Literature for family C3

Family

Summary Holotypes Alignment Tree Genomes Structure Literature Architecture

C3A

Summary Holotypes Alignment Tree Genomes Literature

C3B

Summary Holotypes Alignment Tree Genomes Literature

C3C

Summary Holotypes Alignment Tree Genomes Literature

C3D

Summary Holotypes Alignment Tree Genomes Literature

C3E

Summary Holotypes Alignment Tree Genomes Literature

C3F

Summary Holotypes Alignment Tree Genomes Literature

C3G

Summary Holotypes Alignment Tree Genomes Literature

C3H

Summary Holotypes Alignment Tree Genomes Literature


(Topics flags: S Structure, T Target, I Inhibitor. To select only the references relevant to a single topic, click the link above. See explanation.)

    2017
  1. Li,B., Yue,Y., Zhang,Y., Yuan,Z., Li,P., Song,N., Lin,W., Liu,Y., Gu,L. and Meng,H.
    A novel enterovirus 71 (EV71) virulence determinant: the 69th residue of 3C protease modulates pathogenicity
    Front Cell Infect Microbiol (2017) 7, 26-26. PubMed  Europe PubMed DOI  PMC  EPMC  S
  2. 2016
  3. Sun,D., Chen,S., Cheng,A. and Wang,M.
    Roles of the picornaviral 3C proteinase in the viral life cycle and host cells
    Viruses (2016) 8, 82-82. PubMed  Europe PubMed DOI  I
  4. Zhang,Q.-Y., Zhang,W.-H., Xiao,J.-H. and Li,S.
    Broad spectrum inhibitors of 3C and 3CL proteases: research advances
    J Int Pharm Res (2016) 43, 425-430. DOI  I
  5. 2011
  6. Ramajayam,R., Tan,K.P. and Liang,P.H.
    Recent development of 3C and 3CL protease inhibitors for anti-coronavirus and anti-picornavirus drug discovery
    Biochem Soc Trans (2011) 39, 1371-1375. PubMed  Europe PubMed DOI  I
  7. 2008
  8. Koonin,E.V., Wolf,Y.I., Nagasaki,K. and Dolja,V.V.
    The Big Bang of picorna-like virus evolution antedates the radiation of eukaryotic supergroups
    Nat Rev Microbiol (2008) 6, 925-939. PubMed  Europe PubMed DOI
  9. 2007
  10. [YEAR:14-8-2007]Curry,S., Roque-Rosell,N., Zunszain,P.A. and Leatherbarrow,R.J.
    Foot-and-mouth disease virus 3C protease: recent structural and functional insights into an antiviral target
    Int J Biochem Cell Biol (14-8-2007) 39, 1-6. PubMed  Europe PubMed DOI  T
  11. 2006
  12. [YEAR:7-7-2006]Yin,J., Cherney,M.M., Bergmann,E.M., Zhang,J., Huitema,C., Pettersson,H., Eltis,L.D., Vederas,J.C. and James,M.N.
    An episulfide cation (thiiranium ring) trapped in the active site of HAV 3C proteinase inactivated by peptide-based ketone inhibitors
    J Mol Biol (7-7-2006) 361, 673-686. PubMed  Europe PubMed DOI  S  I
  13. 2001
  14. [YEAR:4-9-2001]Sarkany,Z., Szeltner,Z. and Polgar,L.
    Thiolate-imidazolium ion pair is not an obligatory catalytic entity of cysteine peptidases: the active site of picornain 3C
    Biochemistry (4-9-2001) 40, 10601-10606. PubMed  Europe PubMed DOI
  15. 2000
  16. [YEAR:22-9-2000]Sarkany,Z., Skern,T. and Polgar,L.
    Characterization of the active site thiol group of rhinovirus 2A proteinase
    FEBS Lett (22-9-2000) 481, 289-292. PubMed  Europe PubMed DOI  I
  17. 1996
  18. De Francesco,R., Urbani,A., Nardi,M.C., Tomei,L., Steinkuhler,C. and Tramontano,A.
    A zinc binding site in viral serine proteinases
    Biochemistry (1996) 35, 13282-13287. PubMed  Europe PubMed DOI
  19. 1994
  20. [YEAR:5-5-1994]Allaire,M., Chernaia,M.M., Malcolm,B.A. and James,M.N.
    Picornaviral 3C cysteine proteinases have a fold similar to chymotrypsin-like serine proteinases
    Nature (5-5-1994) 369, 72-76. PubMed  Europe PubMed DOI  S
  21. Matthews,D.A., Smith,W.W., Ferre,R.A., Condon,B., Budahazi,G., Sisson,W., Villafranca,J.E., Janson,C.A., McElroy,H.E., Gribskov,C.L. and Worland,S.
    Structure of human rhinovirus 3C protease reveals a trypsin-like polypeptide fold, RNA-binding site, and means for cleaving precursor polyprotein
    Cell (1994) 77, 761-771. PubMed  Europe PubMed DOI  S
  22. 1990
  23. Neill,J.D.
    Nucleotide sequence of a region of the feline calicivirus genome which encodes picornavirus-like RNA-dependent RNA polymerase, cysteine protease and 2C polypeptides
    Virus Res (1990) 17, 145-160. PubMed  Europe PubMed DOI
  24. Palmenberg,A.C.
    Proteolytic processing of picornaviral polyprotein
    Annu Rev Microbiol (1990) 44, 603-623. PubMed  Europe PubMed DOI
  25. 1989
  26. [YEAR:30-1-1989]Gorbalenya,A.E., Donchenko,A.P., Blinov,V.M. and Koonin,E.V.
    Cysteine proteases of positive strand RNA viruses and chymotrypsin-like serine proteases. A distinct protein superfamily with a common structural fold
    FEBS Lett (30-1-1989) 243, 103-114. PubMed  Europe PubMed DOI
  27. 1988
  28. Bazan,J.F. and Fletterick,R.J.
    Viral cysteine proteases are homologous to the trypsin-like family of serine proteases: structural and functional implications
    Proc Natl Acad Sci U S A (1988) 85, 7872-7876. PubMed  Europe PubMed  PMC  EPMC
  29. 1984
  30. [YEAR:25-9-1984]Argos,P., Kamer,G., Nicklin,M.J. and Wimmer,E.
    Similarity in gene organization and homology between proteins of animal picornaviruses and a plant comovirus suggest common ancestry of these virus families
    Nucleic Acids Res (25-9-1984) 12, 7251-7267. PubMed  Europe PubMed  PMC  EPMC