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0  structures 1  species 0  interactions 1  sequence 1  architecture

Protein: Q6ZKF1_ORYSJ (Q6ZKF1)

Summary

This is the summary of UniProt entry Q6ZKF1_ORYSJ (Q6ZKF1).

Description: cDNA clone:J033060O03, full insert sequence {ECO:0000313|EMBL:BAG95202.1}
Source organism: Oryza sativa subsp. japonica (Rice) (NCBI taxonomy ID 39947)
Length: 1000 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

Download the data used to generate the domain graphic in JSON format.

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Source Domain Start End
low_complexity n/a 3 9
low_complexity n/a 107 116
Pfam Pep3_Vps18 255 407
Pfam Clathrin 597 759
low_complexity n/a 723 739
coiled_coil n/a 760 780
coiled_coil n/a 796 830
disorder n/a 921 922
disorder n/a 927 931
disorder n/a 933 935
disorder n/a 979 988
disorder n/a 993 997

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Sequence information

This is the amino acid sequence of the UniProt sequence database entry with the accession Q6ZKF1. 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
MDAAAAAFAP GGQLFSVDPL ERHAARGHGV VTSMAAGSDV IVLGTSRGWL
50
51
VRHDFSFEDA HDLDLGTGRS GEHSVHRVFL DPGGKHCVAT VVHPGGAETY
100
101
YHHARWPRPK LLPRLRNVLV NAVAWNRQTI TEASTKEVIL GTEDGQIFEI
150
151
AVDEADKKEK YVKSLFTLSE LQEGIKGLQM ETAVVGNATR FYVMAVTPTR
200
201
LYSFTGIGSL ETVFASYSDR AIHFMELPGD IPNSELHFFI KQRRAKHFGW
250
251
LSGAGIYHGE LNFGAQHSST SGDENFVENK GFFDYSKLGE SGIKPRSFAL
300
301
SEFHFLLLIR DKIKVVNRIS QQIVEELIVD SSPEVTKGII GLCSDASTGL
350
351
FYAYDENSIF QISSSDEGRD MWQVYLDMKE YATALSHCRN SFQRDQVYLV
400
401
QADTAFNTKE YYIAASFYAK MNYILSFEEI SLKFISVGEQ DALRTFLLRR
450
451
LDNLTKDDRM QITMISTWAT ELYLDKINRL LLEDGTGATS NAVADSKDSE
500
501
YRSIVNEFRA FLSDSKDVLD EATTMRLLES YGRVDELVYF AGLKEQHEIV
550
551
VHHYIQQGEA RKALEVLQRH NVLVDLVYKF APDLIMLDAY ETVESWMMAR
600
601
NKLNPGKLIP AMMRYVSEPH AKNETHEVIK YLEFCVKDLN NEDPGVHNLL
650
651
LSLYAKKDDE SQLLQFLDTK FGKGQTNGPE FFYDPKYALR LCLQEKRMRA
700
701
CVRIYSMMSM HEEAVALALT VDLELAKAEA DKVEDDEELR KKLWLKVAKH
750
751
VIEQEKGVKR ENIKKAIEFL SETNNLLKIE DILPFFPDFV LIDDFKEEIC
800
801
KSLKDYDSQI DQLKQEMDDA TRGADNIRSD IGALAQRYTV IDREEECGVC
850
851
KRKILTAGGL HQVGRSYTST GHMAPFYVFP CGHAFHANCL IAHVTRCNSS
900
901
QTQAEKILDL QKRLSLMDRK AAKENGGNMN GESIISATPI DKLRSQLDDA
950
951
VASECPFCGD LMIKEISLPF ILPEESDEKA SWEIKPQPTG QKILPMTMSI
1000
1001
                                                      
1000
 

Show the unformatted sequence.

Checksums:
CRC64:AE123CABE8DB2AC7
MD5:0619c30105bc17c07105d5e2210db8b8

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;