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0  structures 1  species 0  interactions 1  sequence 1  architecture

Protein: PHYC_ARATH (P14714)

Summary

This is the summary of UniProt entry PHYC_ARATH (P14714).

Description: Phytochrome C
Source organism: Arabidopsis thaliana (Mouse-ear cress) (NCBI taxonomy ID 3702)
Length: 1111 amino acids
Reference Proteome: ✓

Please note: when we start each new Pfam data release, we take a copy of the UniProt sequence database. This snapshot of UniProt forms the basis of the overview that you see here. It is important to note that, although some UniProt entries may be removed after a Pfam release, these entries will not be removed from Pfam until the next Pfam data release.

Pfam domains

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Source Domain Start End
disorder n/a 1 13
low_complexity n/a 2 18
low_complexity n/a 10 25
Pfam PAS_2 64 180
disorder n/a 105 106
Pfam GAF 213 393
Pfam PHY 404 582
disorder n/a 524 536
Pfam PAS 606 721
Pfam PAS 736 862
Pfam HATPase_c 994 1109

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Sequence information

This is the amino acid sequence of the UniProt sequence database entry with the accession P14714. This sequence is stored in the Pfam database and updated with each new Pfam release, but this means that the sequence we store may differ from that stored by UniProt.

Sequence:
1
MSSNTSRSCS TRSRQNSRVS SQVLVDAKLH GNFEESERLF DYSASINLNM
50
51
PSSSCEIPSS AVSTYLQKIQ RGMLIQPFGC LIVVDEKNLK VIAFSENTQE
100
101
MLGLIPHTVP SMEQREALTI GTDVKSLFLS PGCSALEKAV DFGEISILNP
150
151
ITLHCRSSSK PFYAILHRIE EGLVIDLEPV SPDEVPVTAA GALRSYKLAA
200
201
KSISRLQALP SGNMLLLCDA LVKEVSELTG YDRVMVYKFH EDGHGEVIAE
250
251
CCREDMEPYL GLHYSATDIP QASRFLFMRN KVRMICDCSA VPVKVVQDKS
300
301
LSQPISLSGS TLRAPHGCHA QYMSNMGSVA SLVMSVTING SDSDEMNRDL
350
351
QTGRHLWGLV VCHHASPRFV PFPLRYACEF LTQVFGVQIN KEAESAVLLK
400
401
EKRILQTQSV LCDMLFRNAP IGIVTQSPNI MDLVKCDGAA LYYRDNLWSL
450
451
GVTPTETQIR DLIDWVLKSH GGNTGFTTES LMESGYPDAS VLGESICGMA
500
501
AVYISEKDFL FWFRSSTAKQ IKWGGARHDP NDRDGKRMHP RSSFKAFMEI
550
551
VRWKSVPWDD MEMDAINSLQ LIIKGSLQEE HSKTVVDVPL VDNRVQKVDE
600
601
LCVIVNEMVR LIDTAAVPIF AVDASGVING WNSKAAEVTG LAVEQAIGKP
650
651
VSDLVEDDSV ETVKNMLALA LEGSEERGAE IRIRAFGPKR KSSPVELVVN
700
701
TCCSRDMTNN VLGVCFIGQD VTGQKTLTEN YSRVKGDYAR IMWSPSTLIP
750
751
PIFITNENGV CSEWNNAMQK LSGIKREEVV NKILLGEVFT TDDYGCCLKD
800
801
HDTLTKLRIG FNAVISGQKN IEKLLFGFYH RDGSFIEALL SANKRTDIEG
850
851
KVTGVLCFLQ VPSPELQYAL QVQQISEHAI ACALNKLAYL RHEVKDPEKA
900
901
ISFLQDLLHS SGLSEDQKRL LRTSVLCREQ LAKVISDSDI EGIEEGYVEL
950
951
DCSEFGLQES LEAVVKQVME LSIERKVQIS CDYPQEVSSM RLYGDNLRLQ
1000
1001
QILSETLLSS IRFTPALRGL CVSFKVIARI EAIGKRMKRV ELEFRIIHPA
1050
1051
PGLPEDLVRE MFQPLRKGTS REGLGLHITQ KLVKLMERGT LRYLRESEMS
1100
1101
AFVILTEFPL I                                          
1111
 

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Checksums:
CRC64:58FE4645501135CA
MD5:9d166f7db025e4cd2a7b994716f017bd

AlphaFold Structure Prediction

The protein structure below has been predicted by DeepMind with AlphaFold. For more information, please visit the AlphaFold page for this protein.

Model confidence scale

  Very High (pLDDT > 90)
  Confident (90 > pLDDT > 70)
  Low (70 > pLDDT > 50)
  Very Low (pLDDT < 50)
Highly accurate protein structure prediction with AlphaFold. John Jumper, Richard Evans, Alexander Pritzel, Tim Green, Michael Figurnov, Olaf Ronneberger, Kathryn Tunyasuvunakool, Russ Bates, Augustin Žídek, Anna Potapenko, Alex Bridgland, Clemens Meyer, Simon A. A. Kohl, Andrew J. Ballard, Andrew Cowie, Bernardino Romera-Paredes, Stanislav Nikolov, Rishub Jain, Jonas Adler, Trevor Back, Stig Petersen, David Reiman, Ellen Clancy, Michal Zielinski, Martin Steinegger, Michalina Pacholska, Tamas Berghammer, Sebastian Bodenstein, David Silver, Oriol Vinyals, Andrew W. Senior, Koray Kavukcuoglu, Pushmeet Kohli & Demis Hassabis Nature 2021-07-15; DOI: 10.1038/s41586-021-03819-2;