ライフサイエンスコーパス: invasive species

1 to the source and timing of introduction of invasive species.

2 eing important ornamental but also weedy and invasive species.

3 e shifts can shed light on the management of invasive species.

4 ncrease due to climate-induced expansions of invasive species.

5 on, direct exploitation, climate change, and invasive species.

6 opulation management for both threatened and invasive species.

7 onary processes that modulate the effects of invasive species.

8 competitors on the dietary niche breadths of invasive species.

9 effects on B. tectorum and other nitrophilic invasive species.

10 their trading partners and incumbent pool of invasive species.

11 at influence the establishment and spread of invasive species.

12 ding outside their present range, especially invasive species.

13 ctive asynchrony or the population growth of invasive species.

14 g and prediction of the predatory impacts of invasive species.

15 of disease vectors, agricultural pests, and invasive species.

16 e in insects and weeds, and control damaging invasive species.

17 , SGARs remain a mainstay for eradication of invasive species.

18 found to be important to the success of some invasive species.

19 nd behavior, S. invicta is a more successful invasive species.

20 there are very few process-based models for invasive species.

21 tween TEs, life history and adaptation in an invasive species.

22 periodicity of spread of this potential new invasive species.

23 several trait differences between native and invasive species.

24 are to be made to halt this potential marine invasive species.

25 lowstone cutthroat trout (YCT) and competing invasive species.

26 at symbionts may help to trace the source of invasive species.

27 try has not been examined in more than a few invasive species.

28 n important step in the evolution of asexual invasive species.

29 cognized as one of the world's most damaging invasive species.

30 al reproduction is a trait commonly found in invasive species.

31 ens, representing assembly in the context of invasive species.

32 food webs containing a mixture of native and invasive species.

33 that may aid the success of this widespread invasive species.

34 cluding vector borne disease, crop pests and invasive species.

35 structive as a predator and successful as an invasive species.

36 of global change: the rapid establishment of invasive species.

37 because of the dominance and persistence of invasive species.

38 lization of temperate ecosystems by tropical invasive species.

39 habitat and indirect facilitation of exotic invasive species.

40 environmental (e)DNA detections of rare and invasive species.

41 of the spread and potentially the impacts of invasive species.

42 current low population densities of this new invasive species.

43 aterial shed into the water by imperiled and invasive species.

44 ormation to mitigate the negative effects of invasive species.

45 ecreational fishing, as well as stocking and invasive species.

46 gricultural use, trophic simplification, and invasive species.

47 ecades to efficiently model the dispersal of invasive species.

48 utility for the monitoring of this important invasive species.

49 sure by quagga mussels, a widespread aquatic invasive species.

50 f less-competitive species and the spread of invasive species.

51 id in assessing and mitigating the impact of invasive species.

52 e responses to invasion depend critically on invasive species' abundance and trophic position.

53 A large majority of studies on invasive species address timescales of less than one yea

54 er se is not a pathway by which forest woody invasive species affect North American temperate forest

55 NA (eDNA) can be used for monitoring aquatic invasive species (AIS) such as the American signal crayf

56 toring, including early detection of aquatic invasive species (AIS).

57 e better predictors than the trait values of invasive species alone.

58 Consideration of the biology of invasive species and adaptation of the timing, intensity

59 tries vary in terms of potential threat from invasive species and also their role as potential source

60 o forecast the progress and impacts of alien invasive species and assess potential range-shifting dri

61 roduction, revealing a close linkage between invasive species and carbon dynamics.

62 nteractions for future biological control of invasive species and conservation of native species.

63 vasion success is in high fecundity for both invasive species and demographic compensation for Apetio

64 ns) are bred with characteristics typical of invasive species and environmental weeds.

65 emerging challenges such as climate change, invasive species and habitat alteration, often differ ma

66 mming from climate change, overexploitation, invasive species and habitat degradation often cause an

67 Carcinus maenas is in the top 100 globally invasive species and harbours a wide diversity of pathog

68 estimates of the financial damage caused by invasive species and high estimates of the value of spec

69 icators either increased or decreased due to invasive species and increased due to stocking.

70 standing of intraspecific differentiation in invasive species and its interaction with climate change

71 dioxide enrichment, nitrogen eutrophication, invasive species and land-use changes.

72 ses of humans and managed species, policy on invasive species and parasites of wildlife is fragmented

73 uld be critical for predicting the spread of invasive species and population responses to climate cha

74 bacteria are engineered to communicate with invasive species and potentially prevent human disease.

75 ds are easily adapted for a variety of other invasive species and that such risk maps could be used b

76 In addition, hotspots of invasive species and the most susceptible native species

77 patial distributions and local abundances of invasive species and the potential effect they may have

78 e is expected to increase the performance of invasive species and their community-level impacts.

79 e subsequent establishment of extrabasinal (=invasive) species and may have led to a suppression of s

80 of disease, wildfire, carbon sequestration, invasive species, and biogeochemical cycles.

81 rgoing range expansion, including pathogens, invasive species, and humans.

82 rs such as global emissions, climate change, invasive species, and local geochemistry are likely affe

83 d prey responses to humans, synanthropic and invasive species, and other anthropogenic disturbances.

84 al systems, including issues like fisheries, invasive species, and restoration, as well as others, of

85 , eradication of disease vectors, control of invasive species, and the safe study of emerging biotech

86 igra-considered one of the world's 100 worst invasive species-and that one decade of concerted trophi

87 Invasive species are a key driver of global environmenta

88 Invasive species are a significant threat to global biod

89 Invasive species are a world-wide threat to biodiversity

90 Many invasive species are able to escape from coevolved enemi

91 atives more likely to be invasive, but these invasive species are also evolutionarily closer to nativ

92 Aggressive invasive species are associated with all three groups.

93 Invasive species are believed to spread through a proces

94 rivers such as climate change, land use, and invasive species are changing the nature of fire activit

95 Population sizes of invasive species are commonly characterized by boom-bust

96 Invasive species are expected to cluster on the "high-re

97 Efforts to limit the impact of invasive species are frustrated by the cryptogenic statu

98 While invasive species are most often studied in the context o

99 an three-quarters of taxa listed globally as invasive species are plants.

100 Invasive species are rare in long-established national p

101 Because invasive species are rarely eradicated, and their damage

102 Invasive species are recognized as a significant threat

103 sults indicate that PA loads may increase if invasive species are sufficiently abundant.

104 and use and climate, nitrogen deposition and invasive species are the most important threats to globa

105 rchical model that differentiated native and invasive species as a function of summer growth rate and

106 two host populations though evidence for the invasive species as the source of the outbreak was equiv

107 h ants, which are among the most detrimental invasive species, as they are responsible for declines o

108 hed schemes of existing risk assessments for invasive species assume that a species' information (e.g

109 fe tool for detection and monitoring of this invasive species at ports of entry, and for monitoring t

110 r the effective management of threatened and invasive species because false detections directly affec

111 ng 70% of all termite species) have only two invasive species, because relatively few species have th

112 mpacts on native amphibian populations as an invasive species, bullfrogs play a key role in spreading

113 effective management strategies not only for invasive species but also for assisted colonization unde

114 es in wildlands to greater use of exotic and invasive species by cougars in contemporary urban interf

115 nd altitudinal shifts in the distribution of invasive species by offering more thermally suitable hab

116 Reducing the abundances of invasive species by removals aims to minimize their ecol

117 henotypic traits of surviving individuals of invasive species can affect ecosystem functioning and re

118 Invasive species can be particularly disruptive when the

119 The effects of invasive species can be strongly influenced and potentia

120 Invasive species can cause severe damage in their introd

121 gical forecasts of the extent and impacts of invasive species can inform conservation management deci

122 New England salt marshes and assertions that invasive species can play positive roles outside of thei

123 sland populations respond demographically to invasive species can provide information to mitigate the

124 Eradication of an invasive species can provide significant environmental,

125 Invasive species can quickly transform biological commun

126 lophora glabripennis, a globally significant invasive species capable of inflicting severe feeding da

127 In the worst cases, impacts from invasive species cascade through a community and destabi

128 Invasive species cause considerable ecological and econo

129 ions present challenges to agriculture where invasive species cause significant crop damage and requi

130 The expansion of invasive species challenges our understanding of the pro

131 how the trophic position of this widespread invasive species changes over time as native ant species

132 l environmental changes (e.g., habitat loss, invasive species, climate change) are often overlooked,

133 act values are due mainly to the presence of invasive species, climate change, cropland and pasture a

134 ion interact across a variety of ecosystem - invasive species combinations.

135 ethod for estimating the range of a globally invasive species, common ragweed (Ambrosia artemisiifoli

136 Invasive species continue to proliferate and detrimental

137 vels is not always an effective strategy for invasive species control.

138 ch provide a net economic benefit) for every invasive species correctly identified.

139 Invasive species cost the global economy billions of dol

140 of T-CNCs from the tunicate Styela clava, an invasive species currently causing significant harm to l

141 characterising the genetic structure of the invasive species D. suzukii in Italy.

142 stimates of invasion success from the Global Invasive Species Database as well as the primary literat

143 ion for Conservation of Nature (IUCN) Global Invasive Species Database, which are presented here for

144 eriments containing a population gradient of invasive species densities.

145 monitoring aquatic macrofauna allows the non-invasive species determination and measurement of their

146 future climates; study the distributions of invasive species; discover new species; and simulate inc

147 ish (Gambusia affinis), one of the 100 worst invasive species, disperse further, suggesting a sociabi

148 Global change is likely to affect invasive species distribution, especially at range margi

149 tries may have different susceptibilities to invasive species due to different financial and response

150 dbacks structure plant communities, underlie invasive species dynamics, or reduce agricultural produc

151 y than native species since plasticity helps invasive species establish and spread in new environment

152 Invasive species, expanding human technologies, and glob

153 Invasive species' facilitation, or benefiting, of native

154 indicate significant challenges for SDMs of invasive species far from climate equilibrium.

155 represent the greatest potential sources of invasive species for the rest of the world.

156 seven leaf N pools for five native and five invasive species from Hawaii under low irradiance to mim

157 Preemptive measures to prevent potential invasive species from reaching new habitats are the most

158 stressors, such as atmospheric pollution and invasive species, further weaken trees in some regions.

159 uture predatory impacts of geckos, and other invasive species globally, as temperatures change.

160 tivity, disturbance) and anthropogenic (e.g. invasive species, habitat destruction) ecological driver

161 The successful establishment of invasive species has been shown to depend on aspects of

162 Recent discussion on invasive species has invigorated the debate on strategie

163 Studies focusing on invasive species have been based on plants or animals wh

164 Although mean rates of spread for invasive species have been intensively studied, variance

165 Invasive species have great ecological and economic impa

166 y spatio-temporal metadata enable rapid, non-invasive species identification.

167 l biodiversity, but our understanding of how invasive species impact native communities across space

168 al responses as a tool to predict and assess invasive species impacts incorporating multiple context

169 rate ecosystem services into our analysis of invasive species impacts, management, and public policy.

170 nitrogen (C : N) ratio, explain variation in invasive species' impacts on soil N cycling.

171 e more prevalent in NIS and therefore favour invasive species in aquatic habitats.

172 eed and is listed as one of the top 10 alien invasive species in China.

173 tially address questions about the impact of invasive species in ecological systems and new competito

174 minance trade-off is thought to be broken by invasive species in enemy-free space or territorial spec

175 To better predict population evolution of invasive species in introduced areas it is critical to i

176 Like invasive species in nature, cancer cells at the leading

177 the distributions of species, especially of invasive species in non-native ranges, involves multiple

178 rope and Asia that has emerged as an aquatic invasive species in North America.

179 ased assessment and management of ship-borne invasive species in the Arctic.

180 To date, the most successful marine invasive species in the Atlantic is the lionfish (Pteroi

181 ea lamprey (Petromyzon marinus), a parasitic invasive species in the Laurentian Great Lakes that deci

182 ecause of its population history as an alien invasive species in the UK.

183 tritional quality in Chromolaena odorata (an invasive species in West Africa) and related these attri

184 tial picture of the spread and management of invasive species, in the absence of any other long-term

185 stablished quickly among noncoevolved (e.g., invasive) species, indicating its easy assembly is due t

186 eational, or other factors like stocking and invasive species influence patterns.

187 Invasive species introduced via the ballast water of com

188 The growing problem of invasive species introductions brings considerable econo

189 g the dispersal and establishment of aquatic invasive species is controversial.

190 Effective control of an invasive species is frequently used to infer positive ou

191 in developing gene drive systems to control invasive species is growing, with New Zealand reportedly

192 y across all environments, so the success of invasive species is habitat-dependent.

193 In contrast, the richness of invasive species is high in the more recently designated

194 nvaded ecosystems even when the abundance of invasive species is substantially reduced.

195 y tissue traits, in addition to those of the invasive species, is critical to understanding the impac

196 a large genus that includes polyphagous and invasive species (L. trifolii, L. sativae, and L. huidob

197 d the economic and ecological harm caused by invasive species, linkages between invasions, changes in

198 ncreasing biological and economic impacts of invasive species, little is known about the evolutionary

199 ing evidence for the shared benefits between invasive species management and native biodiversity cons

200 These results could help guide invasive species management in many waterways globally.

201 As this suggests that invasive species management in the UK is vulnerable to a

202 If these results were extended to invasive species management, preserving community divers

203 important implications for conservation and invasive species management.

204 where they can be widely applied to aquatic invasive species management.

205 However, invasive species managers struggle with using eDNA resul

206 Such invasive species may be able to evolve in response to ch

207 This hypothesis predicts that high-resource invasive species may be particularly susceptible to biol

208 ntinuum rather than discrete categories, and invasive species may follow strategies that are underrep

209 In particular, invasive species may have greater behavioural plasticity

210 mates of the economic effects of Great Lakes invasive species may increase considerably if cases of s

211 Invasive species may not exhibit different population dy

212 Invasive species may precipitate evolutionary change in

213 Invasive species may succeed by employing a wide range o

214 s adapted to resource-poor environments, and invasive species may succeed in low-resource environment

215 udies addressing the trophic interactions of invasive species most often focus on their direct effect

216 Halyomorpha halys is a global invasive species, native to Southeast Asia, that is thre

217 Our results show that invasive species not only reduce biodiversity but rapidl

218 potted study, we grew eight native and eight invasive species of annuals commonly found in southern C

219 e efficiencies in 14 native and 18 nonnative invasive species of common genera found in Eastern North

220 Vespa velutina nigrithorax is an invasive species of hornet accidentally introduced into

221 trol of sea lamprey (Petromyzon marinus), an invasive species of the Laurentian Great Lakes.

222 both direct and indirect losses, with alien invasive species often having the most severe ecological

223 The human-mediated spread of exotic and invasive species often leads to unintentional and harmfu

224 While invasive species often threaten biodiversity and human w

225 ings demonstrate the potential impacts of an invasive species on a diverse faunal assemblage across b

226 orldwide, yet knowledge about the impacts of invasive species on bacterial communities remains sparse

227 n order to predict and manage the impacts of invasive species on ecosystems.

228 ate the strength of ecological effects of an invasive species on invaded communities.

229 root traits that differed between native and invasive species, only leaf nitrogen was significantly a

230 Specially, establishing whether invasive species operate within the constraint of conser

231 enturies and ask: Can we fight the spread of invasive species or do we need to develop strategies for

232 Homogenization can be also driven by invasive species or effects of soil eutrophication propa

233 Most invasive species originate from Southeast Asia.

234 ecies in the United States, yet as with many invasive species, our ability to predict, control or und

235 ailable resources on attempting to eradicate invasive species, our findings suggest that in the futur

236 However, the invasive species P. macrodactylus represents an exceptio

237 cess for management treatments to control an invasive species, particularly for moderate, and more fe

238 graphic inference may be applicable to other invasive species, particularly those with extreme and re

239 The management of harmful species, including invasive species, pests, parasites, and diseases, is a m

240 Invasive species pose a major threat to biodiversity on

241 Invasive species pose a major threat to global biodivers

242 Despite knowledge on invasive species' predatory effects, we know little of t

243 Invasive species present a major conservation threat glo

244 Invasive species present significant threats to global a

245 Plants are commonly listed as invasive species, presuming that they cause harm at both

246 Recently, authors have theorized that invasive species prevention is more cost-effective than

247 Invasive species produced 3x fewer ovules/flower and >25

248 (LTS) assay, we test for the presence of two invasive species: quagga (Dreissena bugensis) and zebra

249 lepidopterans to determine the importance of invasive species relative to 15 other recognized endange

250 cognized, the response of carbon dynamics to invasive species remains largely unknown.

251 Invasive species represent a significant threat to globa

252 Invasive species represent promising models to study spe

253 vides lessons for future efforts to mitigate invasive species, restore ecological resilience and sust

254 Adding two invasive species, Ruminococcus gnavus and Clostridium sy

255 logy, behavior, and demography of a damaging invasive species, sea lamprey (Petromyzon marinus), in t

256 To address the global problems caused by invasive species, several studies investigated steps ii

257 All invasive species share three characteristics that togeth

258 In particular, invasive species showed preferential N allocation to met

259 torical CO2 increase in the atmosphere, with invasive species showing the largest increase.

260 ns in soils, enabling for the first time non-invasive species-specific pest monitoring.

261 sessing the risks of aquaculture activities, invasive species spread, and movements of ballast water

262 t contemporary evolution may facilitate this invasive species' spread in this desert ecosystem.

263 ent years, either by natural factors such as invasive species, storms and global change or by direct

264 just trade flow, as has been interpreted in invasive species studies.

265 ted CO2 and warming would strongly influence invasive species success in a semi-arid grassland, as a

266 al controls are inadequate, and the range of invasive species such as Aedes albopictus (Asian Tiger M

267 seems to play a major role in the success of invasive species such as the viburnum leaf beetle.

268 re invaded to a greater extent by non-native invasive species than ectomycorrhizal (ECM) dominant for

269 s and highlight the additional risk posed by invasive species that are highly abundant and can act as

270 ald ash borer (EAB, Agrilus planipennis), an invasive species that causes widespread mortality of ash

271 Islands have double the number of invasive species that continents do, with islands in the

272 k bug Halyomorpha halys (Stal) is a globally invasive species that harbours the primary bacterial sym

273 front of the cane toad (Rhinella marina), an invasive species that has colonized much of northern Aus

274 However, the limited number of invasive species that have been included in decompositio

275 Many invasive species that have been spread through the globa

276 bworm, Hyphantria cunea, a highly successful invasive species that originated in North America, sprea

277 hat fire ants may be representative of other invasive species that would be better described as distu

278 To determine the probable origin of this invasive species, the genetic structure of the populatio

279 spread of organisms governs the dynamics of invasive species, the spread of pathogens, and the shift

280 sed niche shifts in one of the world's worst invasive species: the wild boar Sus scrofa.

281 Invasive species threaten biodiversity globally, and inv

282 Invasive species threaten global biodiversity, food secu

283 investment in the prevention and control of invasive species to better maximize the economic benefit

284 er diversity may also improve the ability of invasive species to establish and subsequently spread in

285 The introduction of invasive species to new locations (that is, biological i

286 th and less conservative water use may allow invasive species to take advantage of both carbon fertil

287 the mainland has led to the arrival of many invasive species to the Galapagos Islands, including nov

288 d (Scardinius erythrophthalmus), which is an invasive species to the Great Lakes.

289 wgrass (C3 ) led to the establishment of the invasive species torpedograss (C4 ) when water was resup

290 tic potential of the orthologs from the less invasive species Treponema denticola and Treponema phage

291 dea that native species generally outperform invasive species under conditions of low resource availa

292 Native to Asia, this invasive species was first discovered in North America i

293 anning, extinction risk, climate refugia and invasive species - we then explore which models best mee

294 de and the direct and indirect effects of an invasive species, we examined the impacts of Norway rats

295 e growth forms and broad taxonomic diversity invasive species were generally more efficient than nati

296 the maternal fitness of a self-incompatible invasive species, wild radish (Raphanus sativus).

297 er mosquito, Aedes albopictus (Skuse), is an invasive species with substantial biting activity, high

298 scales and to determine the trophic roles of invasive species within native ecosystems.

299 commerce has resulted in the spread of urban invasive species worldwide such that various species are

300 implemented to mitigate the damage caused by invasive species worldwide.