The metabolic basis of whole-organism RNA and phosphorus content - Wikidata - awgldk - TriplyDB

The metabolic basis of whole-organism RNA and phosphorus content

The metabolic basis of whole-organism RNA and phosphorus content

http://www.wikidata.org/entity/Q33920196

about

Kinetic effects of temperature on rates of genetic divergence and speciation Scaling of number, size, and metabolic rate of cells with body size in mammals Interactions between temperature and nutrients across levels of ecological organization.Stoichiometry and the new biology: the future is now.Biological stoichiometry in human cancer.Energetic basis of colonial living in social insects.Free mRNA in excess upon polysome dissociation is a scaffold for protein multimerization to form stress granules.Influence of cell size and DNA content on growth rate and photosystem II function in cryptic species of Ditylum brightwellii.Carbon use efficiency of microbial communities: stoichiometry, methodology and modelling.Initial amino acid intake influences phosphorus and calcium homeostasis in preterm infants--it is time to change the composition of the early parenteral nutrition.Individuals scale up carbon flow in ecosystems.Unifying elemental stoichiometry and metabolic theory in predicting species abundances.Metabolic theory and taxonomic identity predict nutrient recycling in a diverse food web.Biogeochemistry drives diversity in the prokaryotes, fungi, and invertebrates of a Panama forest.Can resource costs of polyploidy provide an advantage to sex?Energetic constraints on an early developmental stage: a comparative view.Dynamic relationships between microbial biomass, respiration, inorganic nutrients and enzyme activities: informing enzyme-based decomposition models.Temperature-size relations from the cellular-genomic perspective.Mitochondria and the non-genetic origins of cell-to-cell variability: More is different.Consumer-driven nutrient dynamics in freshwater ecosystems: from individuals to ecosystems.Single Cell Analysis Linking Ribosomal (r)DNA and rRNA Copy Numbers to Cell Size and Growth Rate Provides Insights into Molecular Protistan Ecology.Biogeochemistry and the structure of tropical brown food webs.Enhanced phosphorus nutrition in monocots and dicots over-expressing a phosphorus-responsive type I H+-pyrophosphatase.Investment in boney defensive traits alters organismal stoichiometry and excretion in fish.Ontogenetic variation in the body stoichiometry of two fish species.Scaling of individual phosphorus flux by caterpillars of the whitemarked tussock moth, Orygia leucostigma.Hot tadpoles from cold environments need more nutrients--life history and stoichiometry reflects latitudinal adaptation.Multiple environmental controls on phytoplankton growth strategies determine adaptive responses of the N : P ratio.Protein synthesis controls phosphate homeostasis.Plasticity in metabolic allometry: the role of dietary stoichiometry.Multiple nutrients and herbivores interact to govern diversity, productivity, composition, and infection in a successional grassland Integrating elements and energy through the metabolic dependencies of gross growth efficiency and the threshold elemental ratio The elemental stoichiometry of aquatic and terrestrial ecosystems and its relationships with organismic lifestyle and ecosystem structure and function: a review and perspectives Exploring patterns and mechanisms of interspecific and intraspecific variation in body elemental composition of desert consumers How allometric scaling relates to soil abiotics Soil acidity, ecological stoichiometry and allometric scaling in grassland food webs The Stoichiometry of Nutrient Release by Terrestrial Herbivores and Its Ecosystem Consequences Ontogenetic coupling of growth rate with RNA and P contents in five species of Drosophila

P2860

Q22066325-B630D6BB-9080-47BB-8738-C4FF49785D3C Q24673689-8C18C98B-B56B-4C97-89D5-DE1258C71A82 Q30870042-F4B49B1F-32DD-40F2-95B3-3CD5B5D300EE Q33291142-F2DB49BE-EA6C-4F5F-9989-BA61C08D852C Q33302123-82E33FF1-7DEF-458E-B9B3-DC5214549A7B Q33734520-4C4ADC27-C103-49C1-A0F7-011AE46C9765 Q33983718-F1533632-E122-474D-9E70-820F2C8A38D5 Q34541406-86AB80DD-2172-4EA0-9AC4-3B296CD477B7 Q34694221-724D0137-022F-4DA6-A6AF-547ED16CF432 Q34974131-86839096-C1BD-4593-BE94-BD234E5C26B0 Q35134840-438EBA0A-FC07-43DA-84B9-D83D40EAC7C2 Q35209496-974CC081-A686-4A4F-8378-33688A4A8D2B Q35644579-E4889745-2B88-4CF2-8E63-03C579A10326 Q36370924-7DD127A1-B10C-44FF-9BAF-39680D702C92 Q36560882-2697A162-D95C-4A62-AA72-74CDE41B29E5 Q37000114-55A8C844-396C-420A-8012-A1ECBF3F6A1D Q37087034-40E33020-34FF-4618-A620-22AC95C346FE Q38095683-8E29E9CD-E3E2-4463-9708-1EB85841031B Q38667428-BDD47B28-EA70-4957-89AB-351A4E24782A Q38778941-C6DDA642-7108-476E-8D41-49F298C89DC2 Q38789109-FD42774C-57C8-478B-A47C-07FC8D18D11E Q39122707-496C814B-FFF4-4EAC-AC46-3459BC867F8C Q39612673-3158128C-E5CF-44DE-9E48-1C132B40A94B Q39853162-94F4B729-3675-4ED2-B4C0-819CFC1E80EC Q40913673-C071A770-54FB-4556-AC01-333185364C4A Q41520798-6417F662-28B1-4F01-AE65-E75E24DFBCC1 Q44960654-C2A09819-6C6E-4EB2-9319-079708816FCF Q46946904-90FD117A-B7A0-431B-A49C-292255D89AFB Q49923898-159EE10A-8481-4217-9F0F-6B4709DA335B Q51711975-C4583F5D-F17A-4F01-AB24-0B0F8EF6E391 Q56930270-5C91EB3B-AEB0-4EA6-9723-7EBB80C10431 Q56972737-D6CAEDDD-90AD-4CB2-8F08-620DFE303EFF Q56991101-3EAAC164-97A7-41CA-8190-6F8F68CA4C88 Q57014660-29AE3659-65D3-4F7F-B0D4-5933E10D542D Q57504903-4F2940B8-ED5B-4F6B-89CF-2EE037F6F399 Q57504983-8C78392B-0F95-4757-8595-03FC7863F7FE Q57730249-52A55993-6E22-4096-8B0D-4E821986FE21 Q58390899-82E62F4B-70E2-4DA9-AEB5-A7C6313E8E1E

P2860

The metabolic basis of whole-organism RNA and phosphorus content

http://www.wikidata.org/entity/Q33920196

description

2005 nî lūn-bûn

@nan

2005 թուականի Օգոստոսին հրատարակուած գիտական յօդուած

@hyw

2005 թվականի օգոստոսին հրատարակված գիտական հոդված

@hy

2005年の論文

@ja

2005年論文

@yue

2005年論文

@zh-hant

2005年論文

@zh-hk

2005年論文

@zh-mo

2005年論文

@zh-tw

2005年论文

@wuu

name

The metabolic basis of whole-organism RNA and phosphorus content

@ast

The metabolic basis of whole-organism RNA and phosphorus content

@en

type

label

The metabolic basis of whole-organism RNA and phosphorus content

@ast

The metabolic basis of whole-organism RNA and phosphorus content

@en

prefLabel

The metabolic basis of whole-organism RNA and phosphorus content

@ast

The metabolic basis of whole-organism RNA and phosphorus content

@en

P1433

Q33920196-F7BF9432-CE93-4855-8E40-54A97B058AE1

P1476

Q33920196-C84369F7-0140-4A7D-B980-E4EDC2FCD04E

P2093

Q33920196-04E1BF83-F760-47DE-A917-A5ADE568D885

Q33920196-122AA29B-A00C-451E-B8C5-E03369763910

Q33920196-49316AF6-054A-4931-ABE6-33F3775CCEAC

Q33920196-BB3C3FAA-4D06-42EC-A3F2-9E0B2B088490

Q33920196-C702B7B4-3054-4C2D-BFCD-CB80FEF23985

Q33920196-CA3A5CFB-5367-4CC0-8BF3-B8C7F16E2390

Q33920196-CFBED48A-B4E7-4C0B-BF69-8B281DE5FBBD

P2860

Q33920196-0215B3CF-B99E-44A0-88CE-A422C5544E15

Q33920196-196EA78E-779A-4369-87B2-245EF2EFE262

Q33920196-1A4E26EE-120F-4B4C-B571-E3CEFC4B3C5E

Q33920196-37529383-0C09-4730-AF63-CC83D1E3FF8D

Q33920196-3E17AB89-3BA2-404E-BC4B-CACE84408C95

Q33920196-4573BDCD-69A8-4E7F-BC01-BC9356D0C48E

Q33920196-520884CE-7A65-4B93-ADCC-52D97E96BC87

Q33920196-5B16814E-84D5-41EC-BA9E-9A2274460E66

Q33920196-63004AF7-3FDD-4B90-AE2D-643578B5CD9A

Q33920196-6DE98479-380E-41F9-9303-D5BAC79D6FB8

P304

Q33920196-3BDAE266-F67D-4BB6-B7F7-CB7F6F23DB21

P31

Q33920196-2DFD1A3B-7610-4312-9A62-3093B095F12F

P356

Q33920196-00450E12-0056-4513-88CD-1461B44AD494

P407

Q33920196-08452781-AEA1-47AF-AA9D-DF2A8AB84B92

P433

Q33920196-450945AA-E429-4146-BA25-B86C83ACBCBF

P478

Q33920196-DE72E442-0F85-42FF-8940-F789C69B604D

P50

Q33920196-37D23A08-8F0C-47E8-8A71-F8AE28E18180

Q33920196-73D4F1DC-4516-4F7E-856A-37ABF3D28CBD

P577

Q33920196-69088010-BBD9-4E79-B43B-6B7D8194ADE2

P5875

Q33920196-5BA02C9C-6E6A-4518-86D5-EAD0239B977A

P698

Q33920196-C410AC66-3A8D-4D4B-913C-0923C0A981B7

P932

Q33920196-A4693D5F-1368-468B-98BF-AA0CCBA64478

P356

PNAS.0504756102

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

The metabolic basis of whole-organism RNA and phosphorus content

@en

P2093

Carlos Martinez del Rio

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

Geoffrey B West

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

H Arthur Woods

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

James F Gillooly

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

James H Brown

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

Van M Savage

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

William H Woodruff

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

P2860

Effects of size and temperature on metabolic rate

A general model for the origin of allometric scaling laws in biology

The ribosome as an entropy trap

The impact of surface-adsorbed phosphorus on phytoplankton Redfield stoichiometry.

Nutritional constraints in terrestrial and freshwater food webs.

Mechanisms underlying the cost of living in animals.

Allometric scaling of metabolic rate from molecules and mitochondria to cells and mammals.

Optimal nitrogen-to-phosphorus stoichiometry of phytoplankton.

Cellular energy utilization and molecular origin of standard metabolic rate in mammals.

Overview: phosphorylation and translation control.

P304

11923-11927

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

P31

scholarly article

P356

10.1073/PNAS.0504756102

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

P407

P433

33

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

P478

102

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

P50

P577

2005-08-09T00:00:00Z

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

P5875

216811358

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

P698

16091465

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

P932

1187991

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