Plant cell factories in the post-genomic era: new ways to produce designer secondary metabolites.
about
Functional characterization of premnaspirodiene oxygenase, a cytochrome P450 catalyzing regio- and stereo-specific hydroxylations of diverse sesquiterpene substratesProcessing methods for differential analysis of LC/MS profile dataNext Generation Sequencing Technologies: The Doorway to the Unexplored Genomics of Non-Model PlantsBiotechnological approaches to enhance salidroside, rosin and its derivatives production in selected Rhodiola spp. in vitro culturesMulti-dimensional regulation of metabolic networks shaping plant development and performanceOrnamental exterior versus therapeutic interior of Madagascar periwinkle (Catharanthus roseus): the two faces of a versatile herbProtein structure modeling indicates hexahistidine-tag interference with enzyme activity.Plant metabolomics: from holistic hope, to hype, to hot topic.Imaging Matrix Assisted Laser Desorption Ionization Mass Spectrometry: a technique to map plant metabolites within tissues at high spatial resolution.Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry monitoring of anthocyanins in extracts from Arabidopsis thaliana leaves.Mass spectrometric analysis of differentially expressed proteins in an endangered medicinal herb, Picrorhiza kurroa.Fusarium inhibition by wild populations of the medicinal plant Salvia africana-lutea L. linked to metabolomic profiling.Triterpenoids from Gymnema sylvestre and their pharmacological activities.Nutritionally improved agricultural crops.Gene-to-metabolite networks for terpenoid indole alkaloid biosynthesis in Catharanthus roseus cells.Influence of ecological factors on the production of active substances in the anti-cancer plant Sinopodophyllum hexandrum (Royle) T.S. YingSecondary metabolites as DNA topoisomerase inhibitors: A new era towards designing of anticancer drugs.Connecting genes to metabolites by a systems biology approach.Metabolomic data suggest regulation of black howler monkey (Alouatta pigra) diet composition at the molecular level.Chemical Elicitor-Induced Modulation of Antioxidant Metabolism and Enhancement of Secondary Metabolite Accumulation in Cell Suspension Cultures of Scrophularia kakudensis Franch.Metabolic engineering of plant L-ascorbic acid biosynthesis: recent trends and applications.Metabolomic technologies and their application to the study of plants and plant-host interactions.Application of metabolic engineering to the production of scopolamine.Combinatorial biosynthesis in plants: a (p)review on its potential and future exploitation.Strategies to enhance biologically active-secondary metabolites in cell cultures of Artemisia - current trends.Biotechnology of the medicinal plant Rhazya stricta: a little investigated member of the Apocynaceae family.Inhibition of In Vivo Growth of Plasmodium berghei by Launaea taraxacifolia and Amaranthus viridis in Mice.Function Analysis of Caffeoyl-CoA O-Methyltransferase for Biosynthesis of Lignin and Phenolic Acid in Salvia miltiorrhiza.Protein and metabolite analysis reveals permanent induction of stress defense and cell regeneration processes in a tobacco cell suspension culture.Gene introduction into the mitochondria of Arabidopsis thaliana via peptide-based carriers.An UPLC-ESI-MS/MS Assay Using 6-Aminoquinolyl-N-Hydroxysuccinimidyl Carbamate Derivatization for Targeted Amino Acid Analysis: Application to Screening of Arabidopsis thaliana Mutants.Establishment and characterization of a Satureja khuzistanica Jamzad (Lamiaceae) cell suspension culture: a new in vitro source of rosmarinic acid.Time-series integrated "omic" analyses to elucidate short-term stress-induced responses in plant liquid cultures.Bioconversion of stilbenes in genetically engineered root and cell cultures of tobaccoProduction of the anti-inflammatory compound 6-O-palmitoyl-3-O-β-D-glucopyranosylcampesterol by Callus cultures of Lopezia racemosa Cav. (Onagraceae).Molecular cloning and characterization of Crmdr1, a novel MDR-type ABC transporter gene from Catharanthus roseus.CYP716A179 functions as a triterpene C-28 oxidase in tissue-cultured stolons of Glycyrrhiza uralensis.Botanicals in Ribes nigrum bud-preparations: an analytical fingerprinting to evaluate the bioactive contribution to total phytocomplex.Metabolic Pathway Assignment of Plant Genes based on Phylogenetic Profiling-A Feasibility Study.Lysine decarboxylase catalyzes the first step of quinolizidine alkaloid biosynthesis and coevolved with alkaloid production in leguminosae.
P2860
Q24646983-163C0E1F-A5DD-47D1-961C-55FE05E7D21CQ24813623-ABB1B262-504E-49FD-A12C-4C1B0BC32687Q26770658-BF89844B-0627-40B1-B627-88B4731951AAQ26799408-D44072DF-F7DC-48DD-8E2A-82D20FB77348Q27012683-F0FA7F71-635D-44E5-BC7D-616426CF8F87Q28085249-07C6CE51-D0CB-4463-9C2C-26BF67E1D15DQ30319684-1AEB04AB-AD62-4FE1-8FFA-79D5C90A4D7FQ33231588-01684A75-CC11-4603-A30C-ACA5179776BCQ33258650-B5A36142-2AC1-4425-BBC9-D1D9BD87D01FQ33382217-A8C32CB0-9DA0-4111-BA1A-47482DC0D838Q33625343-37D0A107-F129-4AC4-B84E-2619280FF508Q33913954-2744097F-11BB-49AB-83FA-4B0DBD517F90Q34431343-B1531CEB-0AA7-4C53-A84D-F0C86617FA99Q34593952-A39CA5D4-42D4-44E4-A15F-526A40D17F60Q34600470-BFDFBF0C-882C-40B0-A0BB-0D8773444378Q35433382-0D4DA088-99FC-4BA3-89B8-FAD0B293ADAFQ35646690-5E2938DE-DCC5-468C-88BA-D00899E90C55Q35972159-B25F4608-46E8-443A-B86D-85F60ADCF5A1Q36218829-FA4D8030-F0E1-48F6-8037-16CDBD83ED6BQ36743771-D1A601C5-A95F-4615-A63F-691CA68082C6Q36937984-E24A9ED1-B149-4E60-9E4C-BAF80058E1C4Q37077716-B0FCC5A1-CA30-4C01-BF08-8228EE6BE3CCQ37270375-254CA106-3406-4409-ABED-FA587726FD89Q37939609-13E6104E-7575-459A-BE23-C32D480A00CAQ39066071-43F09C2E-6BC0-436A-BB52-876360EEB9B2Q39181310-E0C0FF18-B350-45F8-9B60-95CFE49980ACQ39262545-FEA64FD1-D7BC-4E21-9291-05CD319909F5Q39404995-EE864DC7-C625-4B38-8777-A8A9779971D8Q39801318-29FA0292-AE97-4C1E-B6BE-52D01F9F9BDDQ41590508-DB2AE56D-DCBD-4287-BDED-F7A5FDA8C034Q41780042-20F5A232-5433-4846-9A5A-513653C4BE04Q41944206-2CD18014-FB70-41FC-A39A-E9E664280FCEQ42141039-424E046A-E46F-4AC1-93FE-E92C85C5C9E1Q42314241-75899B5B-1DEB-46E0-B381-C4AEDAAF9BEAQ42461201-FE00A396-9211-4ACB-A5E8-FD2221B08D61Q42622519-06DB5B0C-2AEC-4BA4-B6D4-2ED22C54FC6EQ42775257-44B72187-0F33-4D86-AE01-B5B8CC3B04ACQ44973622-6D0200B9-457B-44D3-8ED5-94C1627144EBQ45943697-DCF7F0E2-1A18-4C30-8628-0AEFB61C9675Q46293533-06A01218-3D29-43EE-8E4A-26605598A526
P2860
Plant cell factories in the post-genomic era: new ways to produce designer secondary metabolites.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年学术文章
@wuu
2004年学术文章
@zh-cn
2004年学术文章
@zh-hans
2004年学术文章
@zh-my
2004年学术文章
@zh-sg
2004年學術文章
@yue
2004年學術文章
@zh
2004年學術文章
@zh-hant
name
Plant cell factories in the po ...... esigner secondary metabolites.
@ast
Plant cell factories in the po ...... esigner secondary metabolites.
@en
type
label
Plant cell factories in the po ...... esigner secondary metabolites.
@ast
Plant cell factories in the po ...... esigner secondary metabolites.
@en
prefLabel
Plant cell factories in the po ...... esigner secondary metabolites.
@ast
Plant cell factories in the po ...... esigner secondary metabolites.
@en
P1476
Plant cell factories in the po ...... esigner secondary metabolites.
@en
P304
P356
10.1016/J.TPLANTS.2004.07.006
P577
2004-09-01T00:00:00Z