KEGG   PATHWAY: ssl03410
Entry
ssl03410                    Pathway                                
Name
Base excision repair - Sclerotinia sclerotiorum
Description
Base excision repair (BER) is the predominant DNA damage repair pathway for the processing of small base lesions, derived from oxidation and alkylation damages. BER is normally defined as DNA repair initiated by lesion-specific DNA glycosylases and completed by either of the two sub-pathways: short-patch BER where only one nucleotide is replaced and long-patch BER where 2-13 nucleotides are replaced. Each sub-pathway of BER relies on the formation of protein complexes that assemble at the site of the DNA lesion and facilitate repair in a coordinated fashion. This process of complex formation appears to provide an increase in specificity and efficiency to the BER pathway, thereby facilitating the maintenance of genome integrity by preventing the accumulation of highly toxic repair intermediates.
Class
Genetic Information Processing; Replication and repair
Pathway map
ssl03410  Base excision repair
ssl03410

Other DBs
GO: 0006284 0006285 0006286 0006287 0006288
Organism
Sclerotinia sclerotiorum [GN:ssl]
Gene
SS1G_02978  hypothetical protein [KO:K03660] [EC:3.2.2.- 4.2.99.18]
SS1G_00867  hypothetical protein [KO:K10773] [EC:3.2.2.- 4.2.99.18]
SS1G_06269  uracil-DNA glycosylase [KO:K03648] [EC:3.2.2.27]
SS1G_12790  hypothetical protein [KO:K10801] [EC:3.2.2.-]
SS1G_05672  hypothetical protein [KO:K20813] [EC:3.2.2.29]
SS1G_13282  hypothetical protein [KO:K10771] [EC:3.1.11.2]
SS1G_03983  hypothetical protein [KO:K08073] [EC:3.1.3.32 2.7.1.78]
SS1G_13301  hypothetical protein [KO:K10862] [EC:3.1.4.-]
SS1G_11675  hypothetical protein [KO:K10863] [EC:3.6.1.70 3.6.1.71 3.6.1.72]
SS1G_11593  hypothetical protein [KO:K02332] [EC:2.7.7.7]
SS1G_11504  hypothetical protein [KO:K02327] [EC:2.7.7.7]
SS1G_06107  hypothetical protein [KO:K02328]
SS1G_08296  hypothetical protein [KO:K03504]
SS1G_11933  hypothetical protein [KO:K02324] [EC:2.7.7.7]
SS1G_05217  hypothetical protein [KO:K02325] [EC:2.7.7.7]
SS1G_06591  hypothetical protein [KO:K02326] [EC:2.7.7.7]
SS1G_08576  predicted protein [KO:K03506] [EC:2.7.7.7]
SS1G_00911  hypothetical protein [KO:K10754]
SS1G_00433  conserved hypothetical protein [KO:K10755]
SS1G_04432  hypothetical protein [KO:K10755]
SS1G_10275  hypothetical protein [KO:K10756]
SS1G_01540  hypothetical protein [KO:K10756]
SS1G_11175  hypothetical protein [KO:K04799] [EC:3.1.-.-]
SS1G_13713  hypothetical protein [KO:K10747] [EC:6.5.1.1 6.5.1.6 6.5.1.7]
SS1G_02408  hypothetical protein [KO:K10563] [EC:3.2.2.23 4.2.99.18]
SS1G_10574  hypothetical protein [KO:K01247] [EC:3.2.2.21]
Reference
PMID:17893748
  Authors
Krwawicz J, Arczewska KD, Speina E, Maciejewska A, Grzesiuk E.
  Title
Bacterial DNA repair genes and their eukaryotic homologues: 1. Mutations in genes involved in base excision repair (BER) and DNA-end processors and their implication in mutagenesis and human disease.
  Journal
Acta Biochim Pol 54:413-34 (2007)
Reference
PMID:17337257
  Authors
Almeida KH, Sobol RW.
  Title
A unified view of base excision repair: lesion-dependent protein complexes regulated by post-translational modification.
  Journal
DNA Repair (Amst) 6:695-711 (2007)
DOI:10.1016/j.dnarep.2007.01.009
Reference
PMID:21665970
  Authors
Moen MN, Knaevelsrud I, Haugland GT, Grosvik K, Birkeland NK, Klungland A, Bjelland S
  Title
Uracil-DNA glycosylase of Thermoplasma acidophilum directs long-patch base excision repair, which is promoted by deoxynucleoside triphosphates and ATP/ADP, into short-patch repair.
  Journal
J Bacteriol 193:4495-508 (2011)
DOI:10.1128/JB.00233-11
Reference
PMID:11436317
  Authors
Ikeda S, Seki S.
  Title
[Base excision repair: DNA glycosylase and AP endonuclease]
  Journal
Tanpakushitsu Kakusan Koso 46:916-23 (2001)
KO pathway
ko03410   

  All links  
Genome (1)   
   KEGG GENOME (1)   
Gene (26)   
   KEGG GENES (26)   
All databases (27)   

Download RDF
DBGET integrated database retrieval system