ライフサイエンスコーパス: ecological niche

1 constructing the species' potentially unique ecological niche.

2 d on adaptive strategies within a particular ecological niche.

3 an allow an animal to occupy an entirely new ecological niche.

4 ding its complexity and resilience within an ecological niche.

5 on with modern humans, who occupied the same ecological niche.

6 lleles is associated with socially inherited ecological niche.

7 hat species morphologies will adapt to their ecological niche.

8 raphical distribution while keeping the same ecological niche.

9 ent hybrid species with a potentially unique ecological niche.

10 AR(+)] appearance correlate with the yeast's ecological niche.

11 h an arsenal of secreted molecules for their ecological niche.

12 phylum with members inhabiting nearly every ecological niche.

13 but also their plasmids, are defined by the ecological niche.

14 thesis seems to correlate with lifestyle and ecological niche.

15 ction within the necrotrophic plant pathogen ecological niche.

16 ographic limits and the limits of a species' ecological niche.

17 frequently occupy environments outside their ecological niche.

18 ging evolutionary adaptations based on their ecological niche.

19 y adapts to efficiently exploit the animal's ecological niche.

20 es not necessarily result in the shift of an ecological niche.

21 ll raker numbers (GRNs) to utilize a broader ecological niche.

22 ly to have done so in isolates from the same ecological niche.

23 gene exchange between MGE occupying the same ecological niche.

24 nnovations allow populations to colonize new ecological niches.

25 pmental trajectories and limits on available ecological niches.

26 tope analyses as tools in the exploration of ecological niches.

27 n populations have access to many unoccupied ecological niches.

28 ggest that virophage genera occupy different ecological niches.

29 esponses, evolve new behaviours, and exploit ecological niches.

30 en the two fungi, related to their different ecological niches.

31 ctive isolation and allowing access to novel ecological niches.

32 ics that improve fitness in their particular ecological niches.

33 while encountering diverse and often hostile ecological niches.

34 alist species differ in the breadth of their ecological niches.

35 f evolutionary progress and constantly shape ecological niches.

36 biological diversification by unlocking new ecological niches.

37 the ability to inhabit otherwise prohibitive ecological niches.

38 with small ranges or increase the variety of ecological niches.

39 es, enabling these animals to occupy diverse ecological niches.

40 on it comprises a dramatically wide range of ecological niches.

41 m-negative bacteria inhabit a broad range of ecological niches.

42 eria and beta-cyanobacteria occupy different ecological niches.

43 key geographic regions, which opened up new ecological niches.

44 f major groups, as lineages invade disparate ecological niches.

45 and the fitness of V. cholerae in different ecological niches.

46 arily structured according to their members' ecological niches.

47 in most lineages, which rarely exploited new ecological niches.

48 happened in a C4 background and opened novel ecological niches.

49 actions of individuals situated in different ecological niches.

50 among hosts, facilitating adaptation to new ecological niches.

51 t for their differential survival in various ecological niches.

52 e shapes of facial whiskers reflect distinct ecological niches.

53 garner adaptive fitness for their respective ecological niches.

54 chococcus, or 'ecotypes' adapted to distinct ecological niches.

55 ution as well as its adaptation in different ecological niches.

56 in ways that enable microbes to exploit new ecological niches.

57 eir successful coexistence in their specific ecological niches.

58 theories of how species occupy and then fill ecological niches.

59 aptations of various species to their unique ecological niches.

60 f the core TCSTs for adaptation to different ecological niches.

61 ce of the NE cat, both felid taxa shared the ecological niches.

62 ltivated bacteria isolated from hot and arid ecological niches.

63 ffect on terrestrial biota by creating novel ecological niches.

64 onary forces triggered by dissimilarities of ecological niches.

65 iversity of eyes that are adapted to various ecological niches.

66 perties and their competitiveness in several ecological niches.

67 time that have diversified into a variety of ecological niches.

68 d evidence suggests that they filled similar ecological niches.

69 daptations enabled our colonisation of novel ecological niches.

70 isphere are attributed to adaptations to new ecological niches.

71 new traits and exploitation of inaccessible ecological niches [1, 2], driving evolutionary innovatio

72 nuclear loci (RAG-1, 1,054 bp; BDNF 529 bp), ecological niches (11 bioclimatic variables; 285 unique

73 al tetrapods and the establishment of modern ecological niches(12,13).

74 ly among gradients, indicating divergence in ecological niche across the species' range.

75 nome evolution of Symbiodiniaceae in diverse ecological niches across the broad spectrum of symbiotic

76 transduction, providing insights into their ecological niche adaptations.

77 nstrained to persistent and clearly distinct ecological niches: advanced members of Pliosauridae (ran

78 delivering degradative enzymes to defend an ecological niche against competing bacterial species, an

79 A microbe's ecological niche and biotechnological utility are determ

80 r functions, which are enriched in the rumen ecological niche and could confer advantages to their ho

81 gus-growing ants occupy a highly specialized ecological niche and face the constant existential threa

82 ges of conditions, gradually expanding their ecological niche and geographic range?

83 istent with reports that it occupies a wider ecological niche and has higher genetic diversity.

84 athogenic fungi and bacteria that share this ecological niche and have established microbial interact

85 discoveries about C. gattii genetics and its ecological niche and highlight areas ripe for future exp

86 We discuss its natural ecological niche and interactions with other organisms,

87 represents a likely adaptation to a specific ecological niche and may have been promoted by intensive

88 ns of individual microbial players within an ecological niche and the extent and directionality of in

89 These lungworms share both the ecological niche and the species of snail (Helix aspersa

90 olic differences during growth in the tested ecological niches and an overall reprogramming following

91 the needs of organisms that occupy different ecological niches and face different environmental chall

92 tarhizium robertsii occupies a wide array of ecological niches and has diverse lifestyle options (sap

93 e resistance may further spread into various ecological niches and into clinical high-risk pathogens.

94 on, allowing adaptation to a wide variety of ecological niches and lifestyles.

95 associated with the exploitation of multiple ecological niches and likely played a key role in the di

96 ned host and endosymbiont can exploit vacant ecological niches and occupy novel environments [1, 2];

97 gy have led to a better understanding of the ecological niches and pathogenesis of the condition.

98 process and likely reflects the diversity of ecological niches and roles mammals can play.

99 erences of the interactions between species' ecological niches and spatial distribution have been his

100 ons and replacements on the shift into novel ecological niches and subsequent lineage diversification

101 determining metabolic performance, fitness, ecological niches, and responses of many aquatic organis

102 urished and diversified as they filled empty ecological niches, and some of them presaged later dinos

103 nswered question originated with the idea of ecological niches, and yet bears relevance today for und

104 are being rapidly elucidated, the effects on ecological niche are still largely unknown.

105 l lineages with different life histories and ecological niches are largely unexplored.

106 ations that enable organisms to colonize new ecological niches are rare compared to gradual evolution

107 sympatry are more likely to coexist if their ecological niches are segregated either in time, space o

108 opportunistic pathogens that share the same ecological niches as amoebae.

109 ly related alpha-proteobacteria with similar ecological niches as S. meliloti, suggesting that the Ct

110 sses are likewise advantageous for switching ecological niches, as in microbial pathogen host switch

111 Early chaetognaths apparently occupied ecological niches associated with predatory euarthropods

112 onment, exemplifying the emergence of stable ecological niche behavior in a model system.

113 he buccal mucosa appeared as an intermediate ecological niche between the plaque and the tongue.

114 Growth of S. meliloti is modelled in three ecological niches (bulk soil, rhizosphere and nodule) wi

115 plants, C4 photosynthesis does not shift the ecological niche, but broadens it, allowing dispersal in

116 Animals adapt their behaviors to specific ecological niches, but the genetic and cellular basis of

117 The ecological niche can be thought of as a volume in multid

118 to understand how species occupying similar ecological niches can co-exist because, with limited res

119 ternative strategies and exploit alternative ecological niches, colour polymorphism can be expected t

120 from a more arboreal ancestor occupying the ecological niche common to all living apes.

121 election that integrates the behavioural and ecological niche concepts.

122 distribution models (SDMs) based on current ecological niche constraints are used to project future

123 y and other processes that more tightly pack ecological niches contribute more to ecosystem structure

124 re not targeted by the vaccine occupying the ecological niche created by the elimination of these typ

125 Critical thermal maxima were estimated, and ecological niches delineated using bioclimatic modeling.

126 Despite strong postzygotic isolation, ecological niche differentiation has long been thought t

127 to recent analyses, our results confirm that ecological niche differentiation is an important compone

128 phylogenetic and genomic diversity suggests ecological niche differentiation, but the selective forc

129 Light quantity and quality promotes ecological-niche differentiation of photosynthetic organ

130 infectious disease pathogen can be driven by ecological niche dissimilarities arising from different

131 s weakly influenced by richness-standardised ecological niche diversity, questioning the significance

132 nd (4) ecological, reflecting differences in ecological niche diversity.

133 ent clades were successful at spreading into ecological niches due to high behavioral plasticity and

134 arios in which expanding species track their ecological niche during climate change while adapting to

135 , in which a greater diversity of social and ecological niches elicits a broader range of multivariat

136 of giant mammals was diversification to fill ecological niches, environmental temperature and land ar

137 ence records, we examine the relationship of ecological niche evolution to diversification in the lar

138 ygen concentration constrain the fundamental ecological niches (FENs) of marine invertebrates and fis

139 Parasitism is a major ecological niche for a variety of nematodes.

140 Medical devices provide an ecological niche for microbes to flourish as a biofilm c

141 he formation of root nodules that provide an ecological niche for nitrogen-fixing bacteria.

142 glucosamine metabolism suggests an important ecological niche for oral chloroflexi in scavenging mate

143 s about the role of microplastics as a novel ecological niche for potentially pathogenic microorganis

144 n observations, we characterize the realized ecological niches for 87 North Atlantic diatom and dinof

145 establishment, for example by providing new ecological niches for hybrids, it will have limited effe

146 de demographic data needed to directly infer ecological niches for multiple species.

147 cquire it from organisms inhabiting a shared ecological niche-for example, ammonia-oxidizing archaea.

148 the adaptation of Agaricus to the humic-rich ecological niche formed during biomass degradation.

149 nisms governing adaptation to the humic-rich ecological niche formed during plant degradation, furthe

150 e conclude that the direct quantification of ecological niches from demographic responses to environm

151 It highlights that the inference of ecological niches from geographical distributions is mos

152 Here we argue that ecological niches function at levels above species, nota

153 straints for two important dimensions of the ecological niche--growth rates and distribution along cl

154 Colonization of new ecological niches has triggered large adaptive radiation

155 The evolutionary trajectories of ecological niches have profound impacts on community, po

156 64 strains of S. aureus spanning a range of ecological niches, host types, and antibiotic resistance

157 shared optima, defined by a multidimensional ecological niche hypothesis.

158 f the atmosphere, and led to the creation of ecological niches important for early life.

159 how to elucidate evolution in the context of ecological niches in any lineage of microbial eukaryotes

160 The sand flies have adapted to various ecological niches in distinct ecosystems.

161 the role of shared evolutionary history and ecological niches in driving variation in plant phytoche

162 rapods have repeatedly colonised a series of ecological niches in marine ecosystems, producing textbo

163 r flexible capacity to take advantage of new ecological niches, including adapting to humans as prima

164 cterial species distributed across different ecological niches, including human, animals, plants, and

165 ssociated with aphid lineages colonizing new ecological niches, including novel plant species and cli

166 Fungi inhabit extraordinarily diverse ecological niches, including the human body.

167 The quest to discover the variety of ecological niches inhabited by Saccharomyces cerevisiae

168 window into the molecular traits that define ecological niches, insight that we use to uncover source

169 The relationship between bacteria whose ecological niche is the eukaryote, and the eukaryote, is

170 ghly prevalent human pathogens whose primary ecological niche is the superficial epithelial layers of

171 ly diversification of angiosperms in diverse ecological niches is poorly understood.

172 the enigmatic role of the rhodopsins in dry ecological niches is still poorly understood.

173 ely related organisms usually occupy similar ecological niches, leading to intense competition and ev

174 ural selection drives adaptation to distinct ecological niches, leading ultimately to reproductive is

175 trypanosomatids, with their life cycles and ecological niches likely influencing these differences.

176 dispersal capacities and inhabiting a large ecological niche, local selection and gene flow are expe

177 indicative of adaptation to a rather strict ecological niche (mammalian skin).

178 In exploiting unique ecological niches many prokaryotes have evolved the mean

179 As mammals entered new ecological niches, many changes in tooth number occurred

180 We created a present-day ecological niche model (ENM) for C. picta and hindcast t

181 heir time-frequency resemblances and (ii) an ecological niche model that helps identify plague suitab

182 Ecological niche modeling (ENM) has been used to address

183 Ecological niche modeling (ENM) is widely employed in ec

184 We used two methodological approaches (ecological niche modeling [ENM] and geometric morphometr

185 Ecological niche modeling corroborates winter temperatur

186 tential areas of distribution of species via ecological niche modeling has become a very active field

187 e complementarity of population genetics and ecological niche modeling in understanding gene flow his

188 Ecological niche modeling indicated that changing climat

189 Here, we demonstrate how ecological niche modeling may be used to investigate the

190 Ecological niche modeling suggested that a gradual range

191 Molecular clock and ecological niche modeling suggested that the history of

192 orary and future climate conditions, we used ecological niche modeling techniques in conjunction with

193 Additionally, we use ecological niche modeling to infer current and past (Las

194 Using ecological niche modeling we investigated environmental

195 In this paper, we present phylogeographic, Ecological Niche Modeling, and morphometric analyses to

196 ith those of their diploid progenitors using ecological niche modeling, niche analyses, and multivari

197 f these geographic disjunctions, we combined ecological niche modeling, paleoclimate models, and the

198 Using ecological niche modeling, thermal tolerance experiments

199 ips has underappreciated potential to inform ecological niche modeling.

200 We encourage the ecological niche modelling community, as well as journal

201 nvadable areas based on an ensemble of three ecological niche modelling methods, and evaluated the pe

202 ion by intergrating population genetics with ecological niche modelling of Litsea auriculata (Laurace

203 Here, we address this issue for ecological niche modelling or species distribution model

204 found within native House Crow lineages and ecological niche modelling predicts suitable climatic ar

205 least the minimum information necessary for ecological niche modelling reproducibility, offering a s

206 Ecological niche modelling shows a Campanian-to-Maastric

207 We coupled ecological niche modelling with simulations of potential

208 Using ecological niche modelling, we found that the Pacific No

209 distribution analyses, neutrality tests, and ecological niche models (ENM) and suggested the existenc

210 carbon dates of bat fossils with time-scaled ecological niche models (ENM) to study bat extinctions i

211 We examined the hypothesis that ecological niche models (ENMs) more accurately predict s

212 Here we use multilocus data and ecological niche models (ENMs) to test alternative GM mo

213 We combined ecological niche models (ENMs) with population genetic s

214 niche space, we created genetically informed ecological niche models (gENMs) using Populus fremontii

215 Historical range changes based on ecological niche models also failed to explain the obser

216 it has yet to be introduced, we trained 900 ecological niche models and constructed an Ensemble Mode

217 Over-the-edge transplant experiments and ecological niche models are commonly used to address thi

218 erformance of demographic models vs. simpler ecological niche models are still lacking owing to diffi

219 Ecological niche models calibrated with both native and

220 Therefore, ecological niche models can provide a reasonable first a

221 icting range changes at the grid-cell level, ecological niche models do as well, or better, than more

222 endations that should promote more realistic ecological niche models for transfer across space and ti

223 use and dynamic climate variables in simpler ecological niche models improve forecasts of observed ra

224 upled ecological-niche-population models and ecological niche models in predicting documented shifts

225 Ecological niche models supported inference of drastic c

226 ul information for developing predictive and ecological niche models to guide management methods.

227 Using frogs as indicators, ecological niche models under paleoclimates, and simulta

228 Here we build ecological niche models using MAXENT and test whether se

229 savannization." We combined projections from ecological niche models, habitat filter masks and disper

230 s and on future projections of climate-based ecological niche models.

231 Broad ecological niches occupied by South Island giant moa (Di

232 da CRPs are considered in the context of the ecological niches occupied by these bacteria.

233 ago proposed that one could characterize the ecological niche of a species as an abstract mapping of

234 The ecological niche of a species describes the variation in

235 tter ant distribution, thereby expanding the ecological niche of an obligate host-microbe symbiosis.

236 ntal conditions, restricting or altering the ecological niche of asexual lineages.

237 According to one view, the ecological niche of diazotrophs is primarily controlled

238 d fitness via better adaptation to the local ecological niche of each species.

239 CAM in Eulophiinae orchids; characterize the ecological niche of extant taxa; infer divergence times;

240 -based systems, an understanding of the true ecological niche of organisms and the dynamic state of t

241 d forest fragmentation, may have altered the ecological niche of Pteropus species acting as natural H

242 ed from Earth observation data subsuming the ecological niche of the target species.

243 onate-hosted methanotrophy extends the known ecological niche of these important methane consumers an

244 The spatial model showed that the ecological niche of these two flying fox species, the hu

245 Deep shotgun metagenomics unveiled distinct ecological niches of microbes and antibiotic resistance

246 experimental approaches to characterize the ecological niches of species and directly assess the imp

247 The higher specialisation and narrower ecological niches of these plant-fungal interactions in

248 in nutrient-poor environments that are known ecological niches of V. cholerae, including pond water a

249 survival is enhanced by occupying exclusive 'ecological' niches of the body.

250 originating and still occupying the coldest ecological niche on Earth, the Antarctic.

251 ing nematodes, which are found in almost any ecological niche on Earth.

252 , comparing nine species that occupy diverse ecological niches on Santa Cruz island.

253 g emm types either may not be constrained by ecological niches or population immunity to the M protei

254 g a new host species, species invading a new ecological niche, or cancer cells invading a new tissue

255 perate within the constraint of conservative ecological niches, or if niche shifts occur at all commo

256 ties have been shaped, in large part, by the ecological niches our evolutionary ancestors occupied an

257 cement of gymnosperms by angiosperms in many ecological niches over time and the huge disparity in sp

258 ponses to global change incorporate shifting ecological niches, population dynamics, species interact

259 We found that more complex coupled ecological-niche-population models (that account for dis

260 the first comparison of the skill of coupled ecological-niche-population models and ecological niche

261 life stage (with concomitant shifts into new ecological niches) primarily by re-working genetic pathw

262 an therefore lead to the exploitation of new ecological niches, prompting an adaptive radiation of ba

263 mixed layer to tropical coral reefs, and in ecological niches ranging from free-living plankton to s

264 cancer cells from primary tumors to distant ecological niches, rather than the primary tumors, is th

265 Ecological niches reflect not only adaptation to local c

266 its, but how such traits directly affect the ecological niche remains poorly understood.

267 monstrated that microbes inhabiting the same ecological niche share common preferences for synonymous

268 cted spatial range shift and accelerates the ecological niche shift.

269 extinction because of both spatial range and ecological niche shifts.

270 We found that N. obtusa is exploiting novel ecological niche space in its introduced range, which ma

271 k into ever more densely occupied regions of ecological niche space.

272 s) available in the database revealed strong ecological niche specialization within habitats.

273 ther assessed by shape, food, metabolism, or ecological niche-surely rivals (if not exceeds) that of

274 Mucus is a densely populated ecological niche that coats all non-keratinized epitheli

275 of which are important for existence in the ecological niche that the organism occupies.

276 stresses resulting from the wide variety of ecological niches that bacteria inhabit.

277 New ecological niches that may arise due to climate change c

278 g coarse-graining of microbiomes in terms of ecological niches that may be filled.

279 greater the quantitative difference between ecological niches, the greater the importance of reticul

280 range of other bacteria thriving in the same ecological niches, the soil and plant rhizosphere.

281 Ecological niche theory holds that species distributions

282 ing species range shifts in the framework of ecological niche theory may help to direct future resear

283 bits a unique ability to invade and adapt to ecological niches throughout tropical and subtropical re

284 astric mucosa, the bacterium survives in its ecological niche, thus favoring diseases ranging from ch

285 e traits that allow them to exploit distinct ecological niches, thus enabling multiple species to coe

286 l stages of the same animal occupy different ecological niches to avoid competing for food or other e

287 These results suggest a universal way for ecological niches to be populated by abundant microorgan

288 gated versus high-bodied shape, differential ecological niche use and genetic differentiation.

289 Additionally, we compared their ecological niches using eight ecological variables.

290 eathered dinosaurs and Mesozoic birds to new ecological niches was potentiated by rapid diversificati

291 These ecological niches were modeled using boosted regression

292 were active predators that occupied discrete ecological niches while living in the shadow of Tyrannos

293 ynanthropic nonhuman primates (NHP) share an ecological niche with humans, cross-species transmission

294 to data mine and model-predict LP AI and its ecological niche with machine learning and open access d

295 erent CRD1 and EnvB ESTUs occupying distinct ecological niches with regard to iron availability and t

296 tiple spatial scales, functional classes and ecological niches with transfer further enriched among b

297 l microbial population that occupies a broad ecological niche, with selection driving frequencies of

298 g how microbes have evolved to fill specific ecological niches within a host.

299 erial pathogen capable of colonizing diverse ecological niches within its human host.

300 present in samples collected from a range of ecological niches worldwide, including invertebrates and