Difference between revisions of "Translation"
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=Back to [[categories]]= | =Back to [[categories]]= |
Revision as of 12:37, 19 June 2014
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Contents
- 1 Genes in this functional category
- 1.1 Ribosomal RNA
- 1.2 rRNA modification and maturation
- 1.3 rRNA modification and maturation/ based on similarity
- 1.4 Ribosomal proteins
- 1.5 Ribosomal protein/ based on similarity
- 1.6 Ribosome assembly
- 1.7 tRNA
- 1.8 tRNA modification and maturation
- 1.9 tRNA modification and maturation/ based on similarity
- 1.10 Aminoacyl-tRNA synthetases
- 1.11 Translation factors
- 1.12 Translation/ other
- 1.13 Translation/ other/ based on similarity
- 2 Important publications
- 3 Back to categories
Genes in this functional category
Ribosomal RNA
- rrnA-16S
- rrnA-23S
- rrnA-5S
- rrnB-16S
- rrnB-23S
- rrnB-5S
- rrnD-16S
- rrnD-23S
- rrnD-5S
- rrnE-16S
- rrnE-23S
- rrnE-5S
- rrnG-16S
- rrnG-23S
- rrnG-5S
- rrnH-16S
- rrnH-23S
- rrnH-5S
- rrnI-16S
- rrnI-23S
- rrnI-5S
- rrnJ-16S
- rrnJ-23S
- rrnJ-5S
- rrnO-16S
- rrnO-23S
- rrnO-5S
- rrnW-16S
- rrnW-23S
- rrnW-5S
rRNA modification and maturation
rRNA modification and maturation/ based on similarity
Ribosomal proteins
- ctc
- rplA
- rplB
- rplC
- rplD
- rplE
- rplF
- rplI
- rplJ
- rplK
- rplL
- rplM
- rplN
- rplO
- rplP
- rplQ
- rplR
- rplS
- rplT
- rplU
- rplV
- rplW
- rplX
- rpmA
- rpmB
- rpmC
- rpmD
- rpmE
- rpmF
- rpmGA
- rpmGB
- rpmH
- rpmI
- rpmJ
- rpsB
- rpsC
- rpsD
- rpsE
- rpsF
- rpsG
- rpsH
- rpsI
- rpsJ
- rpsK
- rpsL
- rpsM
- rpsN
- rpsO
- rpsP
- rpsQ
- rpsR
- rpsS
- rpsT
- rpsU
- ybxF
- yhzA
- ytiA
Ribosomal protein/ based on similarity
Ribosome assembly
tRNA
- trnA-Ala
- trnA-Ile
- trnB-Ala
- trnB-Arg
- trnB-Asn
- trnB-Asp
- trnB-Glu
- trnB-Gly1
- trnB-Gly2
- trnB-His
- trnB-Ile2
- trnB-Leu1
- trnB-Leu2
- trnB-Lys
- trnB-Met1
- trnB-Met2
- trnB-Met3
- trnB-Phe
- trnB-Pro
- trnB-Ser1
- trnB-Ser2
- trnB-Thr
- trnB-Val
- trnD-Asn
- trnD-Asp
- trnD-Cys
- trnD-Gln
- trnD-Glu
- trnD-Gly
- trnD-His
- trnD-Leu1
- trnD-Leu2
- trnD-Met
- trnD-Phe
- trnD-Ser
- trnD-Thr
- trnD-Trp
- trnD-Tyr
- trnD-Val
- trnE-Arg
- trnE-Asp
- trnE-Gly
- trnE-Met
- trnI-Ala
- trnI-Arg
- trnI-Asn
- trnI-Gly
- trnI-Pro
- trnI-Thr
- trnJ-Ala
- trnJ-Arg
- trnJ-Gly
- trnJ-Leu1
- trnJ-Leu2
- trnJ-Lys
- trnJ-Pro
- trnJ-Thr
- trnJ-Val
- trnO-Ala
- trnO-Ile
- trnQ-Arg
- trnS-Asn
- trnS-Gln
- trnS-Glu
- trnS-Leu1
- trnS-Leu2
- trnS-Lys
- trnS-Ser
- trnSL-Ala1
- trnSL-Arg1
- trnSL-Arg2
- trnSL-Gln1
- trnSL-Gln2
- trnSL-Glu1
- trnSL-Glu2
- trnSL-Gly1
- trnSL-Met1
- trnSL-Ser1
- trnSL-Thr1
- trnSL-Tyr1
- trnSL-Val1
- trnSL-Val2
- trnY-Asp
- trnY-Glu
- trnY-Lys
- trnY-Phe
tRNA modification and maturation
- cca
- cspR
- fmt
- folD
- gidA
- miaA
- nifZ
- queA
- queC
- queD
- queE
- queF
- queG
- rnpA
- rnpB
- rnz
- rph
- tgt
- thdF
- thiI
- tilS
- trmB
- trmD
- trmFO
- trmK
- trmU
- truA
- truB
- tsaB
- tsaC
- tsaD
- tsaE
- yaaJ
- yacF
- yfjN
- ymcB
- yqeV
- yrvM
tRNA modification and maturation/ based on similarity
Aminoacyl-tRNA synthetases
- alaS
- argS
- asnS
- aspS
- cysS
- gatA
- gatB
- gatC
- gltX
- glyQ
- glyS
- hisS
- hisZ
- ileS
- leuS
- lysS
- metS
- pheS
- pheT
- proS
- serS
- thrS
- thrZ
- trpS
- tyrS
- tyrZ
- valS
- ytpR
Discussion of the structure of aminoacyl-tRNA synthetases
Translation factors
Translation/ other
Translation/ other/ based on similarity
Important publications
Henri Grosjean, Marc Breton, Pascal Sirand-Pugnet, Florence Tardy, François Thiaucourt, Christine Citti, Aurélien Barré, Satoko Yoshizawa, Dominique Fourmy, Valérie de Crécy-Lagard, Alain Blanchard
Predicting the minimal translation apparatus: lessons from the reductive evolution of mollicutes.
PLoS Genet: 2014, 10(5);e1004363
[PubMed:24809820]
[WorldCat.org]
[DOI]
(I e)
Matthew H Larson, Rachel A Mooney, Jason M Peters, Tricia Windgassen, Dhananjaya Nayak, Carol A Gross, Steven M Block, William J Greenleaf, Robert Landick, Jonathan S Weissman
A pause sequence enriched at translation start sites drives transcription dynamics in vivo.
Science: 2014, 344(6187);1042-7
[PubMed:24789973]
[WorldCat.org]
[DOI]
(I p)
Basma El Yacoubi, Marc Bailly, Valérie de Crécy-Lagard
Biosynthesis and function of posttranscriptional modifications of transfer RNAs.
Annu Rev Genet: 2012, 46;69-95
[PubMed:22905870]
[WorldCat.org]
[DOI]
(I p)
Alex Rosenberg, Lior Sinai, Yoav Smith, Sigal Ben-Yehuda
Dynamic expression of the translational machinery during Bacillus subtilis life cycle at a single cell level.
PLoS One: 2012, 7(7);e41921
[PubMed:22848659]
[WorldCat.org]
[DOI]
(I p)
Gene-Wei Li, Eugene Oh, Jonathan S Weissman
The anti-Shine-Dalgarno sequence drives translational pausing and codon choice in bacteria.
Nature: 2012, 484(7395);538-41
[PubMed:22456704]
[WorldCat.org]
[DOI]
(I e)