about
Importance of metabolic rate to the relationship between the number of genes in a functional category and body size in Peto's paradox for cancerMetabolic network modularity in archaea depends on growth conditions.Data integration aids understanding of butterfly-host plant networks.Correlation between structure and temperature in prokaryotic metabolic networksOrigin of structural difference in metabolic networks with respect to temperature.Nested structure acquired through simple evolutionary process.Heterogeneity in ecological mutualistic networks dominantly determines community stability.FunSAV: predicting the functional effect of single amino acid variants using a two-stage random forest modelAn integrative computational framework based on a two-step random forest algorithm improves prediction of zinc-binding sites in proteinsThe proportion of genes in a functional category is linked to mass-specific metabolic rate and lifespanFunctional Classification of Uncultured "Candidatus Caldiarchaeum subterraneum" Using the Maple System.Systematic Protein Level Regulation via Degradation Machinery Induced by Genotoxic Drugs.Analysis of the Effect of Degree Correlation on the Size of Minimum Dominating Sets in Complex NetworksLimited influence of oxygen on the evolution of chemical diversity in metabolic networks.Current understanding of the formation and adaptation of metabolic systems based on network theory.Limitations of a metabolic network-based reverse ecology method for inferring host-pathogen interactions.Exosomes in mammals with greater habitat variability contain more proteins and RNAs.An automated system for evaluation of the potential functionome: MAPLE version 2.1.0.Heterogeneity of cells may explain allometric scaling of metabolic rate.Identification of chemogenomic features from drug-target interaction networks using interpretable classifiers.Climatic seasonality may affect ecological network structure: food webs and mutualistic networks.Habitat variability does not generally promote metabolic network modularity in flies and mammals.Metabolic network modularity arising from simple growth processes.Large-scale aggregation analysis of eukaryotic proteins reveals an involvement of intrinsically disordered regions in protein folding.PREvaIL, an integrative approach for inferring catalytic residues using sequence, structural, and network features in a machine-learning framework.Modeling for evolving biological networks with scale-free connectivity, hierarchical modularity, and disassortativity.Brain structural connectivity and neuroticism in healthy adultsNetwork resilience of mutualistic ecosystems and environmental changes: an empirical studyDecomposing the effects of ocean environments on predator-prey body-size relationships in food websMAPLE 2.3.0: an improved system for evaluating the functionomes of genomes and metagenomesMetabolic networks are almost nonfractal: A comprehensive evaluationModular organization of cancer signaling networks is associated with patient survivabilityGlobal architecture of metabolite distributions across species and its formation mechanismsEvolving networks by merging cliquesA network biology-based approach to evaluating the effect of environmental contaminants on human interactome and diseasesRevisiting the hypothesis of an energetic barrier to genome complexity between eukaryotes and prokaryotesDifficulty in inferring microbial community structure based on co-occurrence network approachesGlobal COVID-19 transmission rate is influenced by precipitation seasonality and the speed of climate temperature warming
P50
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P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Kazuhiro Takemoto
@ast
Kazuhiro Takemoto
@en
Kazuhiro Takemoto
@es
Kazuhiro Takemoto
@sl
type
label
Kazuhiro Takemoto
@ast
Kazuhiro Takemoto
@en
Kazuhiro Takemoto
@es
Kazuhiro Takemoto
@sl
prefLabel
Kazuhiro Takemoto
@ast
Kazuhiro Takemoto
@en
Kazuhiro Takemoto
@es
Kazuhiro Takemoto
@sl
P106
P1153
35270356700
P21
P2456
P31
P496
0000-0002-6355-1366
P5008
P569
2000-01-01T00:00:00Z