ライフサイエンスコーパス: ecology

1 s is one of the most controversial issues in ecology.

2 long-term dynamics are ongoing challenges in ecology.

3 ps to advance reproducibility in trait-based ecology.

4 f tetraploids related to their evolution and ecology.

5 sms persist remains an essential question in ecology.

6 magnitude, associated with their habitat and ecology.

7 complex communities is a central question in ecology.

8 ications for disease transmission as well as ecology.

9 ing community assembly is a central issue in ecology.

10 ally investigated using tools from community ecology.

11 unknown bauplan, and a previously undetected ecology.

12 a along with a comprehensive review of their ecology.

13 ons in relation to their unique behavior and ecology.

14 t is correlated with shifts in body size and ecology.

15 unities is fundamental to the development of ecology.

16 plexity evolves is a fundamental question in ecology.

17 otics in studies of behavioural and movement ecology.

18 oxin, delta-toxin) that defined a pathogenic ecology.

19 factor for computational reproducibility in ecology.

20 ure research challenges in the field of root ecology.

21 y for drug discovery and studying microbiome ecology.

22 earch should focus on understanding mosquito ecology.

23 reased brain size including biogeography and ecology.

24 d should also be useful for plant and animal ecology.

25 , but we lack a scale-perspective of cyclone ecology.

26 ironmental gradients is a major challenge in ecology.

27 s a fundamental attribute of animal movement ecology.

28 typically handled by hierarchical models in ecology.

29 as model systems to understand evolution and ecology.

30 h this process being mediated by an animal's ecology.

31 as been slow, especially in biodiversity and ecology.

32 a broad range of questions in evolution and ecology.

33 ection dynamics incorporating the known host ecology.

34 aints for species invasions are important in ecology.

35 basic questions related to IAV evolution and ecology.

36 andard pillars of knowledge in physiological ecology.

37 s to other wolves and short life-history and ecology.

38 ys commonly used to understand marine mammal ecology.

39 duce offspring that differ in morphology and ecology.

40 rstanding their distribution, abundance, and ecology.

41 fits and are therefore central to a species' ecology.

42 , a key determinant of animal physiology and ecology.

43 and thus plays a global role in climate and ecology.

44 the promise of minimal models for microbial ecology.

45 n grape agroecosystems including its spatial ecology.

46 ntitative and predictive microbial community ecology.

47 tant, but not yet fully resolved question in ecology.

48 Journal of Animal Ecology.

49 esearch linking humans, animal behaviour and ecology.

50 integrity, immune activation, and microbial ecology.

51 tion about the Rodrigues owl's evolution and ecology.

52 s insights into eye functionality and visual ecology.

53 of ecological networks is a key frontier in ecology.

54 itated evolutionary diversification of shark ecologies.

55 en individuals inhabit more and less diverse ecologies.

56 on scales is fundamental to many concepts in ecology [1], including migration [2, 3].

57 t underlie bacterial diversity is central to ecology(1,2) and microbiome research(3).

58 of network cluster dynamics in multi-species ecologies(15).

59 2,13), strategy(14,15), evolution(16,17) and ecology(18,19).

60 As a result, key questions related to the ecology(4,5), biogeography(3,6,7) and divergence times(1

61 Journal of Animal Ecology, 89, 276-284.

62 Journal of Animal Ecology, 89, 29-43.

63 Journal of Animal Ecology, 89, 972-995.

64 ow that HWI is correlated with geography and ecology across 10,338 (>99%) species, increasing at high

65 , many biologists assumed that evolution and ecology acted independently because evolution occurred o

66 How climate and ecology affect key cultural transformations remains deba

67 terature in plant physiology, ecophysiology, ecology, agronomy and soil science, we reviewed 24 aspec

68 Here, we introduce iEcology (i.e., internet ecology), an emerging research approach that uses divers

69 stimate spatial-social covariance in disease ecology analyses.

70 , many of which are associated with specific ecologies and shared with ecologically similar species f

71 important insights into migratory waterfowl ecology and AI disease dynamics that aid in better prepa

72 tial impact of biofluorescence on the visual ecology and behavior of biofluorescent amphibians.

73 iations, where species differ principally in ecology and behavior, these findings illustrate how new

74 shape that impacts numerous aspects of avian ecology and behaviour - has consistently increased acros

75 These phenotypes translated into distinct ecology and biofilm structures that enabled mutants to c

76 e processes are critically important to soil ecology and biogeochemistry yet are difficult to study d

77 y applying this framework to case studies in ecology and biology, we are able to not only understand

78 otka-Volterra (gLV) equations from community ecology and compositional data analysis.

79 l behavioral responses with implications for ecology and conservation.

80 ent method has facilitated advances in virus ecology and discuss its current limitations and future p

81 nce of viral pathogens, and ultimately their ecology and dispersion, hinges on their ability to withs

82 oaches will transform the field of microbial ecology and dramatically improve our understanding of ho

83 data in areas such as computational biology, ecology and econometrics.

84 Diet provides critical information about the ecology and environment of herbivores.

85 ostic test for FFV, efforts to elucidate the ecology and epidemiology of the virus may be complicated

86 our understanding of K. pneumoniae taxonomy, ecology and evolution as well as the diversity and distr

87 We also invite the ecology and evolution community to lead further progress

88 Amplifying Black excellence in ecology and evolution is the antidote for white supremac

89 oral reef species, potentially impacting the ecology and evolution of a key regional endemic.

90 ing predators is a fundamental aspect of the ecology and evolution of all prey animals.

91 pacts of environmental predictability on the ecology and evolution of animal movement have been the s

92 etagenomes and pangenomes to investigate the ecology and evolution of bacteria across analytical scal

93 and the contribution of these systems to the ecology and evolution of bacteria, archaea, and the mobi

94 the temporal dimension for understanding the ecology and evolution of complex webs of mutualistic int

95 erable advances in knowledge of the anatomy, ecology and evolution of early mammals, far less is know

96 un metagenomes has enabled insights into the ecology and evolution of environmental and host-associat

97 , as well as more fundamental aspects of the ecology and evolution of interspecific interactions.

98 d has become an important model to study the ecology and evolution of microbiota-host interactions.

99 nce of these two arms of the defence for the ecology and evolution of prokaryotes and their parasites

100 could have significant ramifications for the ecology and evolution of these diverse and declining ver

101 ms has intensified interest in the microbial ecology and evolution of this biotope.

102 further research is needed to understand the ecology and evolution of viral size diversity.

103 In the future, urban ecology and evolution researchers must consider how syst

104 del system for asking questions in microbial ecology and evolution.

105 an reveal new dimensions to old questions in ecology and evolution.

106 ion, diversity, and collective excellence in ecology and evolution?

107 Power laws are cornerstone relationships in ecology and evolutionary biology.

108 iscusses the current knowledge regarding the ecology and evolutionary mechanisms of Lyme borreliae-ho

109 ts have wide-ranging implications for global ecology and for anticipating changes in host use during

110 ild has led to a better understanding of its ecology and habitat preferences making it an excellent m

111 We advocate for increased engagement between ecology and infectious researchers to address such commo

112 pproaches in metaecosystem and metacommunity ecology and integrate cross-scale feedbacks.

113 ues for further integration of natural enemy ecology and integrated pest management.

114 ion of the genome provides insights into the ecology and long evolutionary history of this important

115 We call this synthesis between ecology and metabolomics 'meta-metabolome ecology' and d

116 athogens they carry, the fields of bat virus ecology and molecular biology are still nascent, with ma

117 es in the shape of the humerus are driven by ecology and phylogeny and are associated with functional

118 entity and symbiotic phenotype influence the ecology and physiology of lichens, they are not correlat

119 in this critical area of direct relevance to ecology and plant performance in a changing world.

120 xa and provides insight into their community ecology and potential pathogenicity.

121 damental mechanisms underlying predator-prey ecology and present a conceptual guide for designing exp

122 s, and their microbiomes can be leveraged in ecology and restoration.

123 anged during growth and has implications for ecology and skull development that go beyond paleontolog

124 However, most traits relevant for ecology and vegetation modelling are characterized by co

125 these drivers in the context of evolutionary ecology and wildlife-human interactions.

126 en ecology and metabolomics 'meta-metabolome ecology' and demonstrate its utility using a mass spectr

127 for the common aims of systems neuroscience, ecology, and ethology.

128 equences for host and pathogen interactions, ecology, and evolution has grown.

129 ur understanding of the metabolic potential, ecology, and global distribution of the Thermoplasmata a

130 as achieved remarkable popularity in disease ecology, and is sometimes carried out without investigat

131 s drosophilids, this study suggests that the ecology, and not common ancestry, contributes to diversi

132 stable isotope techniques are widely used in ecology, archaeology, and forensic science to explore tr

133 eased genetic diversity and often fragmented ecology, are then vulnerable to small stochastic perturb

134 for ecological research, especially movement ecology, are vast, but the crucial questions of how best

135 e patterns in grassland organism nutritional ecology as plant species and physiology are altered with

136 variety of fields including plant and animal ecology as well as human health.

137 sting concepts from community and population ecology, as well as an accompanying set of metrics that

138 s reveal new links between avian physiology, ecology, behaviour and life history, while demonstrating

139 estions underlying the fields of behavioural ecology, behavioural economics and psychology.

140 ies to annual N(2) fixation and thus pelagic ecology, biogeochemistry and CO(2) sequestration, the pr

141 ), are an important feature of predator-prey ecology, but their significance has had little impact on

142 ow existing methods in the field of movement ecology can be extended to use this exciting new data ty

143 tended to focus on genetic relatedness, but ecology can be just as important a determinant of whethe

144 The ratio of men to women in a given ecology can have profound influences on a range of inter

145 The disease ecology community has struggled to come to consensus on

146 ow expression levels, reflecting a versatile ecology compare to the more competitive G. androsaceus w

147 s enhances nutrient fluxes that support soil ecology, contributes to dispersion of sediment and conta

148 Our results show that stromal ecology correlates directly with tumour growth but inver

149 dataset of woody species from the Fine-Root Ecology Database (FRED).

150 iality (e.g., group structure, functioning), ecology (e.g., response to environmental change), and ev

151 amical systems is important in the fields of ecology, economics, critical infrastructures, and organi

152 ts of a survey of 322 editors of journals in ecology, economics, medicine, physics and psychology.

153 tion carrying capacity with implications for ecology, evolution and conservation.

154 behaviors has important implications for the ecology, evolution, and conservation of animals.

155 entities on Earth and play key roles in host ecology, evolution, and horizontal gene transfer.

156 ognized) need among researchers in molecular ecology for bioinformatic software that will not only co

157 road applications from traditional taxonomy, ecology, forensics, food analysis, and environmental sci

158 sequences for our understanding of AM fungal ecology, from the level of the fungus, at the plant comm

159 ry, marking permanent changes to terrestrial ecology, geochemical cycles, atmospheric CO(2) levels, a

160 rculation, albedo, carbon storage, etc.) and ecology (harboring the highest biodiversity of continent

161 Although movement ecology has leveraged models of home range formation to

162 rk from evolutionary biology, economics, and ecology has shown that specialization is beneficial when

163 nd social cues on movement behavior, disease ecology has yet to integrate these potential drivers and

164 Many probiotics that affect gut microbial ecology have been shown to produce beneficial effects on

165 cal theories such as the metabolic theory of ecology have focused on the effects of temperature rathe

166 Decades of research in ecology have generated myriad concepts for the appropria

167 classic optimal foraging theory, nutritional ecology, heuristics) conceptualise multi-attribute choic

168 ormation due to a long-standing challenge in ecology: How do we draw robust population-level inferenc

169 o test a perennial question in predator-prey ecology: how prey balance foraging and safety, as formal

170 disease, including parasite biology, disease ecology, human/animal infection, and administrative issu

171 ltidisciplinary approach combining microbial ecology, immunology, cancer cell biology, and computatio

172 e observed no changes in wolf spider feeding ecology in association with short-term experimental warm

173 chetypal relationship between beak shape and ecology in Darwin's finches and Hawaiian honeycreepers,

174 applied phage biology, and the importance of ecology in evolution of phage resistance.

175 y 9% of camera trap studies on predator-prey ecology in our review use experimental methods, but the

176 Overall, we show that the role of ecology in shaping signal evolution applies to surprisin

177 is study demonstrates alterations in feeding ecology in stingrays at SCS which is of critical importa

178 the interaction between the organism and its ecology in the course of phylogeny and ontogeny, human m

179 our understanding of plankton diversity and ecology in the ocean as a planetary, interconnected ecos

180 little is known about their biogeography and ecology in the ocean.

181 Expression of this phenotype (and presumed ecology) in a stem bird underscores that consolidation t

182 ated with a range of feeding and behavioural ecologies, in contrast to Mesozoic birds.

183 behaviours emerge independently of the local ecology, indicating that hunting techniques in bonobos m

184 istical analyses to compare common microbial ecology indices and immune-mediator median fluorescence

185 hite shark (Carcharodon carcharias) movement ecology is based on individual tracking studies using re

186 Our understanding of cyclone ecology is biased towards the North Atlantic Basin, beca

187 Although the sinus microbial ecology is highly variable between individuals, we ident

188 gy management models in understanding animal ecology is presently unclear.

189 A key concept for such synthesis in ecology is the niche, the set of capabilities that enabl

190 A major goal in ecology is to leverage these patterns to identify the ec

191 A central goal in microbial ecology is to simplify the extraordinary biodiversity th

192 A key challenge in ecology is to understand the relationships between organ

193 t whether size plays a central role in viral ecology is unknown.

194 which integrates concepts from metacommunity ecology, is necessary to reveal underlying mechanisms go

195 erial species with poorly understood current ecologies (let alone their ecological histories).

196 to humans due to broad-scale differences in ecology, life history, and physiology currently influenc

197 relatively small size and possible littoral ecology may corroborate proposed ecological filters(4,5,

198 nd-use changes may benefit from a functional ecology mindset.

199 We analyzed data on host ecology, molecular epidemiology, serological dynamics, a

200 may facilitate speciation through shifts in ecology, morphology or both.

201 spatially explicit patterns and processes in ecology most often rely on climate data interpolated fro

202 broad class of real-world applications from ecology, neurology, and finance, we explore and are able

203 Combining two tenets of ecology-niche theory and predator-prey theory-provides a

204 lied to the emergence of social and cultural ecologies of mind.

205 Here, we assess the viral community ecology of 22 deeply sequenced viral metagenomes along a

206 Here, we examined the seawater microbial ecology of 25 Northern Caribbean reefs varying in human

207 fy the effects of artisanal fisheries on the ecology of a small cetacean, the Ganges River dolphin (P

208 glacial meltwater is expected to impact the ecology of adjoining ecosystems.

209 build models that simulate the behavior and ecology of adult mosquitoes in exquisite detail on compl

210 ypothesized to play an important role in the ecology of AMR.

211 research on the biochemistry, physiology and ecology of AO and discusses the consequences for AO comm

212 Cluster analysis by airway ecology of asthma and COPD in stable state identified tw

213 frequently used approaches to study movement ecology of birds.

214 only minor differences between the isotopic ecology of both these taxa.

215 iduals." The incorporation of the behavioral ecology of conflict species opens promising areas to sea

216 In addition, the microbial ecology of different ANAMMOX-mediated systems is reviewe

217 rogen is a major driver of the physiological ecology of E. huxleyi in this system and further suggest

218 logical and technical aspects coupled to the ecology of eDNA and the 2G ESP instrumentation.

219 ovides a framework for analysing the spatial ecology of environmental microbial communities at single

220 direct and environmental transmission in the ecology of epidemics remains a persistent challenge.

221 tant role in understanding the predator-prey ecology of free-living animals, and such methods will be

222 antitative evidence that the airborne fungal ecology of homes with known mold growth ("moldy") differ

223 dy") differs from the normal airborne fungal ecology of homes with no history of dampness, water dama

224 ave formed a critical element in the dietary ecology of hominins.

225 Understanding the ecology of hosts and aspects of their physiology that ma

226 y researchers dedicated to understanding the ecology of IAV and its subsequent threat to human and an

227 tal change is having profound effects on the ecology of infectious disease systems, which are widely

228 ow continued climate warming will affect the ecology of Lake Tanganyika fishes and other tropical ect

229 Water temperature is critical for the ecology of lakes.

230 In addition, we compared the ecology of Late Neolithic NE cats with the earliest dome

231 general features concerning the biology and ecology of NOVC strains and their associated diseases, t

232 tions and conditions relevant to the natural ecology of NTM, such as hypoxia, is lacking.

233 tes to a better understanding of the feeding ecology of oceanic dolphins and provides new insights in

234 demic through the lenses of the evolutionary ecology of pathogens can help better understand the root

235 nvite scientists working on the evolutionary ecology of pathogens to contribute to a more "solution-o

236 litate novel insights about the evolutionary ecology of plant biotic interactions.

237 Thus, the ecology of red blood cells may play a key role in determ

238 tal to our understanding of the evolutionary ecology of reproductive strategies and sexual dynamics o

239 rooting depth systematically structures the ecology of savanna trees.

240 re available, they rarely use the behavioral ecology of the conflict species to derive effective and

241 rden has been challenging due to the complex ecology of the disease and the presence of multiple, int

242 tigated the population structure and feeding ecology of the dominant wolf spider species Pardosa lapp

243 Review provides an overview of the microbial ecology of the plastisphere in the context of its divers

244 irst information on the foraging and trophic ecology of the poorly-known TP.

245 n help us answer questions about the natural ecology of these amoeba-bacteria symbioses along the pat

246 pogenic climate change, which will alter the ecology of these habitats, even where protected.

247 ncing our understanding of the evolution and ecology of this remarkable lineage.

248 rther our understanding of the evolution and ecology of viruses in this host.IMPORTANCE Avian influen

249 tral to our understanding of the nutritional ecology of, and factors driving the population dynamics

250 ough the influence of bioreactor habitat and ecology on HGT frequency is not well understood.

251 ations to account for variability in trophic ecology on Svalbard when predicting bioaccumulation of P

252 as amassed considerable scholarship in urban ecology over the past few decades, providing a solid fou

253 in phylogenetics, phylogeography, genomics, ecology, paleobotany, population biology and quantitativ

254 stication and dispersal, plant evolution and ecology, paleoenvironmental composition and dynamics, an

255 re, we integrate knowledge of animal sensory ecology, physiology and life history to articulate three

256 ects of adult mosquito behavior and mosquito ecology play an important role in determining the capaci

257 However, knowledge of K. pneumoniae ecology, population structure or pathogenicity is relati

258 egrees of specialisation and diverse feeding ecologies, presenting numerous opportunities for compara

259 y used in epidemiology but rarely applied to ecology, provided high predictive accuracy (67-82%) and

260 and widely used technologies in ethology and ecology, providing unprecedented insight into animal beh

261 The metabolic theory of ecology quantitatively predicts the scaling of metabolic

262 In contrast, models in ecosystem ecology rarely track disease dynamics, yet elemental nut

263 Models in disease ecology rarely track organisms past death, yet death fro

264 hat wildfire is an integral part of peatland ecology rather than an anomaly.

265 evels (e.g., fish communities) to build flow-ecology relationships, rather than using a process that

266 habitat selection traits, we quantified flow-ecology responses in the Karnali River of Nepal during t

267 Bout-based and Individual-based Transmission Ecology Simulator).

268 logeny, and tested for relationships between ecology, skull shape, and hyperossification.

269 dietary items to investigate their foraging ecology, specifically focussing on the importance of sea

270 Beyond advancing understanding of migration ecology, SPR will facilitate conservation through identi

271 Thus, both disease and ecosystem ecology stand to grow as fields by exploring questions t

272 lexity, our understanding of lotic microbial ecology still lacks conceptual frameworks for the ecolog

273 ilable for interrogation by future microbial ecology studies.

274 ic variation is consequential to an animals' ecology, studies of functional variation are often restr

275 ependent PCa may be a result of poor stromal ecology, supporting the concept that purely tumour epith

276 prey sampling showed a more complex feeding ecology than previously understood, and provides a means

277 Here, we detail scenarios in disease ecology that benefit from spatial-social analysis.

278 Here, we apply methods from ecosystem ecology that quantify the structure and dynamics of the

279 lti-scale linkages between geomorphology and ecology that, in turn, define spatially explicit pattern

280 pite their close relatedness and overlapping ecology, they deviate strongly in both visual and olfact

281 s spatial-social network analyses in disease ecology thus far.

282 pproaches from macroecology and evolutionary ecology to better understand how adaptation and dispersa

283 elled insects, indicating a shift in trophic ecology to insectivory associated with diminutive body s

284 asting from a largely observational field of ecology to one rooted in mechanistic understanding.

285 de diversity of research topics, from 'pure' ecology to sociopolitical research.

286 olutionary biology, community and functional ecology, to biodiversity conservation, ecosystem and lan

287 cal and mathematical foundations of movement ecology, to include the rich set of high-frequency multi

288 household consumption, by linking Industrial Ecology tools and Integrated Assessment Models (IAM).

289 We review the state of code availability in ecology using a random sample of 346 nonmolecular articl

290 health surveillance and research in disease ecology, virology, and immunology.

291 treatment strategies to modulate the airway ecology warrants further investigation.

292 To better understand their ecology, we developed and environmentally-validated a qu

293 in other disciplines and pioneering work in ecology, we present a standardised framework to robustly

294 mics, natural resource economics, and marine ecology, we use a unique dataset and modeling framework

295 es can be modified for use in stable isotope ecology when data are not normally distributed in bivari

296 Hierarchical organization in ecology, whereby interactions are nested in a manner tha

297 minant of this aggressiveness is the stromal ecology, which can be either inhibitory, highly reactive

298 The integration of DNA-based fungal ecology with advanced computational approaches can be us

299 By pairing observations of mosquito ecology with environmental monitoring, we quantified lon

300 te and that incorporating markers of stromal ecology would improve prognosis.