Detailed information    

experimental Experimentally validated

Overview

Name   addB   Type   Machinery gene
Locus tag   BSU_10620 Genome accession   NC_000964
Coordinates   1136320..1139820 (+) Length   1166 a.a.
NCBI ID   NP_388943.2    Uniprot ID   -
Organism   Bacillus subtilis subsp. subtilis str. 168     
Function   homologous recombination; plasmid transformation   
Homologous recombination

Function

AddB, along with AddA, forms a heterodimer that functions as an ATP-dependent nuclease, processing incoming double-stranded DNA (dsDNA) to generate single-stranded DNA (ssDNA) intermediates. This processing is crucial for the subsequent steps of homologous recombination.


Genomic Context

Location: 1131320..1144820
Locus tag Gene name Coordinates (strand) Size (bp) Protein ID Product Description
  BSU_10580 (BSU10580) yhjO 1132179..1133384 (-) 1206 NP_388939.1 putative permease (recent HGT island) -
  BSU_10590 (BSU10590) yhjP 1133498..1135225 (+) 1728 NP_388940.1 putative transcription factor -
  BSU_10600 (BSU10600) yhjQ 1135255..1135581 (-) 327 NP_388941.1 putative metal-chelating cysteine-rich protein of unknown function -
  BSU_10610 (BSU10610) yhjR 1135699..1136136 (-) 438 NP_388942.1 putative electron carrier protein (putative sporulation gene) -
  BSU_10620 (BSU10620) addB 1136320..1139820 (+) 3501 NP_388943.2 ATP-dependent deoxyribonuclease (subunit B) Machinery gene
  BSU_10630 (BSU10630) addA 1139807..1143505 (+) 3699 NP_388944.2 ATP-dependent deoxyribonuclease (subunit A) Machinery gene
  BSU_10640 (BSU10640) sbcD 1143577..1144752 (+) 1176 NP_388945.3 DNA repair exonuclease -

Sequence

Protein


Download         Length: 1166 a.a.        Molecular weight: 134644.66 Da        Isoelectric Point: 5.5235

>NTDB_id=120 BSU_10620 NP_388943.2 1136320..1139820(+) (addB) [Bacillus subtilis subsp. subtilis str. 168]
MGAEFLVGRSGSGKTKLIINSIQDELRRAPFGKPIIFLVPDQMTFLMEYELAKTPDMGGMIRAQVFSFSRLAWRVLQHTG
GMSRPFLTSTGVQMLLRKLIEEHKQEFKVYQKASDKSGFTAQVERMLTEFKRYCLEPEDIRRMAESGTASEYRGERVLSE
KLHDLSILYQQMEKSLADQYLHSEDYLTLLAEHIPLAEDIKGAHIYVDGFYQFTPQEFRVLEQLMVHAEHITFSLTADKP
SYEREPHELELFRMTGKTYYRLHQKAKELNLDITYKELSGTERHTKTPELAHLEAQYEARPAIPYAEKQEALTVMQAANR
RAELEGIAREIHALVREKGYRYKDVAILARQPEDYKDMVKEVFADYEIPYFIDGKASMLNHPLIEFIRSSLDVLKGNWRY
EAVFRCVKTELLFPLNEPKAKVREQVDQLENYCIAYGIKGDRWTKGDRFQYRRFVSLDDDFAQTDQEIEMENMLNDTRDW
IVPPLFQLQKRMKKAKTVQEKAEALYRYLEETDVPLKLDQERQRAEDDGRIIEAQQHQQAWDAVIQLLEEFVEMMGDDEI
SLDLFQQMIEAGAESLTFSLIPPALDQVFVGNMDLSRMYGTSCTFVLGANDGVLPARPDENGVLSDDDREWLKTIGVELS
SGGRERLLDEHFLIYMAFSSPSDRLYVSYPIADAEGKTLLPSMIVKRLEELFPHHKERLLTNEPEQVSDEEQLMYVVNKS
VAQSFTASQLRLWTREYDISDVWWSTYNVLMSEQDRLQSKKLFSSLFFRNEVKQLERSVSRQLYGERIQGSVSRMETFNA
CPFSHFASHGLHLKERQFFKLEAPDIGQLFHSSLKLISDRLREQKLDWRDLTKEQCELFSYDAVERLAPKLQKEILLSSN
RHYYVKEKLQKIVTRVSGILSEHAKASGFVPIGLELGFGGKGPLPPLTFQLKNGCTMELVGRIDRVDKAESSKGLLLRIV
DYKSSDKGLDLAEVYYGLALQMLTYLDLSITHSADWLGMRATPAGVLYFHIHDPMIQSNLPLGLDEIEQEIFKKFKMKGL
LLGDQEVVRLMDTTLQEGRSNIINAGLKKDGSLRSDSAAVGEKEFDLLTKHVRRTFQEAGEQITDGRVSIEPYKMKNKTP
CTYCAFKSVCQFDESLEENEYRPLKAEKDKTILEWIKKEADGNEHS

Nucleotide


Download         Length: 3501 bp        

>NTDB_id=120 BSU_10620 NP_388943.2 1136320..1139820(+) (addB) [Bacillus subtilis subsp. subtilis str. 168]
TTGGGAGCAGAGTTTTTAGTAGGCAGGTCCGGGAGTGGAAAAACGAAGCTGATCATCAACAGCATTCAGGATGAATTGCG
CCGGGCTCCATTCGGGAAGCCGATCATTTTTCTAGTCCCGGATCAAATGACGTTTTTAATGGAATACGAGCTTGCTAAAA
CGCCAGATATGGGCGGGATGATACGCGCTCAAGTGTTCAGTTTTTCACGATTGGCCTGGCGCGTCCTCCAGCATACGGGA
GGAATGAGCAGGCCGTTTCTGACGAGCACCGGCGTACAAATGCTCCTGCGGAAGCTCATTGAGGAGCATAAACAGGAGTT
CAAAGTCTATCAAAAAGCGAGTGACAAAAGCGGGTTTACCGCACAGGTTGAGCGGATGCTGACAGAGTTTAAGCGCTATT
GTCTGGAACCGGAGGATATCCGCCGGATGGCGGAAAGCGGAACGGCTTCCGAGTATCGCGGAGAACGTGTTTTATCTGAA
AAGCTCCATGACTTATCAATTCTGTATCAGCAAATGGAAAAAAGCCTCGCAGATCAATATCTTCACTCTGAGGATTATTT
GACATTGCTGGCAGAGCATATCCCGCTTGCGGAAGATATAAAAGGCGCCCATATCTATGTGGATGGCTTTTATCAGTTTA
CCCCGCAGGAATTCAGGGTGTTGGAGCAGCTTATGGTTCATGCGGAGCATATCACGTTTTCGCTCACAGCGGACAAGCCG
TCATATGAGCGGGAGCCGCATGAACTGGAATTGTTCAGAATGACGGGGAAAACCTATTACCGCCTGCATCAGAAGGCGAA
GGAACTGAATTTGGACATTACGTATAAAGAGCTGAGCGGGACTGAGCGGCATACAAAGACGCCGGAATTGGCGCATCTAG
AGGCACAGTATGAAGCGCGTCCGGCCATTCCATACGCAGAAAAACAAGAAGCCCTTACTGTGATGCAGGCCGCAAACAGA
CGAGCTGAGCTGGAAGGCATTGCTCGGGAAATTCACGCCCTAGTCAGAGAGAAGGGATATCGCTATAAGGATGTAGCAAT
TCTTGCGCGCCAGCCGGAAGACTACAAGGATATGGTGAAGGAAGTTTTCGCAGATTACGAGATTCCTTATTTCATTGACG
GAAAAGCATCTATGCTGAACCATCCGTTAATTGAATTTATCCGGTCGAGCCTTGATGTTCTGAAAGGGAATTGGCGTTAT
GAAGCGGTGTTTCGCTGCGTGAAAACCGAACTGCTATTCCCGCTCAATGAACCGAAGGCCAAAGTGAGAGAACAGGTCGA
TCAGCTCGAAAATTACTGTATCGCCTATGGTATTAAAGGCGACCGCTGGACAAAGGGCGATCGGTTCCAATACAGGCGTT
TTGTGTCATTGGATGATGATTTTGCGCAGACTGATCAGGAAATCGAAATGGAAAACATGTTGAATGACACCCGCGATTGG
ATTGTTCCGCCGCTTTTTCAGCTTCAAAAACGCATGAAAAAAGCGAAGACGGTTCAAGAGAAGGCGGAGGCGCTCTATCG
TTATTTAGAAGAGACGGATGTGCCGCTGAAGCTGGATCAGGAAAGGCAGCGTGCTGAGGATGACGGCAGAATCATTGAAG
CGCAGCAGCATCAGCAGGCGTGGGACGCAGTCATTCAGCTGCTTGAGGAGTTTGTTGAAATGATGGGAGATGATGAGATT
TCTCTTGATTTGTTTCAGCAAATGATAGAAGCCGGCGCGGAGTCGCTTACATTTTCTCTAATTCCGCCTGCGCTTGACCA
GGTGTTTGTCGGCAATATGGATTTGTCCAGAATGTATGGCACCTCCTGCACCTTTGTGCTCGGGGCAAACGACGGCGTTC
TGCCGGCACGCCCTGATGAAAACGGGGTCCTGTCGGATGATGACCGGGAATGGCTGAAAACGATTGGGGTTGAGCTATCC
TCAGGCGGACGAGAGCGTTTGCTTGATGAGCACTTCCTCATCTACATGGCGTTTTCAAGTCCGTCTGACCGGCTTTACGT
ATCGTATCCGATTGCTGATGCGGAAGGAAAAACGCTTTTGCCGTCGATGATCGTTAAGCGGCTGGAAGAACTGTTTCCGC
ATCATAAGGAGCGCCTGTTAACAAATGAACCTGAACAGGTCAGCGATGAGGAACAGCTGATGTATGTTGTGAATAAAAGC
GTGGCACAGTCCTTTACCGCGAGCCAGCTCAGGTTATGGACTCGGGAATACGACATCAGCGACGTCTGGTGGAGCACGTA
CAATGTGCTGATGAGTGAGCAGGACAGGCTGCAATCGAAAAAGCTGTTCTCAAGCCTGTTTTTCCGGAATGAAGTGAAGC
AGCTTGAACGCAGCGTGTCGAGACAGCTCTATGGTGAACGTATTCAGGGCAGTGTATCGAGAATGGAAACCTTTAACGCA
TGCCCGTTTTCCCATTTTGCGTCACACGGGCTGCATTTGAAGGAACGGCAATTCTTCAAGCTTGAAGCACCGGATATCGG
CCAGCTGTTTCATTCCAGCTTAAAGCTGATTTCGGACAGGCTGCGTGAGCAAAAGCTGGATTGGCGCGATTTAACGAAGG
AGCAGTGCGAGCTGTTTTCCTATGATGCGGTAGAGCGGCTGGCACCGAAACTGCAAAAGGAAATTCTGCTCAGCTCAAAC
CGGCATTATTATGTGAAGGAAAAACTGCAAAAAATTGTGACACGTGTGTCCGGCATTTTAAGCGAGCATGCGAAAGCGAG
CGGATTCGTACCGATCGGGCTTGAACTGGGCTTTGGAGGAAAAGGGCCGCTTCCGCCGCTGACCTTTCAACTGAAAAACG
GCTGTACGATGGAACTCGTCGGGCGAATTGACCGTGTTGATAAGGCTGAAAGCTCAAAAGGCCTGCTCCTCAGGATTGTC
GATTATAAATCAAGCGACAAAGGCCTTGACTTAGCGGAAGTATATTACGGATTGGCACTGCAAATGCTGACGTACCTTGA
TTTATCGATTACACATTCAGCTGACTGGCTCGGGATGAGGGCGACGCCTGCCGGAGTGCTGTATTTCCATATTCATGACC
CGATGATTCAATCTAATCTCCCGCTTGGGCTTGACGAGATTGAACAGGAGATCTTTAAGAAATTTAAAATGAAGGGCTTG
CTCCTCGGTGATCAGGAAGTGGTTCGCCTCATGGATACAACCCTTCAAGAGGGACGTTCAAATATCATAAACGCCGGCTT
GAAAAAAGACGGCTCTCTCAGATCAGACTCAGCAGCAGTCGGTGAAAAGGAATTTGATCTTTTGACAAAGCATGTGCGCC
GCACCTTCCAAGAAGCGGGCGAACAAATCACCGACGGGCGCGTATCCATTGAGCCGTACAAAATGAAGAACAAGACGCCG
TGCACATACTGTGCGTTCAAATCAGTATGCCAATTTGATGAATCACTGGAAGAAAACGAGTATCGCCCATTAAAGGCTGA
AAAGGACAAGACAATACTTGAGTGGATAAAAAAGGAGGCGGATGGCAATGAACATTCCTAA

Domains

Predicted by InterproScan.

UvrD-like helicase C-terminal domain (UvrD_C)

(305-668)

PD-(D/E)XK nuclease superfamily (PDDEXK_1)

(790-1131)


Secondary structure

Protein secondary structures were predicted by S4PRED and visualized by seqviz.



3D structure

Source ID Structure

Transmembrane helices

Transmembrane helices of protein were predicted by TMHMM 2.0 and visualized by seqviz and ECharts.


Visualization of predicted probability:


Similar proteins

Only experimentally validated proteins are listed.

Protein Organism Identities (%) Coverage (%) Ha-value

References

[1] Neville S Gilhooly et al. (2016) Chi hotspots trigger a conformational change in the helicase-like domain of AddAB to activate homologous recombination. Nucleic Acids Research 44(6):2727-41. [PMID: 26762979]
[2] Wojciech W Krajewski et al. (2014) Structural basis for translocation by AddAB helicase-nuclease and its arrest at χ sites. Nature 508(7496):416-9. [PMID: 24670664]
[3] Kayarat Saikrishnan et al. (2012) Insights into Chi recognition from the structure of an AddAB-type helicase-nuclease complex. The EMBO Journal 31(6):1568-78. [PMID: 22307084]
[4] Joseph T P Yeeles et al. (2011) The AddAB helicase-nuclease catalyses rapid and processive DNA unwinding using a single Superfamily 1A motor domain. Nucleic Acids Research 39(6):2271-85. [PMID: 21071401]
[5] Gareth A Cromie (2009) Phylogenetic ubiquity and shuffling of the bacterial RecBCD and AddAB recombination complexes. Journal of Bacteriology 191(16):5076-84. [PMID: 19542287]
[6] B J Haijema et al. (1996) The C terminus of the AddA subunit of the Bacillus subtilis ATP-dependent DNase is required for the ATP-dependent exonuclease activity but not for the helicase activity. Journal of Bacteriology 178(17):5086-91. [PMID: 8752323]
[7] B J Haijema et al. (1995) Expression of the ATP-dependent deoxyribonuclease of Bacillus subtilis is under competence-mediated control. Molecular Microbiology 15(2):203-11. [PMID: 7746142]
[8] J Kooistra et al. (1993) The Bacillus subtilis addAB genes are fully functional in Escherichia coli. Molecular Microbiology 7(6):915-23. [PMID: 8387145]
[9] J C Alonso et al. (1993) Genetic recombination in Bacillus subtilis 168: effect of recN, recF, recH and addAB mutations on DNA repair and recombination. Molecular & General Genetics : MGG 239(1-2):129-36. [PMID: 8510642]