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Data from: Morphological diversification of biomechanical traits: mustelid locomotor specializations and the macroevolution of long bone cro

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关键词：: limbs;Trait Diversification;Functional morphology;Extant;skeleton;Second Moment of Area;Mustelidae;Mammals;Cross-Sectional Area;Adaptation

DOI：: doi:10.5061/dryad.7vf4004

摘要：: r, phylogenetic affinity underlies these results. Fitting models of trait evolution to CSA and SMA revealed that a multi-rate Brownian motion model and a multi

Data from: Decoupled diversification dynamics of feeding morphology following a major functional innovation in marine butterflyfishes

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关键词：: trophic versatility;adaptive zone;feeding mechanism;ecological release;design break-through;Miocene to recent

DOI：: doi:10.5061/dryad.t0910

摘要：: ilarly. We measured 19 cranial functional morphological traits, gut length and body elongation for 33 Indo-Pacific species. Comparisons of Brownian motion

Data from: Running in circles in phylomorphospace: host environment constrains morphological diversification in parasitic wasps

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关键词：: Brownian motion;parasitoid;Cryptinae;Gabunia;evolution rates;Cryptini;Morphological Evolution;Ichneumonidae;Cryptus;Holocene;Geometric morphometrics

DOI：: doi:10.5061/dryad.41r1q12

摘要：: ve roles of rate versus mode of morphological evolution for a hyperdiverse group: cryptine ichneumonid wasps. Data from genomic ultraconserved elements (UCEs

Data from: Metabolic physiology explains macroevolutionary trends in the melanic colour system across amniotes

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关键词：: phenotypic evolution;melanosome;Brownian motion;sexual selection;integument

DOI：: doi:10.5061/dryad.qv871g8

摘要：: Metabolism links organisms to their environment through its effects on thermoregulation, feeding behaviour, and energetics. Genes involved

Data from: The evolution of hominoid cranial diversity: a quantitative genetic approach

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关键词：: Morphological Evolution;Pan troglodytes troglodytes;Pan paniscus;Homo Sapiens;Symphalangus syndactylus;Great and Lesser apes;Gorilla gorilla;Pan troglodytes schweinfurthii;Pan troglodytes verus;Gorilla beringei beringei;Hylobates lar;Hoolock hoolock;Hylobates muelleri;Pongo abelii;Hylobates agilis;Gorilla beringei graueri;Pongo pygmaeus;Hominoidea

DOI：: doi:10.5061/dryad.2pb43

摘要：: on a Brownian motion model of evolutionary change to estimate nested hypothetical ancestral forms from 15 extant hominoid taxa. These ancestors were then use

Data from: Elliptical Time-Density model to estimate wildlife utilization distributions

负责人：: University Of Konstanz

关键词：: African elephant animal movement GIS GPS tracking home-range Loxodonta africana utilization distribution

DOI：: doi:10.5441/001/1.f321pf80

摘要：: . We compared the performance of the ETD model, the Brownian Bridge Movement Model (BBMM), the Time-Geography Density Estimator (TGDE

Data from: A phylogenetic analysis of macroevolutionary patterns in fermentative yeasts

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关键词：: Zygosaccharomyces bisporus;Zygosaccharomyces mellis;Zygosaccharomyces bailii;Kluyveromyces nonfermentans;Kazachstania turicensis;Naumovozyma castellii;Lachancea waltii;Saccharomycodes ludwigii;Saccharomyces cariocanus;Saccharomyces pastorianus;Tetrapisispora phaffii;Saccharomyces bayanus;Kazachstania barnettii;Vanderwaltozyma polyspora;Hanseniaspora occidentalis;comparative method;Hanseniaspora vineae;Saccharomyces mikatae;Kazachstania spencerorum;Kazachstania exigua;Zygosaccharomyces kombuchaensis;Kazachstania kunashirensis;Saccharomicotina;Schizosaccharomyces pombe;Eremothecium cymbalariae;Kluyveromyces marxianus;Wickerhamomyces anomalus;Naumovozyma dairenensis;Saccharomyces paradoxus;Hanseniaspora valbyensis;Torulaspora franciscae;Zygosaccharomyces rouxii;Kazachstania viticola;Kazachstania telluris;Hanseniaspora guilliermondii;Candida glabrata;Torulaspora delbrueckii;Zygotorulaspora florentina;Eremothecium coryli;Lachancea kluyveri;Kazachstania servazzii;Lachancea fermentati;Kluyveromyces aestuarii;Eremothecium gossypii;Saccharomyces kudriavzevii;Kluyveromyces lactis;fermentation;Hanseniaspora osmophila;Kazachstania lodderae;Kazachstania unispora;Saccharomyces cerevisiae;phylogenetic signal;Tetrapisispora blattae;Kluyveromyces dobzhanskii;Torulaspora globosa;Kazachstania rosinii;Candida humilis;Kloeckera lindneri;Vanderwaltozyma yarrowii;Lachancea cidri;adaptive radiation;Tetrapisispora nanseiensis;Torulaspora microellipsoides;Kazachstania piceae;Lachancea thermotolerans;Kazachstania martiniae;Tetrapisispora iriomotensis;Kazachstania sinensis;Kluyveromyces wickerhamii;Kazachstania bulderi;Eremothecium ashbyi;Tetrapisispora arboricola;Kazachstania africana;Hanseniaspora uvarum;Zygotorulaspora mrakii;Nakaseomyces bacillisporus;Nakaseomyces delphensis;Zygosaccharomyces lentus;Eremothecium sinecaudum;Torulaspora pretoriensis;Candida castellii;Kazachstania transvaalensis

DOI：: doi:10.5061/dryad.2hf06

摘要：: accelerated evolution (diversification in trait values above Brownian Motion expectations) in cell-size. We also found a significant phylogenetic regression between cell

Data from: Phylogenetic patterns of trait and trait plasticity evolution: Insights from amphibian embryos

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关键词：: Pseudacris;Rana;Hyla;Hyla avivoca;Pseudacris crucifer;Anaxyrus;Lithobates;Anaxyrus boreas;Pseudacris ornata;Anaxyrus americanus;Pseudacris triseriata;Rana cascadae;Modern;Hyla versicolor;Anaxyrus fowleri;Pseudacris feriarum;Hyla wrightorum;Pseudacris maculata;Rana boylii;Procambarus clarkii;Rana aurora;Phylogenetic inertia;Pseudacris regilla

DOI：: doi:10.5061/dryad.7p02c

摘要：: ) model provided the best fit or was essentially tied with Brownian motion. Using the best fitting model, evolutionary rates for plasticities were higher

Elliptical Time-Density Model (Wall et al. 2014) African Elephant Dataset (Source-Save the Elephants)-reference-data

负责人：: University Of Konstanz

关键词：: African elephant animal movement GIS GPS tracking home-range Loxodonta africana utilization distribution

DOI：: doi:10.5441/001/1.f321pf80/2

摘要：: . We compared the performance of the ETD model, the Brownian Bridge Movement Model (BBMM), the Time-Geography Density Estimator (TGDE

Elliptical Time-Density Model (Wall et al. 2014) African Elephant Dataset (Source-Save the Elephants)

负责人：: University Of Konstanz

关键词：: African elephant animal movement GIS GPS tracking home-range Loxodonta africana utilization distribution

DOI：: doi:10.5441/001/1.f321pf80/1

摘要：: . We compared the performance of the ETD model, the Brownian Bridge Movement Model (BBMM), the Time-Geography Density Estimator (TGDE

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Data from: Morphological diversification of biomechanical traits: mustelid locomotor specializations and the macroevolution of long bone cro

Data from: Decoupled diversification dynamics of feeding morphology following a major functional innovation in marine butterflyfishes

Data from: Running in circles in phylomorphospace: host environment constrains morphological diversification in parasitic wasps

Data from: Metabolic physiology explains macroevolutionary trends in the melanic colour system across amniotes

Data from: The evolution of hominoid cranial diversity: a quantitative genetic approach

Data from: Elliptical Time-Density model to estimate wildlife utilization distributions

Data from: A phylogenetic analysis of macroevolutionary patterns in fermentative yeasts

Data from: Phylogenetic patterns of trait and trait plasticity evolution: Insights from amphibian embryos

Elliptical Time-Density Model (Wall et al. 2014) African Elephant Dataset (Source-Save the Elephants)-reference-data

Elliptical Time-Density Model (Wall et al. 2014) African Elephant Dataset (Source-Save the Elephants)

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