Quantification of the importance of individual steps in the control of aromatic amino acid metabolism. - Wikidata - awgldk - TriplyDB

Quantification of the importance of individual steps in the control of aromatic amino acid metabolism.

Quantification of the importance of individual steps in the control of aromatic amino acid metabolism.

http://www.wikidata.org/entity/Q42503579

about

The physiological action of picolinic Acid in the human brain Understanding the role of the kynurenine pathway in human breast cancer immunobiology Model of tryptophan metabolism, readily scalable using tissue-specific gene expression data.Metabolomic Profiling of Soybeans (Glycine max L.) Reveals the Importance of Sugar and Nitrogen Metabolism under Drought and Heat Stress Metabolic flux and fitness.Evolution of a single gene highlights the complexity underlying molecular descriptions of fitness.Why is uncompetitive inhibition so rare? A possible explanation, with implications for the design of drugs and pesticides.Linking genotypes database with locus-specific database and genotype-phenotype correlation in phenylketonuria Metabolic control analysis: a survey of its theoretical and experimental development The PAH gene, phenylketonuria, and a paradigm shift.What we know that could influence future treatment of phenylketonuria.Kynurenine metabolism in health and disease.Enzyme-enzyme interactions and control analysis. 1. The case of non-additivity: monomer-oligomer associations.The salience of Garrod's 'molecular groupings' and 'Inborn Factors in Disease'.Unraveling Key Metabolomic Alterations in Wheat Embryos Derived from Freshly Harvested and Water-Imbibed Seeds of Two Wheat Cultivars with Contrasting Dormancy Status.Hepatocytes from wild-type or heterozygous donors are equally effective in achieving successful therapeutic liver repopulation in murine phenylketonuria (PKU).Human phenylalanine hydroxylase mutations and hyperphenylalaninemia phenotypes: a metanalysis of genotype-phenotype correlations.The role of haem in the regulation of rat liver tryptophan metabolism Switch between life history strategies due to changes in glycolytic enzyme gene dosage in Saccharomyces cerevisiae.Determination of Flux Control Coefficients from transient metabolite concentrations.A strategy for increasing an in vivo flux by genetic manipulations. The tryptophan system of yeast.How does displacement of albumin-bound tryptophan cause sustained increases in the free tryptophan concentration in plasma and 5-hydroxytryptamine synthesis in brain?A quantitative analysis of the control of glutamine catabolism in rat liver cells. Use of selective inhibitors.Determination of control coefficients in intact metabolic systems.Study of the flux and transition time control coefficient profiles in a metabolic system in vitro and the effect of an external stimulator.Nonflowering plants possess a unique folate-dependent phenylalanine hydroxylase that is localized in chloroplasts.The characteristics and site of inhibition of gluconeogenesis in rat liver cells by bacterial endotoxin. Stimulation of phosphofructokinase-1.The derivation and interpretation of control coefficients.Control analysis provides a simple means of understanding the control structure of a metabolic pathway.Tryptophan metabolism in vitamin B6-deficient mice.In vivo disposal of phenylalanine in phenylketonuria: a study of two siblings.Blood-brain barrier phenylalanine transport and individual vulnerability in phenylketonuria.The control of 5-hydroxytryptamine and dopamine synthesis in the brain: a theoretical approach.Application of biochemical systems theory to metabolism in human red blood cells. Signal propagation and accuracy of representation.Responses of metabolic systems to large changes in enzyme activities and effectors. 1. The linear treatment of unbranched chains.Metabolic control and its analysis. Extensions to the theory and matrix method.

P2860

Q24634995-999805C4-8217-43BD-A5B4-D91BC4126C91 Q26773472-BF398323-CA5D-45BA-B61B-FC0350F4C5C8 Q30678210-0CAEC384-6E01-4909-96F7-3F99CFEEC77E Q33850103-01A1515C-BCCA-4F11-84E2-E79760F863DC Q33952746-15FFADC3-047C-4412-A438-723E9C5ECB4E Q34017244-48C06B09-1D84-4580-B202-5FE16460DED0 Q34050556-9ECD95A1-F882-473C-8E77-6ED05F13585B Q35079956-7BE69D8C-0476-4ACC-BBC4-87C64E0CC59E Q35860764-1B920354-AB3B-4E81-8F1B-EF0DF0A8B150 Q36795399-5EC314BA-70B9-47FD-893A-58FC3D292B3A Q37231019-F6B59ABE-39A2-4178-98C5-51BAE7D06435 Q37802769-DB874151-D0F2-4DED-8BEA-37DFB1907BDD Q38141742-D66B3FC8-2570-4767-9381-414F89C63DFF Q38237414-D8C9882B-4715-4D65-8A1A-5C96FD01AB19 Q38658899-EFDA05AE-1008-4E7B-955E-CA312FC5EFAD Q39190570-234C99C0-E315-4701-9219-91F2F4C38D1F Q41889461-8B416F36-0485-424E-97AD-FB15851312BA Q42134835-F893AAC3-4485-4D31-A0E8-B6BCD7A52A19 Q42170421-77AFFB2C-A41C-4EFD-8518-0267B3191332 Q42793171-4E6B1E58-2661-4403-A3EB-50E63B13934A Q42801770-AACADFB0-348F-4412-8AE8-793B0184BB71 Q42802502-6E398EB9-527D-47DB-9A23-DC60C4D05C17 Q42815692-58F730D7-C665-4192-8B63-16DEEE0E6447 Q42833274-0A353C5C-3878-43FE-89BF-6216853B74BB Q42836427-4CBC2812-902F-4DC3-AEA2-C0E728700556 Q42853992-959057F3-30E6-4256-B5E1-97096AF95925 Q42855617-06F657F9-EE29-4FDB-9C2E-21A7F513B021 Q42856884-5AE32941-48FD-4973-BD7F-ED6ED2C7F9FE Q42858742-0B649A56-E372-4CED-905D-95A713AFA6E7 Q43578101-A7C2D6E5-DC8A-4643-9792-51CD1B4CE8A8 Q45345330-AD7469CC-3886-4A51-BE17-86545AB06D1D Q48354208-81B1CB47-ED91-41F3-9B98-D8C4B8EE59EB Q52061090-194F46E5-77A0-4C69-B39D-CD15D6DFCFC0 Q52306845-A0253D01-F404-4201-AA98-B6CDCA9533E6 Q52398104-CB65DAE5-2FBF-40E1-AFF4-3BBFD41E9334 Q52428120-7916B94E-DE01-40F8-8FC6-C3D3945A7ECF

P2860

Quantification of the importance of individual steps in the control of aromatic amino acid metabolism.

http://www.wikidata.org/entity/Q42503579

description

1986 nî lūn-bûn

@nan

1986年の論文

@ja

1986年学术文章

@wuu

1986年学术文章

@zh-cn

1986年学术文章

@zh-hans

1986年学术文章

@zh-my

1986年学术文章

@zh-sg

1986年學術文章

@yue

1986年學術文章

@zh

1986年學術文章

@zh-hant

name

Quantification of the importan ...... romatic amino acid metabolism.

@en

Quantification of the importan ...... romatic amino acid metabolism.

@nl

type

label

Quantification of the importan ...... romatic amino acid metabolism.

@en

Quantification of the importan ...... romatic amino acid metabolism.

@nl

prefLabel

Quantification of the importan ...... romatic amino acid metabolism.

@en

Quantification of the importan ...... romatic amino acid metabolism.

@nl

P1433

Q42503579-3E3CF826-B93B-44F0-BD58-FAAF3B1A1BAC

P1476

Q42503579-B245C398-3C69-40D6-8DA7-DC3C203ED87D

P2093

Q42503579-47FF1010-DDBA-4095-A77C-84E3F5C12012

Q42503579-6D0657E5-09D0-4173-A28F-1842796C0EBB

Q42503579-A13E7DEA-9C0D-4E25-B5C5-E26E86C0697C

P2860

Q42503579-01AD3BB9-CB78-4DE6-B350-C32B6E99BEC1

Q42503579-04396EE2-1003-4FCE-974A-B8830FC70F74

Q42503579-0E6D839B-3625-458F-8726-743458AF7CC6

Q42503579-0F11EC21-852A-42C1-83BF-27A4D2E7E0A4

Q42503579-115492D7-8B3F-44FC-8238-EB14B0F272D1

Q42503579-136BBF5D-954D-4EA6-A300-E2D5BF460208

Q42503579-14CB95A8-C5C0-475D-AC7D-4379A3DE228E

Q42503579-190DFC5E-9A5C-456A-A98D-89867679D328

Q42503579-26194CEC-F49A-4A3C-B58A-2E71BF27ECC2

Q42503579-28BD93C8-AF40-4A4F-B6E9-727E8A233AC6

P304

Q42503579-108F6551-CFA6-43AC-B19C-D5F2D6EF3FCC

P31

Q42503579-DDAB3B51-26CC-42EE-8F67-97565DC0C838

P356

Q42503579-CDBDF898-5CD7-4EB7-8699-959054B4629B

P407

Q42503579-CBB4312C-74F0-4156-8EBE-DCB2C953B585

P433

Q42503579-6771A236-4268-47D8-BBDD-EA632777C4FD

P478

Q42503579-4FA23466-F64C-4257-A489-2CE812314B16

P577

Q42503579-52576BD8-481C-471E-A38B-8C3C8F6276B8

P5875

Q42503579-CBF52A5B-4322-449B-B73A-BBA427B24A83

P698

Q42503579-987C3B3C-AD50-43D2-BBE9-0BE6D406A5C8

P932

Q42503579-25E5DCBD-601F-45E5-B6B9-DCD2A608468E

P356

P1433

Biochemical Journal

P1476

Quantification of the importan ...... romatic amino acid metabolism.

@en

P2093

Knowles RG

http://www.w3.org/2001/XMLSchema#string

Pogson CI

http://www.w3.org/2001/XMLSchema#string

Salter M

http://www.w3.org/2001/XMLSchema#string

P2860

Modern theories of metabolic control and their applications

The control of flux

A linear steady-state treatment of enzymatic chains. General properties, control and effector strength

Studies on the phenylalanine hydroxylase system in vivo. An in vivo assay based on the liberation of deuterium or tritium into the body water from ring-labeled L-phenylalanine

In vitro activation of rat liver phenylalanine hydroxylase by phosphorylation

The role of tryptophan 2,3-dioxygenase in the hormonal control of tryptophan metabolism in isolated rat liver cells. Effects of glucocorticoids and experimental diabetes

The metabolism of L-tryptophan by isolated rat liver cells. Quantification of the relative importance of, and the effect of nutritional status on, the individual pathways of tryptophan metabolism

Brain catechol synthesis: control by train tyrosine concentration.

Resolution of DL-tryptophan by affinity chromatography on bovine-serum albumin-agarose columns

Control of the mRNA for hepatic tryptophan oxygenase during hormonal and substrate induction.

P304

635-647

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1042/BJ2340635

http://www.w3.org/2001/XMLSchema#string

P407

P433

3

http://www.w3.org/2001/XMLSchema#string

P478

234

http://www.w3.org/2001/XMLSchema#string

P577

1986-03-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

20283142

http://www.w3.org/2001/XMLSchema#string

P698

2872885

http://www.w3.org/2001/XMLSchema#string

P932

1146619

http://www.w3.org/2001/XMLSchema#string