Literature for peptidase C01.003: caricain

Summary Alignment Sequences Sequence features Distribution Structure Literature Substrates

(Topics flags: S Structure, P Specificity, V Review. To select only the references relevant to a single topic, click the link above. See explanation.)

2023

Vaissier Welborn,V.
Understanding Cysteine Reactivity in Protein Environments with Electric Fields
J Phys Chem B127, 9936-9942. PubMed Europe PubMed DOI

2016

Cornell,H.J., Stelmasiak,T., Small,D.M. and Buddrick,O.
Application of the rat liver lysosome assay to determining the reduction of toxic gliadin content during breadmaking
Food Chem192, 924-927. PubMed Europe PubMed DOI

2015

Buddrick,O., Cornell,H.J. and Small,D.M.
Reduction of toxic gliadin content of wholegrain bread by the enzyme caricain
Food Chem170, 343-347. PubMed Europe PubMed DOI

2012

Buttle,D.J.
Caricain
[ISSN:978-0-12-407743-0]3, 1865-1867. DOI

2005

Liu,W., Ye,W., Wang,Z., Chao,H. and Lian,J.
Preparation and characterization of a truncated caricain lacking 41 residues from the N-terminal
Protein J24, 243-251. PubMed Europe PubMed DOI

2004

Buttle,D.J.
Caricain
[ISSN:0-12-079610-4]2, 1130-1132. V

2003

[YEAR:25-6-2003]Azarkan,M., El Moussaoui,A., van Wuytswinkel,D., Dehon,G. and Looze,Y.
Fractionation and purification of the enzymes stored in the latex of Carica papaya
J Chromatogr B Analyt Technol Biomed Life Sci790, 229-238. PubMed Europe PubMed DOI

1998

[YEAR:16-10-1998]Ikeuchi,Y., Katerelos,N.A. and Goodenough,P.W.
The enhancing of a cysteine proteinase activity at acidic pH by protein engineering, the role of glutamic 50 in the enzyme mechanism of caricain
FEBS Lett437, 91-96. PubMed Europe PubMed DOI

1996

Groves,M.R., Taylor,M.A., Scott,M., Cummings,N.J., Pickersgill,R.W. and Jenkins,J.A.
The prosequence of procaricain forms an alpha-helical domain that prevents access to the substrate-binding cleft
Structure4, 1193-1203. PubMed Europe PubMed
Katerelos,N.A., Taylor,M.A., Scott,M., Goodenough,P.W. and Pickersgill,R.W.
Crystal structure of a caricain D158E mutant in complex with E-64
FEBS Lett392, 35-39. PubMed Europe PubMed DOI S
Katerelos,N.A. and Goodenough,P.W.
Rapid kinetic studies and structural determination of a cysteine proteinase mutant imply that residue 158 in caricain has a major effect upon the ability of the active site histidine to protonate a dipyridyl probe
Biochemistry35, 14763-14772. PubMed Europe PubMed DOI

1994

Taylor,M.A., Baker,K.C., Connerton,I.F., Cummings,N.J., Harris,G.W., Henderson,I.M., Jones,S.T., Pickersgill,R.W., Sumner,I.G. and Warwicker,J.
An unequivocal example of cysteine proteinase activity affected by multiple electrostatic interactions
Protein Eng7, 1267-1276. PubMed Europe PubMed

1993

[YEAR:30-5-1993]Revell,D.F., Cummings,N.J., Baker,K.C., Collins,M.E., Taylor,M.A., Sumner,I.G., Pickersgill,R.W., Connerton,I.F. and Goodenough,P.W.
Nucleotide sequence and expression in Escherichia coli of cDNAs encoding papaya proteinase omega from Carica papaya
Gene127, 221-225. PubMed Europe PubMed DOI
Sumner,I.G., Vaughan,A., Eisenthal,R., Pickersgill,R.W., Owen,A.J. and Goodenough,P.W.
Kinetic analysis of papaya proteinase omega
Biochim Biophys Acta1164, 243-251. PubMed Europe PubMed DOI

1991

Pickersgill,R.W., Rizkallah,P., Harris,G.W. and Goodenough,P.W.
Determination of the structure of papaya protease omega
Acta Crystallogr B47, 766-771. S
Topham,C.M., Salih,E., Frazao,C., Kowlessur,D., Overington,J.P., Thomas,M., Brocklehurst,S.M., Patel,M., Thomas,E.W. and Brocklehurst,K.
Structure-function relationships in the cysteine proteinases actinidin, papain and papaya proteinase omega. Three-dimensional structure of papaya proteinase omega deduced by knowledge-based modelling and active-centre characteristics determined by two- hydronic-state reactivity probe kinetics and kinetics of catalysis
Biochem J280, 79-92. PubMed Europe PubMed S

1988

Dubois,T., Kleinschmidt,T., Schnek,A.G., Looze,Y. and Braunitzer,G.
The thiol proteinases from the latex of Carica papaya L. II. The primary structure of proteinase omega
Biol Chem Hoppe Seyler369, 741-754. PubMed Europe PubMed

1985

[YEAR:29-1-1985]Asboth,B., Stokum,E., Khan,I.U. and Polgar,L.
Mechanism of action of cysteine proteinases: oxyanion binding site is not essential in the hydrolysis of specific substrates
Biochemistry24, 606-609. PubMed Europe PubMed

1984

[YEAR:1-11-1984]Brocklehurst,K., Carey,P.R., Lee,H.H., Salih,E. and Storer,A.C.
Comparative resonance Raman spectroscopic and kinetic studies of acyl-enzymes involving papain, actinidin and papaya peptidase II
Biochem J223, 649-657. PubMed Europe PubMed
[YEAR:1-5-1984]Schack,P. and Kaarsholm,N.C.
Subsite differences between the active centres of papaya peptidase A and papain as revealed by affinity chromatography. Purification of papaya peptidase A by ionic-strength-dependent affinity adsorption on an immobilized peptide inhibitor of papain
Biochem J219, 727-733. PubMed Europe PubMed
Schack,P. and Kaarsholm,N.C.
Absence in papaya peptidase A catalyzed hydrolyses of a pKa Y^ª 4 present in papain-catalyzed hydrolyses
Biochemistry23, 631-635.

1983

Kaarsholm,N.C. and Schack,P.
Characterization of papaya peptidase A as an enzyme of extreme basicity
Acta Chem Scand B37, 607-611. PubMed Europe PubMed
Lynn,K.R.
Definition of the site of reactivity of the ancestral protease of the papain type
Phytochemistry22, 2485-2487. DOI P

1982

Baines,B.S. and Brocklehurst,K.
Isolation and characterization of the four major cysteine-proteinase components of the latex of Carica papaya L. Reactivity characteristics towards 2,2-dipyridyldisulfide of the thiol groups of papain, chymopapains A and B, and papaya peptidase A
J Protein Chem1, 119-139. DOI

1975

Robinson,G.W.
Isolation and characterization of papaya peptidase A from commercial chymopapain
Biochemistry14, 3695-3700. PubMed Europe PubMed

1968

Johansen,J.T. and Ottesen,M.
The proteolytic degradation of the B-chain of oxidized insulin by papain, chymopapain and papaya peptidase
C R Trav Lab Carlsberg36, 265-283. PubMed Europe PubMed