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Data from: Modeling central metabolism and energy biosynthesis across microbial life
负责人:
关键词:
phylogenetic trees;metabolic models;core metabolism;pathway analysis
DOI:
doi:10.5061/dryad.gs51v
摘要:
in genome-scale metabolic models, and the need for extensive gapfilling to support complex biomass reactions, often results in predicting unrealistic yields or unrealistic
Data from: Energy and the scaling of animal space use
负责人:
关键词:
Allometry Ecology: spatial Home range Predator-prey mass ratio (PPMR)
DOI:
doi:10.5061/dryad.q5j65
摘要:
ty, trophic guild, and prey size) and whether these extend beyond the commonly studied birds and mammals. We derive new home-range scaling relationships for fishes
Data from: Adding biotic complexity alters the metabolic benefits of mutualism
负责人:
关键词:
exploitation;Salmonella enterica;S. enterica;cooperation;Escherichia coli;metabolic modeling;mutualism;E. coli;Methylobacterium extorquens
DOI:
doi:10.5061/dryad.5jk4d
摘要:
a. Conversely, selection for cooperation was lower in the tripartite mutualism relative to the pair-wise system. Genome-scale metabolic models helped identify
Data from: Allometry of mitochondrial efficiency is set by metabolic intensity
负责人:
关键词:
Mammals;Mitochondria;ATP synthesis;skeletal muscle;oxidative phosphorylation
DOI:
doi:10.5061/dryad.fh4vb2c
摘要:
coupling efficiency across mammal species could partly explain why scaling exponent values are very close to 1 at maximal metabolic rates.
Data from: Allometric convergence in savanna trees and implications for plant scaling models in variable ecosystems
负责人:
关键词:
Allometry;biomass;Savanna;trees
DOI:
doi:10.5061/dryad.4s1d2
摘要:
a. We use these exponents to provide a rigorous test of three plant scaling models (Metabolic Scaling Theory (MST), Geometric Similarity, and Stress
Data from: Universal metabolic constraints shape the evolutionary ecology of diving in animals
负责人:
关键词:
ectothermy;endothermy;Evolutionary physiology;paleophysiology;mass scaling;Allometry
DOI:
doi:10.5061/dryad.tqjq2bvv9
摘要:
animals, irrespective of their evolutionary history and metabolic mode. The steeper scaling relationship between body mass and dive duration in endotherms
Data from: A metabolic and body-size scaling framework for parasite within-host abundance, biomass, and energy flux
负责人:
关键词:
Cylicocyclus nassatus;Setaria equina;Cyathostomum montgomeryi;Trichostrongylus affinis;Cylicocyclus gyalocephaloides;Crenosoma sp.;Dictyocaulus viviparus;Cylicostephanus bidentatus;Cylicostephanus minutus;Oesophagostomum quadrispinulatum;Cyathostomum labratum;Ancylostoma caninum;Cylicocyclus triramosus;Cylicodontophorus reineckei;Capillaria aerophilus;Metastrongylus pudendoctectus;Parascaris equorum;energetics;Toxocara cati;Carolinensis kinsellai;Protostrongylus macrotis;Syphacia peromysci;Litosomoides carinii;Macroecology;Cyathospirura sp.;Ascaris suum;Metathelazia californica;Nematodirus odocoilei;Parabronema pecariae;Cylicocyclus adersi;Skrjabinema parva;Physocephalus sexalatus;Apteragia odocoilei;Capillaria plica;Craterostomum acuticaudatum;Oxyuris equi;Strongyloides sigmodontis;Probstmayria vivipara;Placoconus lotoris;Trichostrongylus colubriformis;Globocephalus urosubulatus;Triodontophorus minor;Triodontophorus brevicaudata;Ecology: community;Oesophagostomum venulosum;Oslerus osleri;Capillaria putorii;Cylicostephanus longiconus;Texicospirura turki;Haemonchus contortus;Cyathostomum catenatum;Skrjabinema sp.;Ascarops strongylina;Poteriostomum ratzii;Poteriostomum imparidentatum;Gongylonema pulchrum;Strongyloides westeri;Aspiculuris tetraptera;Cyathostomum tetracanthum;Interactions: host\/parasite;Toxascaris leonina;Pharyngostomoides procyonis;Trichostrongylus thomasi;Cylicostephanus calicatus;Protospirura numidica;Spirocerca lupi;Lagochilascaris sp.;Hymenolepis diminuta;Physaloptera praeputialis;Ancylostoma tubaeforme;Crossocephalus viviparus;Baylisascaris transfuga;Habronema muscae;Ostertagia mossi;Parabronema skrjabini;Gnathostoma sp.;Nematodirus helvetianus;Sertaria yehi;Pterygodermatites peromysci;Cylicospirura subaequalis;Stephanurus dentatus;Ostertagia ostertagi;Allometry;Monodontus floridanus;Cylicodontophorus schuermanni;Dirofilaria immitis;Physaloptera rara;Molineus barbatus;Triodontophorus nipponicus;Draschia megastoma;Syphacia sigmodontis;Cooperia oncophora;Moniliformis dubius;Trichostrongylus axei;Triodontophorus serratus;Haemonchus mitchelli;Strongyloides sp.;Dracunculus sp.;Cyathostomum alveatum;Vogeloides felis;Cylicocyclus auriculatus;Trichuris vulpis;Metastrongylus apri
DOI:
doi:10.5061/dryad.14nn1
摘要:
bably due to methodological difficulties. However, the scaling relationships of individual metabolic rate with body or cell-size and temperature ma
Data from: Ontogenetic and interspecific scaling of consumption in insects
负责人:
关键词:
uptake.;uptake;body mass;Dynamic Energy Budget (DEB) theory;Insecta;Metabolic Rate;Invertebrate;metabolic theory of ecology (MTE)
DOI:
doi:10.5061/dryad.35n9f
摘要:
comparisons. Using principles of dynamic energy budget theory, we present a mechanistic model for the body mass scaling of consumption, which separates

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