BIOMAT Database Logo BIOMAT Database Logo

Autoproteolytic processing of aspartic proteinase from sunflower seeds. 2001

H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Institute of Applied Biochemistry, University of Tsukuba, Ibaraki, Japan.

The autoproteolytic processing of mature aspartic proteinase from sunflower seeds was investigated. The mature aspartic proteinase (48 kDa) was processed at N65s-D66s in the plant-specific region of the enzyme to form 34-kDa and 14-kDa subunits. The next step was the hydrolysis of the A25s-Q26s and N97s-E98s bonds to form a 39-kDa enzyme that consisted of 29-kDa and 9-kDa disulfide-bonded subunits. Finally, bonds including V1s-M2s, M2s-S3s, C100s-D101s, and D101s-R102s were cleaved to form non-covalently bound subunits (29 kDa and 9 kDa) by eliminating the disulfide bonds in the plant-specific region of the protein.

UI MeSH Term Description Entries
D008969 Molecular Sequence Data Descriptions of specific amino acid, carbohydrate, or nucleotide sequences which have appeared in the published literature and/or are deposited in and maintained by databanks such as GENBANK, European Molecular Biology Laboratory (EMBL), National Biomedical Research Foundation (NBRF), or other sequence repositories. Sequence Data, Molecular,Molecular Sequencing Data,Data, Molecular Sequence,Data, Molecular Sequencing,Sequencing Data, Molecular
D011499 Protein Processing, Post-Translational Any of various enzymatically catalyzed post-translational modifications of PEPTIDES or PROTEINS in the cell of origin. These modifications include carboxylation; HYDROXYLATION; ACETYLATION; PHOSPHORYLATION; METHYLATION; GLYCOSYLATION; ubiquitination; oxidation; proteolysis; and crosslinking and result in changes in molecular weight and electrophoretic motility. Amino Acid Modification, Post-Translational,Post-Translational Modification,Post-Translational Protein Modification,Posttranslational Modification,Protein Modification, Post-Translational,Amino Acid Modification, Posttranslational,Post-Translational Amino Acid Modification,Post-Translational Modifications,Post-Translational Protein Processing,Posttranslational Amino Acid Modification,Posttranslational Modifications,Posttranslational Protein Processing,Protein Processing, Post Translational,Protein Processing, Posttranslational,Amino Acid Modification, Post Translational,Modification, Post-Translational,Modification, Post-Translational Protein,Modification, Posttranslational,Modifications, Post-Translational,Modifications, Post-Translational Protein,Modifications, Posttranslational,Post Translational Amino Acid Modification,Post Translational Modification,Post Translational Modifications,Post Translational Protein Modification,Post Translational Protein Processing,Post-Translational Protein Modifications,Processing, Post-Translational Protein,Processing, Posttranslational Protein,Protein Modification, Post Translational,Protein Modifications, Post-Translational
D002403 Cathepsins A group of lysosomal proteinases or endopeptidases found in aqueous extracts of a variety of animal tissues. They function optimally within an acidic pH range. The cathepsins occur as a variety of enzyme subtypes including SERINE PROTEASES; ASPARTIC PROTEINASES; and CYSTEINE PROTEASES. Cathepsin
D006368 Helianthus A genus herbs of the Asteraceae family. The SEEDS yield oil and are used as food and animal feed; the roots of Helianthus tuberosum (Jerusalem artichoke) are edible. Jerusalem Artichoke,Sunflower,Helianthus annuus,Helianthus tuberosus,Artichoke, Jerusalem,Sunflowers
D000595 Amino Acid Sequence The order of amino acids as they occur in a polypeptide chain. This is referred to as the primary structure of proteins. It is of fundamental importance in determining PROTEIN CONFORMATION. Protein Structure, Primary,Amino Acid Sequences,Sequence, Amino Acid,Sequences, Amino Acid,Primary Protein Structure,Primary Protein Structures,Protein Structures, Primary,Structure, Primary Protein,Structures, Primary Protein
D012639 Seeds The encapsulated embryos of flowering plants. They are used as is or for animal feed because of the high content of concentrated nutrients like starches, proteins, and fats. Rapeseed, cottonseed, and sunflower seed are also produced for the oils (fats) they yield. Diaspores,Elaiosomes,Embryos, Plant,Plant Embryos,Plant Zygotes,Zygotes, Plant,Diaspore,Elaiosome,Embryo, Plant,Plant Embryo,Plant Zygote,Seed,Zygote, Plant
D016282 Aspartic Acid Endopeptidases A sub-subclass of endopeptidases that depend on an ASPARTIC ACID residue for their activity. Aspartic Endopeptidases,Aspartyl Endopeptidases,Acid Endopeptidases, Aspartic,Endopeptidases, Aspartic Acid,Endopeptidases, Aspartyl
D017434 Protein Structure, Tertiary The level of protein structure in which combinations of secondary protein structures (ALPHA HELICES; BETA SHEETS; loop regions, and AMINO ACID MOTIFS) pack together to form folded shapes. Disulfide bridges between cysteines in two different parts of the polypeptide chain along with other interactions between the chains play a role in the formation and stabilization of tertiary structure. Tertiary Protein Structure,Protein Structures, Tertiary,Tertiary Protein Structures

Related Publications

H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Purification, cloning and autoproteolytic processing of an aspartic proteinase from Centaurea calcitrapa.
December 2000, European journal of biochemistry,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Aspartic proteinase from the seeds of figleaf gourd (Cucurbita ficifolia)*.
January 1994, Acta biochimica Polonica,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Aspartic proteinase from barley seeds is related to animal cathepsin D.
January 1991, Advances in experimental medicine and biology,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Aspartic proteinase from wheat seeds: isolation, properties and action on gliadin.
March 1989, Planta,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
High-resolution structure of a potent, cyclic proteinase inhibitor from sunflower seeds.
July 1999, Journal of molecular biology,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Efficient autoproteolytic processing of the MHV-A59 3C-like proteinase from the flanking hydrophobic domains requires membranes.
April 1997, Virology,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Contact urticaria from sunflower seeds.
October 1997, Contact dermatitis,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Rectal bezoar from sunflower seeds.
August 1988, Annals of emergency medicine,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Characterization of an aspartic proteinase activity in buckwheat (Fagopyrum esculentum Moench) seeds.
March 2003, Journal of agricultural and food chemistry,
H Park, and I Kusakabe, and Y Sakakibara, and H Kobayashi
Molecular cloning, functional expression, and mutagenesis of cDNA encoding a cysteine proteinase inhibitor from sunflower seeds.
November 1998, Journal of biochemistry,
Copied contents to your clipboard!