about
Patterns of CRISPR/Cas9 activity in plants, animals and microbesThe contribution of transgenic plants to better health through improved nutrition: opportunities and constraintsModulation of the polyamine biosynthetic pathway in transgenic rice confers tolerance to drought stress.Transgenic multivitamin corn through biofortification of endosperm with three vitamins representing three distinct metabolic pathways.Promoter diversity in multigene transformation.Biofortification of plants with altered antioxidant content and composition: genetic engineering strategies.Engineering metabolic pathways in plants by multigene transformation.Molecular characterization of the Arginine decarboxylase gene family in rice.Spermine facilitates recovery from drought but does not confer drought tolerance in transgenic rice plants expressing Datura stramonium S-adenosylmethionine decarboxylase.The potential impact of plant biotechnology on the Millennium Development Goals.Transcriptional regulation of the rice arginine decarboxylase (Adc1) and S-adenosylmethionine decarboxylase (Samdc) genes by methyl jasmonate.Over-expression of a cDNA for human ornithine decarboxylase in transgenic rice plants alters the polyamine pool in a tissue-specific manner.Ascorbic acid synthesis and metabolism in maize are subject to complex and genotype-dependent feedback regulation during endosperm development.Expression of a heterologous S-adenosylmethionine decarboxylase cDNA in plants demonstrates that changes in S-adenosyl-L-methionine decarboxylase activity determine levels of the higher polyamines spermidine and spermine.Reduction in the endogenous arginine decarboxylase transcript levels in rice leads to depletion of the putrescine and spermidine pools with no concomitant changes in the expression of downstream genes in the polyamine biosynthetic pathway.Can the world afford to ignore biotechnology solutions that address food insecurity?Transgenic rice as a vehicle for the production of the industrial enzyme transglutaminase.Promoter strength influences polyamine metabolism and morphogenic capacity in transgenic rice tissues expressing the oat adc cDNA constitutively.Endogenous enzyme activities and polyamine levels in diverse rice cultivars depend on the genetic background and are not affected by the presence of the hygromycin phosphotransferase selectable marker.Transgenic wheat plants expressing an oat arginine decarboxylase cDNA exhibit increases in polyamine content in vegetative tissue and seedsDevelopment of a novel gene transfer system for Cajanus cajan and expression of a monocot arginine decarboxylase cDNA in transformed cell linesA transgenic rice cell lineage expressing the oat arginine decarboxylase (adc) cDNA constitutively accumulates putrescine in callus and seeds but not in vegetative tissuesTransgenic cell lines as a useful tool to study the biochemistry of down-regulation of an endogenous rice gene using a heterologous diamine-oxidase cDNACRISPR/Cas9-induced monoallelic mutations in the cytosolic AGPase large subunit gene APL2 induce the ectopic expression of APL2 and the corresponding small subunit gene APS2b in rice leavesZmPBF and ZmGAMYB transcription factors independently transactivate the promoter of the maize (Zea mays) β-carotene hydroxylase 2 gene
P50
Q28078150-5B33299A-DB06-41ED-942E-BE537D442B5DQ28710129-162ECF48-65D5-42CD-9856-9A5F9DFF8831Q36449429-69DF43D8-1F6F-4BF7-BA0D-3B2C2C38061BQ37194857-5B022924-4BBB-49EC-A01B-836D6B49437BQ37721866-D959AC9E-296E-40F0-B78A-5B593ADA8193Q38042689-7D486BD1-EB7F-4A30-85F3-05B6E39BC816Q38156086-42AECB1F-3D33-4B6D-B263-74590B7E3A99Q39349742-B90CE5A0-B8EB-4FE4-B411-587CDF72306BQ39349748-164A27BA-E571-4BD1-85F4-4F1625FAC631Q39792117-DECF8038-1CAD-4F5D-87DE-75A68B429995Q43161496-59C2B965-6CE1-433D-8439-047EC55E7CE4Q43781889-2CF25700-F746-4AD1-983F-4E3FB4F47E54Q43879393-D067BBB1-BB5B-44ED-85D2-60D899B58EF7Q44102655-D1EF7BA2-EE45-48F3-9F0A-09DC5AE382BEQ44536529-CA72CAD2-355A-4D0E-92CC-98E10EBAE6D9Q46052180-5AA92C9B-270D-4F9F-A5E8-A4F4B5B0A349Q47340568-99B1ED8F-E9D4-4B29-A9AA-010198E044DFQ52167651-1703D9E6-BFC4-4A36-B5F7-F740C74A289CQ53658918-54326076-2AFE-455A-B4B0-89CC89075873Q57522995-08A76A06-2B64-4CD1-9592-FC94893C644AQ57523136-6D4CB019-FCB1-4BB2-8947-F50341BB6DD5Q57523183-EAF08B98-3FDF-4BB1-A8CB-D7F54855051FQ57523220-B6AFAE1B-5269-4260-A714-8303682CE1F2Q90900797-9CF1EECA-AFD6-4A18-81F6-5A3A59ECDE77Q93390899-B3C1F022-9B86-43D1-AAAB-7ADF2EA7259A
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Ludovic Bassie
@ast
Ludovic Bassie
@en
Ludovic Bassie
@es
Ludovic Bassie
@nl
Ludovic Bassie
@sl
type
label
Ludovic Bassie
@ast
Ludovic Bassie
@en
Ludovic Bassie
@es
Ludovic Bassie
@nl
Ludovic Bassie
@sl
altLabel
Ludovic Bassié
@en
prefLabel
Ludovic Bassie
@ast
Ludovic Bassie
@en
Ludovic Bassie
@es
Ludovic Bassie
@nl
Ludovic Bassie
@sl
P106
P1153
6603262187
P21
P31
P496
0000-0002-4791-0963