR-associated cas1 form two distinct clades. One contains three distinct casposon families (1, 2, and 3) which share features with eukaryotic Polinton/Maverick eukaryotic transposons labeled ‘self-synthesizing’ since they include B family DNA polymerase genes. Members of the three families differ in gene content and evolutionary provenance of the DNA polymerases (protein-primed or RNA-primed).|alt=]]
  
 
==Bibliography==
 
==Bibliography==
<references />
+
{{Reflist|32em}}
 +
<br/>
 +
<hr>
 +
{{TnPedia}}

Latest revision as of 12:51, 5 December 2022

The casposases

More recently, TE related to CRISPRs, Casposons have been identified[1] and a reassement of their ends has led to the identification of an 14-15 bp target duplication [2]. Moreover, the purified Cas1 enzyme encoded by these ancestral transposons has been demonstrated to catalyse strand transfer of a pre-cleaved transposon in vitro but does not appear to promote transposon strand cleavage in this assay[3]. Cas1 "casposases" use similar chemistry to that used by the CRISPR Cas1-Cas2 complex but with opposite substrate specificities since CRISPR Cas1-Cas2 integrates "random" sequences into a specific site in the CRISPR locus whereas casposases integrate a specific site (the casposon ends) into random target sequences (Fig.24.1).

Fig.24.1. Organization of the Aciduliprofundum boonei casposon. The casposon is shown as an unfilled box. Black filled arrow-heads represent the terminal inverted repeats (TIR); green arrows, the target site duplication (TSD); the genes are as follows: type B DNA polymerase (red box); HNH endonuclease (green); transcriptional regulator with HTH domain (pink); hypothetical protein with HTH domain (orange); cas1 (dark blue) with a c-terminal HTH (light blue); N6-methyltransferase (yellow). From Hickman and Dyda (2015). Non-CRISPR-associated cas1 form two distinct clades. One contains three distinct casposon families (1, 2, and 3) which share features with eukaryotic Polinton/Maverick eukaryotic transposons labeled ‘self-synthesizing’ since they include B family DNA polymerase genes. Members of the three families differ in gene content and evolutionary provenance of the DNA polymerases (protein-primed or RNA-primed).

Bibliography

  1. Hickman AB, Dyda F . CRISPR-Cas immunity and mobile DNA: a new superfamily of DNA transposons encoding a Cas1 endonuclease. - Mob DNA: 2014, 5;23 [PubMed:25180049] [DOI]