Difference between revisions of "Glossary"

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*<u>Co-integrate</u>:
 
*<u>Co-integrate</u>:
 
*<u>Copy-and-paste transposition model</u>:
 
*<u>Copy-and-paste transposition model</u>:
*Copy-out–Paste-in transposition model:
+
*<u>Copy-out–Paste-in transposition model</u>:
 
*<u>Cut-and-paste transposition model</u>:
 
*<u>Cut-and-paste transposition model</u>:
  
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==D==
 
==D==
  
*'''D'''irect '''R'''epeats (DRs):
+
*<u>'''D'''irect '''R'''epeats (DRs)</u>:
*DDE Domain:
+
*<u>DDE Domain</u>:
*'''D'''onor '''P'''rimed '''R'''eplicative '''T'''ransposition (DPRT):
+
*<u>'''D'''onor '''P'''rimed '''R'''eplicative '''T'''ransposition (DPRT)</u>:
  
 
==E==
 
==E==
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*<u>Group II introns</u>: The group II introns are mobile retroelements that use the combined activities of an autocatalytic RNA and an intron-encoded reverse transcriptase (RT) to propagate efficiently within genomes. They are intimately related with the evolution of eukaryotes, being ancestrally related to nuclear spliceosomal introns, retrotransposons and telomerase ([[wikipedia:Group_II_intron|see also]]).
 
*<u>Group II introns</u>: The group II introns are mobile retroelements that use the combined activities of an autocatalytic RNA and an intron-encoded reverse transcriptase (RT) to propagate efficiently within genomes. They are intimately related with the evolution of eukaryotes, being ancestrally related to nuclear spliceosomal introns, retrotransposons and telomerase ([[wikipedia:Group_II_intron|see also]]).
*Genome decay:
+
*<u>Genome decay</u>:
*Genome Rearrangements:
+
*<u>Genome Rearrangements</u>:
  
 
<br />
 
<br />
 
==H==
 
==H==
  
*Horizontal gene transfer (or Lateral gene transfer):
+
*<u>Horizontal gene transfer (or Lateral gene transfer)</u>:
*Homologous recombination:
+
*<u>Homologous recombination</u>:
  
 
==I==
 
==I==
  
*'''I'''nverted '''R'''epeats (IR):
+
*<u>'''I'''nverted '''R'''epeats (IR)</u>:
 
*<u>Integron</u>: Integrons one class of '''M'''obile '''G'''enetic '''E'''lements (MGEs) are specific genetic structure composed by genes (named as integron cassettes) that generally allow bacteria to adapt and rapidly evolve through the acquisition, stockpiling, excision, and reordering of open reading frames found the integron cassettes. The integron mobilization is mediated by site-specific recombination reactions by the integrase ([[wikipedia:Integron|see also]]).
 
*<u>Integron</u>: Integrons one class of '''M'''obile '''G'''enetic '''E'''lements (MGEs) are specific genetic structure composed by genes (named as integron cassettes) that generally allow bacteria to adapt and rapidly evolve through the acquisition, stockpiling, excision, and reordering of open reading frames found the integron cassettes. The integron mobilization is mediated by site-specific recombination reactions by the integrase ([[wikipedia:Integron|see also]]).
*Invertases:
+
*<u>Invertases</u>:
  
 
==J==
 
==J==
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==M==
 
==M==
  
*Mobilome:
+
*<u>Mobilome</u>:
*Methylase (Methylation):
+
*<u>Methylase (Methylation)</u>:
  
 
==N==
 
==N==
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==P==
 
==P==
  
*Plasmidome:
+
*<u>Plasmidome</u>:
*Pseudogenisation:
+
*<u>Pseudogenisation</u>:
*Peel-and-paste (Single-strand) transposition model:
+
*<u>Peel-and-paste (Single-strand) transposition model</u>:
*Phage tyrosine integrase:
+
*<u>Phage tyrosine integrase</u>:
*Phage serine integrase:
+
*<u>Phage serine integrase</u>:
  
 
==Q==
 
==Q==
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==S==
 
==S==
  
*Synaptic complex:
+
*<u>Synaptic complex</u>:
 
*<u>Serine recombinase:</u> The serine recombinases are a family of DNA breaking and rejoining enzymes. Unlike homologous recombination, the serine recombinases promote rearrangements of DNA by breaking and rejoining strands at precisely defined sequence positions ([[wikipedia:Site-specific_recombination|see also]]).
 
*<u>Serine recombinase:</u> The serine recombinases are a family of DNA breaking and rejoining enzymes. Unlike homologous recombination, the serine recombinases promote rearrangements of DNA by breaking and rejoining strands at precisely defined sequence positions ([[wikipedia:Site-specific_recombination|see also]]).
 
*<u>Serine Resolvases</u>: The serine resolvases and the closely related invertases, are a group of site-specific recombinases that, in their native contexts, resolve large fused replicons into smaller separated ones
 
*<u>Serine Resolvases</u>: The serine resolvases and the closely related invertases, are a group of site-specific recombinases that, in their native contexts, resolve large fused replicons into smaller separated ones
*Single-strand transposition:
+
*<u>Single-strand transposition</u>:
*Site-specific recombination:
+
*<u>Site-specific recombination</u>:
  
 
<br />
 
<br />
 
==T==
 
==T==
  
*Target specificity:
+
*<u>Target specificity</u>:
*Transposase:
+
*<u>Transposase</u>:
*Transposome:
+
*<u>Transposome</u>:
*'''T'''arget '''P'''rimed '''R'''eplicative '''T'''ransposition (TPRT):
+
*<u>'''T'''arget '''P'''rimed '''R'''eplicative '''T'''ransposition (TPRT)</u>:
 
*<u>Tyrosine recombinase:</u> Tyrosine site-specific recombinases (YRs) are a family of DNA breaking and rejoining enzymes which use the active site tyrosine nucleophile for DNA strand breakage ([[wikipedia:Site-specific_recombination#Classification:_tyrosine-_vs._serine-_recombinases|see also]]).
 
*<u>Tyrosine recombinase:</u> Tyrosine site-specific recombinases (YRs) are a family of DNA breaking and rejoining enzymes which use the active site tyrosine nucleophile for DNA strand breakage ([[wikipedia:Site-specific_recombination#Classification:_tyrosine-_vs._serine-_recombinases|see also]]).
  
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==V==
 
==V==
  
*V(D)J Recombination:
+
*<u>V(D)J Recombination</u>:
  
 
==W==
 
==W==
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*<u>Xer Site-Specific Recombination</u>:
 
*<u>Xer Site-Specific Recombination</u>:
  
<br />
 
 
==Y==
 
==Y==
 
==Z==
 
==Z==
 
==See also==
 
==See also==
  
*The logic behind the IS nomenclature and naming attribution
+
*'''The logic behind the IS nomenclature and naming attribution'''
 +
 
 +
According to ...
 +
 
 +
 
 +
 
 +
 
 +
[[File:Wicker.png|center|thumb|592x592px|Proposed classification system for eukaryotic '''T'''ransposable '''E'''lements (TEs) (extracted from [https://www.nature.com/articles/nrg2165 Wicker et al., 2007]).]]

Revision as of 13:55, 24 June 2020

A

B

C

  • Class I Elements: (see also)
  • Class II Elements: (see also)
  • Cre Recombinase: The Cre Recombinase is a DNA breaking and rejoining enzyme (from tyrosine recombinase family) derived from the P1 bacteriophage. It is widely used for conditional mutagenesis of transgenes and insert DNA cassettes into eukaryotic chromosomes. (see also).
  • Co-integrate:
  • Copy-and-paste transposition model:
  • Copy-out–Paste-in transposition model:
  • Cut-and-paste transposition model:


D

  • Direct Repeats (DRs):
  • DDE Domain:
  • Donor Primed Replicative Transposition (DPRT):

E

F

G

  • Group II introns: The group II introns are mobile retroelements that use the combined activities of an autocatalytic RNA and an intron-encoded reverse transcriptase (RT) to propagate efficiently within genomes. They are intimately related with the evolution of eukaryotes, being ancestrally related to nuclear spliceosomal introns, retrotransposons and telomerase (see also).
  • Genome decay:
  • Genome Rearrangements:


H

  • Horizontal gene transfer (or Lateral gene transfer):
  • Homologous recombination:

I

  • Inverted Repeats (IR):
  • Integron: Integrons one class of Mobile Genetic Elements (MGEs) are specific genetic structure composed by genes (named as integron cassettes) that generally allow bacteria to adapt and rapidly evolve through the acquisition, stockpiling, excision, and reordering of open reading frames found the integron cassettes. The integron mobilization is mediated by site-specific recombination reactions by the integrase (see also).
  • Invertases:

J

K

L

M

  • Mobilome:
  • Methylase (Methylation):

N

O

P

  • Plasmidome:
  • Pseudogenisation:
  • Peel-and-paste (Single-strand) transposition model:
  • Phage tyrosine integrase:
  • Phage serine integrase:

Q

R

  • Resolution site:
  • Resolvase:
  • Rolling-circle transposition model:


S

  • Synaptic complex:
  • Serine recombinase: The serine recombinases are a family of DNA breaking and rejoining enzymes. Unlike homologous recombination, the serine recombinases promote rearrangements of DNA by breaking and rejoining strands at precisely defined sequence positions (see also).
  • Serine Resolvases: The serine resolvases and the closely related invertases, are a group of site-specific recombinases that, in their native contexts, resolve large fused replicons into smaller separated ones
  • Single-strand transposition:
  • Site-specific recombination:


T

  • Target specificity:
  • Transposase:
  • Transposome:
  • Target Primed Replicative Transposition (TPRT):
  • Tyrosine recombinase: Tyrosine site-specific recombinases (YRs) are a family of DNA breaking and rejoining enzymes which use the active site tyrosine nucleophile for DNA strand breakage (see also).

U

V

  • V(D)J Recombination:

W

X

  • Xer Site-Specific Recombination:

Y

Z

See also

  • The logic behind the IS nomenclature and naming attribution

According to ...



Proposed classification system for eukaryotic Transposable Elements (TEs) (extracted from Wicker et al., 2007).