Detailed information    

insolico Bioinformatically predicted

Overview


Name   uvrA   Type   Machinery gene
Locus tag   KIM25_RS25595 Genome accession   NZ_CP074856
Coordinates   5034890..5037712 (+) Length   940 a.a.
NCBI ID   WP_000357740.1    Uniprot ID   Q3YUS6
Organism   Escherichia coli strain 2013C_3997_C1     
Function   homologous recombination (predicted from homology)   
Homologous recombination

Genomic Context


Location: 5029890..5042712
Locus tag Gene name Coordinates (strand) Size (bp) Protein ID Product Description
  KIM25_RS25570 (KIM25_25285) soxR 5030828..5031292 (-) 465 WP_000412428.1 redox-sensitive transcriptional activator SoxR -
  KIM25_RS25575 (KIM25_25290) soxS 5031378..5031701 (+) 324 WP_000019358.1 superoxide response transcriptional regulator SoxS -
  KIM25_RS25580 (KIM25_25295) pdeC 5031704..5033290 (-) 1587 WP_106913240.1 c-di-GMP phosphodiesterase PdeC -
  KIM25_RS25585 (KIM25_25300) yjcB 5033720..5034001 (+) 282 WP_001341690.1 YjcB family protein -
  KIM25_RS25590 (KIM25_25305) ssb 5034100..5034636 (-) 537 WP_000168305.1 single-stranded DNA-binding protein SSB1 Machinery gene
  KIM25_RS25595 (KIM25_25310) uvrA 5034890..5037712 (+) 2823 WP_000357740.1 excinuclease ABC subunit UvrA Machinery gene
  KIM25_RS25600 (KIM25_25315) yjbR 5037747..5038103 (-) 357 WP_000155657.1 MmcQ/YjbR family DNA-binding protein -
  KIM25_RS25605 (KIM25_25320) yjbQ 5038107..5038523 (-) 417 WP_000270375.1 secondary thiamine-phosphate synthase enzyme YjbQ -
  KIM25_RS25610 (KIM25_25325) aphA 5038634..5039347 (-) 714 WP_001375558.1 acid phosphatase AphA -
  KIM25_RS25615 - 5039749..5039971 (+) 223 Protein_5020 hypothetical protein -
  KIM25_RS25620 - 5040001..5040252 (+) 252 WP_122989400.1 hypothetical protein -
  KIM25_RS25625 (KIM25_25335) tyrB 5040474..5041667 (-) 1194 WP_000486997.1 aromatic amino acid transaminase -

Sequence


Protein


Download         Length: 940 a.a.        Molecular weight: 103867.54 Da        Isoelectric Point: 6.6066

>NTDB_id=493893 KIM25_RS25595 WP_000357740.1 5034890..5037712(+) (uvrA) [Escherichia coli strain 2013C_3997_C1]
MDKIEVRGARTHNLKNINLVIPRDKLIVVTGLSGSGKSSLAFDTLYAEGQRRYVESLSAYARQFLSLMEKPDVDHIEGLS
PAISIEQKSTSHNPRSTVGTITEIHDYLRLLFARVGEPRCPDHDVPLAAQTVSQMVDNVLSQPEGKRLMLLAPIIKERKG
EHTKTLENLASQGYIRARIDGEVCDLSDPPKLELQKKHTIEVVVDRFKVRDDLTQRLAESFETALELSGGTAVVADMDDP
KAEELLFSANFACPICGYSMRELEPRLFSFNNPAGACPTCDGLGVQQYFDPDRVIQNPELSLAGGAIRGWDRRNFYYFQM
LKSLADHYKFDVEAPWGSLSANVHKVVLYGSGKENIEFKYMNDRGDTSIRRHPFEGVLHNMERRYKETESSAVREELAKF
ISNRPCASCEGTRLRREARHVYVENTPLPAISDMSIGHAMEFFNNLKLAGQRAKIAEKILKEIGDRLKFLVNVGLNYLTL
SRSAETLSGGEAQRIRLASQIGAGLVGVMYVLDEPSIGLHQRDNERLLGTLIHLRDLGNTVIVVEHDEDAIRAADHVIDI
GPGAGVHGGEVVAEGPLEAIMAVPESLTGQYMSGKRKIEVPKKRVPANPEKVLKLTGARGNNLKDVTLTLPVGLFTCITG
VSGSGKSTLINDTLFPIAQRQLNGATIAEPAPYRDIQGLEHFDKVIDIDQSPIGRTPRSNPATYTGVFTPVRELFAGVPE
SRARGYTPGRFSFNVRGGRCEACQGDGVIKVEMHFLPDIYVPCDQCKGKRYNRETLEIKYKGKTIHEVLDMTIEEAREFF
DAVPALARKLQTLMDVGLTYIRLGQSATTLSGGEAQRVKLARELSKRGTGQTLYILDEPTTGLHFADIQQLLDVLHKLRD
QGNTIVVIEHNLDVIKTADWIVDLGPEGGSGGGEILVSGTPETVAECEASHTARFLKPML

Nucleotide


Download         Length: 2823 bp        

>NTDB_id=493893 KIM25_RS25595 WP_000357740.1 5034890..5037712(+) (uvrA) [Escherichia coli strain 2013C_3997_C1]
ATGGATAAGATCGAAGTTCGGGGCGCCCGCACCCATAATCTCAAAAACATCAACCTCGTTATCCCCCGCGACAAGCTCAT
TGTCGTGACCGGGCTTTCGGGTTCTGGCAAATCCTCGCTCGCTTTCGACACCTTATATGCCGAAGGGCAGCGCCGTTACG
TTGAATCCCTTTCCGCCTACGCGCGGCAGTTTCTGTCACTGATGGAAAAGCCGGACGTCGATCATATTGAGGGGCTTTCT
CCTGCCATCTCAATTGAGCAGAAATCGACGTCTCATAACCCGCGTTCTACGGTGGGGACAATCACCGAAATCCACGACTA
TTTGCGTTTGTTGTTCGCCCGCGTCGGCGAACCGCGCTGTCCGGACCACGACGTCCCGCTGGCGGCGCAAACCGTCAGCC
AGATGGTGGATAACGTGCTGTCGCAGCCGGAAGGCAAGCGTCTGATGCTGCTCGCGCCAATCATTAAAGAGCGCAAAGGC
GAACACACCAAAACGCTGGAGAACCTGGCAAGCCAGGGTTACATCCGTGCTCGTATTGATGGCGAAGTCTGCGATCTTTC
CGATCCGCCGAAACTGGAACTGCAAAAGAAACATACCATTGAAGTGGTGGTTGATCGCTTCAAGGTGCGTGACGATCTTA
CCCAACGTCTTGCGGAGTCGTTTGAAACCGCGCTGGAGCTTTCCGGTGGTACAGCGGTAGTGGCGGATATGGACGACCCG
AAAGCGGAAGAGCTGCTGTTCTCCGCCAACTTCGCCTGCCCAATTTGCGGCTACAGTATGCGTGAACTGGAGCCGCGACT
GTTTTCGTTTAACAACCCGGCAGGTGCCTGCCCGACCTGTGACGGCCTTGGCGTACAGCAATATTTCGATCCTGACCGCG
TGATCCAAAACCCCGAGCTGTCACTGGCTGGCGGTGCGATCCGTGGCTGGGATCGCCGCAACTTCTATTACTTCCAGATG
CTGAAATCGCTGGCAGATCACTATAAGTTCGACGTCGAAGCGCCGTGGGGCAGCCTGAGCGCGAACGTGCATAAAGTGGT
GTTGTACGGTTCTGGCAAAGAAAACATTGAATTCAAATACATGAACGATCGTGGCGATACCTCCATCCGTCGTCATCCGT
TCGAAGGCGTGCTGCACAATATGGAGCGCCGTTATAAAGAGACAGAATCCAGTGCGGTACGTGAAGAATTAGCCAAGTTT
ATCAGCAATCGCCCATGCGCCAGCTGCGAAGGGACGCGTCTGCGTCGGGAAGCGCGCCACGTTTATGTCGAGAATACGCC
GCTGCCTGCTATCTCCGACATGAGCATCGGTCATGCGATGGAATTCTTCAACAATCTCAAACTCGCTGGTCAACGGGCGA
AGATTGCGGAAAAAATCCTTAAAGAGATCGGCGATCGTTTGAAATTCCTCGTTAACGTCGGCCTGAATTACCTGACGCTT
TCCCGCTCGGCAGAAACGCTTTCCGGCGGTGAAGCCCAGCGTATCCGTCTGGCGAGCCAGATTGGTGCGGGCCTGGTTGG
CGTTATGTACGTGCTGGACGAGCCATCTATCGGCCTGCACCAGCGCGATAACGAGCGCCTGTTGGGTACGCTTATCCATC
TGCGCGATCTCGGTAATACCGTGATTGTGGTGGAGCACGACGAAGACGCAATTCGCGCCGCTGACCATGTGATCGACATT
GGCCCGGGCGCAGGTGTTCACGGCGGTGAAGTGGTCGCAGAAGGTCCGCTGGAAGCGATTATGGCGGTGCCGGAGTCGTT
GACCGGGCAGTACATGAGCGGCAAACGCAAGATTGAAGTGCCGAAGAAACGCGTTCCGGCGAATCCGGAAAAAGTGCTGA
AGCTGACAGGCGCACGCGGCAACAACCTGAAGGACGTGACGCTGACGCTGCCGGTGGGTCTGTTTACCTGCATCACCGGG
GTTTCAGGTTCCGGTAAATCGACGCTGATTAACGACACACTGTTCCCGATTGCCCAACGCCAGTTGAATGGGGCGACCAT
CGCCGAACCAGCACCGTATCGCGATATTCAGGGGCTGGAGCATTTCGATAAAGTGATCGATATCGACCAAAGCCCAATTG
GTCGTACTCCACGTTCTAACCCGGCGACCTATACCGGCGTGTTTACGCCTGTGCGCGAACTGTTTGCGGGCGTACCGGAA
TCCCGTGCGCGTGGTTATACGCCAGGACGTTTCAGCTTTAACGTCCGTGGCGGGCGCTGCGAAGCCTGTCAGGGCGACGG
TGTGATCAAAGTAGAGATGCACTTCCTGCCGGATATCTACGTGCCGTGCGATCAGTGTAAAGGTAAACGCTATAACCGTG
AAACGCTGGAAATTAAGTACAAAGGCAAAACCATCCACGAAGTGCTGGATATGACCATCGAAGAGGCGCGTGAGTTCTTT
GATGCCGTACCTGCACTGGCGCGTAAGCTGCAAACGTTGATGGACGTTGGCCTGACGTACATTCGCCTGGGGCAGTCCGC
AACCACACTTTCTGGTGGTGAAGCCCAGCGCGTGAAGCTGGCGCGTGAGCTGTCAAAACGCGGCACCGGGCAGACGCTGT
ATATTCTCGACGAGCCGACCACCGGTCTGCACTTCGCCGATATTCAGCAACTGCTCGACGTACTGCATAAACTGCGCGAT
CAGGGCAACACCATTGTGGTGATTGAGCACAATCTCGACGTGATCAAAACCGCTGACTGGATTGTCGACCTGGGACCAGA
AGGCGGCAGTGGCGGCGGCGAAATCCTCGTCTCCGGTACGCCAGAAACCGTCGCGGAGTGCGAAGCTTCGCATACGGCAC
GCTTCCTCAAGCCGATGCTGTAA


Secondary structure


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



3D structure


Source ID Structure
  AlphaFold DB Q3YUS6

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
  uvrA Streptococcus pneumoniae R6

57.37

100

0.576

  uvrA Streptococcus pneumoniae TIGR4

57.37

100

0.576

  uvrA Streptococcus pneumoniae D39

57.37

100

0.576