about
Identification of a biosynthetic gene cluster in rice for momilactones.Diterpene phytoalexins are biosynthesized in and exuded from the roots of rice seedlings.Regulation of a proteinaceous elicitor-induced Ca2+ influx and production of phytoalexins by a putative voltage-gated cation channel, OsTPC1, in cultured rice cells.OsTGAP1, a bZIP transcription factor, coordinately regulates the inductive production of diterpenoid phytoalexins in rice.Identification of UV-Induced Diterpenes Including a New Diterpene Phytoalexin, Phytocassane F, from Rice Leaves by Complementary GC/MS and LC/MS Approaches.Alternative splicing produces two endoglucanases with one or two carbohydrate-binding modules in Mucor circinelloides.Comparison of different sources and degrees of hydrolysis of dietary protein: effect on plasma amino acids, dipeptides, and insulin responses in human subjects.Short-chain fructooligosaccharide regulates hepatic peroxisome proliferator-activated receptor alpha and farnesoid X receptor target gene expression in rats.Effects of a bile acid elicitor, cholic acid, on the biosynthesis of diterpenoid phytoalexins in suspension-cultured rice cells.Post-exercise carbohydrate plus whey protein hydrolysates supplementation increases skeletal muscle glycogen level in rats.Branched-chain amino acid-containing dipeptides, identified from whey protein hydrolysates, stimulate glucose uptake rate in L6 myotubes and isolated skeletal muscles.Cloning and characterization of cDNAs encoding ent-copalyl diphosphate synthases in wheat: insight into the evolution of rice phytoalexin biosynthetic genes.Collagen hydrolysate intake improves the loss of epidermal barrier function and skin elasticity induced by UVB irradiation in hairless mice.Elicitor induced activation of the methylerythritol phosphate pathway toward phytoalexins biosynthesis in rice.Cerebrosides A and C, sphingolipid elicitors of hypersensitive cell death and phytoalexin accumulation in rice plants.Cacao polyphenols influence the regulation of apolipoprotein in HepG2 and Caco2 cells.Post-exercise whey protein hydrolysate supplementation induces a greater increase in muscle protein synthesis than its constituent amino acid content.Amino acid regions of family 45 endoglucanases involved in cotton defibrillation and in resistance to anionic surfactants and oxidizing agentsIdentification of marker genes for intestinal immunomodulating effect of a fructooligosaccharide by DNA microarray analysisExploring amino acids responsible for the temperature profile of glycoside hydrolase family 45 endoglucanase EGL3 from Humicola griseaPreexercise ingestion of carbohydrate plus whey protein hydrolysates attenuates skeletal muscle glycogen depletion during exercise in ratsSpecific characteristics of family 45 endoglucanases from Mucorales in the use of textiles and laundryComparison of fructooligosaccharide utilization by Lactobacillus and Bacteroides speciesDifferential responses of rice to inoculation with wild-type and non-pathogenic mutants of Magnaporthe oryzaeFructooligosaccharides suppress high-fat diet-induced fat accumulation in C57BL/6J micePhytoalexin accumulation in the interaction between rice and the blast fungusA new glycosylated dihydrophaseic acid from cacao germs (Theobroma cacao L.).The effect of high-intensity intermittent swimming on post-exercise glycogen supercompensation in rat skeletal muscleDietary whey protein hydrolysates increase skeletal muscle glycogen levels via activation of glycogen synthase in miceDifferential effects of black currant anthocyanins on diffuser- or negative lens-induced ocular elongation in chicks
P50
Q34688080-00F31896-B811-4CB0-BC41-7940ED85AF42Q34747178-0DA7818F-203D-4A87-9656-497A6AE67C83Q35879911-80700BDC-60A4-4961-9036-21AEA6B522BEQ37446698-2D911B95-402E-445B-BA3F-B4F84E91B4FCQ41341798-BB319018-23AF-4069-ABDA-CBDC03B948BBQ42723124-410921DF-F4E4-48FE-8B5A-7530F17F8FADQ42976228-2E9C83BD-383F-46DB-8BE8-4D32183A2B88Q43064879-CADFBEF1-5A6A-408B-AE4C-D3341BB9AEC9Q43527737-6C608D64-9A2A-4845-A89B-48C936850712Q45931882-FC36EC54-58B6-4725-8F63-D795C514342AQ46058027-13F7D812-8F9F-4062-A5BB-E9BDCECB839BQ46095620-4967B241-D210-4B68-8125-A6EA55990F78Q50866691-430FD1F6-CB3C-4C1D-AF42-9B82250F1531Q52580493-B070824F-6B69-4CD5-ABE9-816561D82C75Q54116073-7E2CA329-73FB-42E0-A023-17BE640EDD46Q54393072-CE43387D-F739-4C4C-B48A-DFD5E9144E73Q54451464-A6267F58-42D4-4D49-A84C-B8E2AACDEAFAQ79216374-5C58419F-EC2D-4A94-8A3A-9004FBEA62BAQ80014582-B84E8865-767B-49AD-81B5-791DB637DFF0Q80230191-9832FDF3-DF2F-4231-BF1A-DD6466B25BEDQ82310804-231CF4A0-A7F5-43C3-B1C0-22EADE779B32Q83196436-4D1A028E-0E38-48EC-A291-3CB2AB44A473Q83201498-B6EA3D2D-5DF7-4C12-BCB8-3C989F19115BQ83775408-311A5005-7362-49FF-8788-606B122CF9B6Q84365672-05DEA172-1043-40C4-A95F-7914471BAD73Q84546537-51DF94B9-C162-4F8C-A631-450488FC6195Q84708105-CA7531A9-3298-4A7D-BB86-030A0D513DE8Q85065830-8A0FF3B9-C191-47C6-8598-B67035359663Q85324304-76D3551E-520E-41CE-8DE2-CF5EF97EACF4Q86129388-C5254555-5A29-4C65-A07C-2AA2E8FB9DBC
P50
description
researcher
@en
wetenschapper
@nl
name
J Koga
@en
J Koga
@nl
type
label
J Koga
@en
J Koga
@nl
prefLabel
J Koga
@en
J Koga
@nl
P106
P31
P496
0000-0003-2106-9894