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1 redictions of tropical forests' responses to environmental change.
2 ce multiple threats induced by anthropogenic environmental change.
3 ng can dictate the response of ecosystems to environmental change.
4 istorical conditions can persist under rapid environmental change.
5 stablishment are defining features of global environmental change.
6 ith implications for their persistence under environmental change.
7 nto how microalgae will respond to long-term environmental change.
8 risking catastrophic and irreversible global environmental change.
9 and local adaptation of organisms to global environmental change.
10 nd strengthen community resilience to global environmental change.
11 trategies aimed at mitigating the effects of environmental change.
12 e-dependent manner to align with the axis of environmental change.
13 ilding corals is threatened by human-induced environmental change.
14 understanding of biodiversity dynamics under environmental change.
15 and play a key role in ecosystem response to environmental change.
16 ogical communities more generally respond to environmental change.
17 dicting how their populations may respond to environmental change.
18 he sensitivity of POC flux to rapid regional environmental change.
19 maintains temporal synchrony in the face of environmental change.
20 earity in the response of disease vectors to environmental change.
21 e, but are increasingly threatened by global environmental change.
22 t balance is increasingly urgent under rapid environmental change.
23 net C sink or source depends on climate and environmental change.
24 biodiversity during periods of climatic and environmental change.
25 ir hosts, including its capacity to tolerate environmental change.
26 determine whether species can adapt to rapid environmental change.
27 defining accelerated plant adaptation during environmental change.
28 and to quantify plant responses to long-term environmental change.
29 the responses of bird and mammal species to environmental change.
30 lanet facing catastrophic global warming and environmental change.
31 nding the scope for species persistence with environmental change.
32 interactions greatly complicate responses to environmental change.
33 d could have facilitated their adaptation to environmental change.
34 solution and ability to project responses to environmental change.
35 shwater systems are also highly sensitive to environmental change.
36 ions involving APs in response to social and environmental change.
37 cies, trophic interactions and ecosystems to environmental change.
38 ance, they may be particularly vulnerable to environmental change.
39 tic and developmentally plastic responses to environmental change.
40 sights into biodiversity responses to global environmental change.
41 e-environment interactions over any range of environmental change.
42 s' abilities to acclimatize or even adapt to environmental change.
43 tation [3], and tolerance [4-6] during rapid environmental change.
44 nities for the species in the face of future environmental change.
45 important insight into species' response to environmental change.
46 diments, consistent with scenarios of future environmental change.
47 ns generates, and is even central to, global environmental change.
48 dapt harvest to changes in production due to environmental change.
49 of the ocean's nitrogen and carbon cycles to environmental change.
50 olobiont adaptation mechanisms to respond to environmental change.
51 The Arctic is undergoing unprecedented environmental change.
52 variable management success, and disruptive environmental change.
53 ad direction cells, responding in concert to environmental change.
54 ability to anticipate ecosystem responses to environmental change.
55 forecast community responses to rapid global environmental change.
56 hey are threatened worldwide by human-driven environmental change.
57 od to assess the sensitivity of food webs to environmental change.
58 represent an underappreciated consequence of environmental change.
59 to correctly assess vegetation responses to environmental change.
60 tial code updates, or remaps, in response to environmental change.
61 ted the robustness of these relationships to environmental change.
62 y influence species' vulnerability to global environmental change.
63 ovements and determine species' responses to environmental change.
64 er more vital in the context of rapid global environmental change.
65 dict behavioural and population responses to environmental change.
66 molecular level) in the clams' responses to environmental change.
67 exhibiting strong hysteresis in response to environmental change.
68 tious diseases is partially driven by global environmental change.
69 out otherwise hidden impacts of human-caused environmental change.
70 redictor of the species' ability to adapt to environmental change.
71 ations-can influence how organisms cope with environmental change.
72 e plant's ability to systemically respond to environmental changes.
73 onged life history filled with unpredictable environmental changes.
74 bium-driven growth is altered in response to environmental changes.
75 chambers respond to external stimuli such as environmental changes.
76 s governing rapid cytoskeletal adaptation to environmental changes.
77 significantly affected by compositional and environmental changes.
78 of a glycolytic enzyme in plant response to environmental changes.
79 or plant growth, development and response to environmental changes.
80 daptive responses in eukaryotic organisms to environmental changes.
81 nderstanding how plants sense and respond to environmental changes.
82 covery from stalled states and adaptation to environmental changes.
83 predict changes in movements in response to environmental changes.
84 es differ in their response to human-induced environmental changes.
85 response to rapid demographic, economic and environmental changes.
86 nt environment might become maladaptive upon environmental changes.
87 avioral flexibility, the ability to adapt to environmental changes.
88 nd to use them as a resource for documenting environmental changes.
89 thways and coordinates cellular responses to environmental changes.
90 these communities are susceptible to Arctic environmental changes.
91 living at temperate latitudes to anticipate environmental changes.
92 es allowed them to thrive despite historical environmental changes.
93 ental and cell-intrinsic factors to adapt to environmental changes.
94 lowing immunisation and is shaped by age and environmental changes.
95 ial scales even in the face of anthropogenic environmental changes.
96 ria living in complex communities respond to environmental changes.
97 erestimate the whole-system impact of global environmental changes.
98 or decrease in abundance following specific environmental changes.
99 ponses of populations and of biodiversity to environmental changes.
100 pidome that is highly dynamic in response to environmental changes.
101 nts increasing their vulnerability to future environmental changes.
102 unication is crucial for plant adaptation to environmental changes.
103 dapt their lengths and widths in response to environmental changes.
104 f gene expression in bacteria in response to environmental changes.
105 nctional composition, ecosystem function and environmental changes.
106 l community composition in the face of other environmental changes.
107 aphic changes alone, in the absence of other environmental changes.
108 cal gene regulation and can respond to rapid environmental changes.
109 esis-related genes in response to growth and environmental changes.
110 , synchronizing gene expression with diurnal environmental changes.
111 populations can help buffer against harmful environmental changes.
112 s residue in fibril disassembly, among other environmental changes.
113 lant genome evolution is crucial to adapt to environmental changes.
114 lying the capability of species to cope with environmental changes.
115 l flexibility of T(H)17 cells with regard to environmental changes.
116 are unable to detect rapid or unanticipated environmental changes.
117 h are substantially perturbed by dietary and environmental changes.
118 daptations to aquatic environments and other environmental changes.
119 ilitating adaptation to diurnal and seasonal environmental changes.
120 conferring the ability to adapt flexibly to environmental changes.
121 ploring microbial adaptation and response to environmental changes.
122 bility to adapt new functions in response to environmental changes.
123 involving multiple anthropogenic drivers of environmental change acting widely across annual and mig
124 little auk fitness proxies were impacted by environmental changes: Adult body condition and chick gr
127 based explanations for observed responses to environmental changes, along with predictive power gaine
129 l groups) are sensitive indicators of marine environmental change and can provide a simplified view o
133 els is therefore important for understanding environmental change and its impacts on ecosystems.
136 Benefits include flexibility to react to environmental change and the promotion of opportunities
138 s that allow organisms to anticipate regular environmental changes and align their physiology and beh
139 o protein facilitates immediate responses to environmental changes and avoids excess production of pr
141 change for ecosystems depend on the kind of environmental change, and are especially significant whe
142 ant insects in lake ecosystems, sensitive to environmental change, and, because their larval exoskele
143 ur understanding of forest responses to past environmental changes, and improve predictions of future
148 rstand because fine roots respond quickly to environmental change, are responsible for nutrient and w
149 graphical area have the potential to inspire environmental change as citizens come together to collec
150 mitochondrial genes indicated adaptation to environmental change associated with speciation events i
151 d to an astronomical time calibration of the environmental changes associated with the two ocean anox
153 tapped potential in existing laws to address environmental change, both by leveraging adaptive and tr
154 Pollination is known to be sensitive to environmental change but we lack direct estimates of how
155 sting to errors that result from unpredicted environmental changes but ignoring errors that result fr
156 has made substantial progress in addressing environmental change, but emerging environmental problem
157 sformative insights into biotic responses to environmental change, but have seen limited application
158 otherms are hypothesized to be vulnerable to environmental changes, but cascading effects of organism
159 role in the regulation of plant responses to environmental changes, but the specific mechanisms and m
161 trate that polydomous colonies can adjust to environmental changes by altering their social network.
165 vide a novel mechanism to explain how global environmental change can generate contingencies in a fun
169 bundant historical evidence demonstrates how environmental changes can affect social stability and, i
170 ed assessment of organismal vulnerability to environmental changes can become a useful tool to conser
172 Circadian clocks allow organisms to predict environmental changes caused by the rotation of the Eart
173 obial communities were less resistant to the environmental changes caused by urbanization than to tho
174 as a means for organisms to anticipate daily environmental changes, circadian rhythms are also import
175 second messenger system responds to certain environmental changes communicated through the PTS (Ntr)
177 the diurnal or seasonal variability in major environmental change drivers, such as temperature, pH an
178 n conjunction with additional endogenous and environmental changes, drives leukaemic transformation.
179 reptiles, two taxonomic groups sensitive to environmental changes due to their physiological constra
181 r interval indicates long-term global marine environmental changes (e.g., regression, ocean water che
183 .0%), and combinations of available multiple environmental change factors (-14.5%), the extents of wh
184 ntly disturbed]) and in response to multiple environmental change factors (warming, elevated carbon d
185 l for the first time the effects of multiple environmental change factors on terrestrial N fixation a
186 turbance reduced the N fixation responses to environmental change factors, which was associated with
188 low us to better project the consequences of environmental change for the ecology and functioning of
189 ls help us to understand the consequences of environmental changes for biodiversity, but tend to negl
190 nal populations often respond differently to environmental changes; for binary phenotypes, such as ce
191 predict evolution have gained new urgency as environmental changes force species to adapt or risk ext
192 can automatically adjust system operation to environmental changes, has been found in previous studie
193 species will respond to human-induced rapid environmental change (HIREC) may depend upon our underst
194 are one of the most vulnerable ecosystems to environmental change, however, little information is kno
195 f the great auk had not been under threat by environmental change, human hunting alone could have bee
199 investigate whether key potential drivers of environmental change in Scottish mountains (snow lie, el
200 is papua) penguins to nearly 100 y of shared environmental change in the Antarctic Peninsula region u
201 part attributable to ubiquitous and frequent environmental changes in nature, causing nonsynonymous m
206 mpacts of global climate change emanate from environmental changes including temperature elevation, e
207 on are highly regulated to accommodate these environmental changes, including regulation of mRNAs tha
209 the extent to which anthropogenic drivers of environmental change interact to affect biological commu
215 transportation through policy, systems, and environmental change is one of the leading evidence-base
217 response of the arctic ecosystem to ongoing environmental change is stronger than we would predict t
218 oteins to change conformation in response to environmental changes is critical to biological function
221 anisms to adapt their actions in response to environmental changes, is impaired in a number of neurop
222 e migrants-may be particularly vulnerable to environmental change, it is possible that recent anthrop
225 esses in an avian species, and suggests that environmental change may have different outcomes on the
226 pine biotas formed in response to historical environmental change may improve our ability to predict
227 ers of immune defence and help predict where environmental change may most alter infectious disease r
229 munities, higher species turnover or greater environmental change, may ultimately explain these resul
230 to test how animal homeostatic responses to environmental change mediate ecological interactions and
232 over change (LUCC) is an important driver of environmental change, occurring at the same time as, and
233 arios of the driving mechanism of biotic and environmental changes of the late Pliensbachian have ran
236 tial for understanding the impacts of global environmental change on biodiversity and ecosystem funct
238 s of factors when assessing the influence of environmental change on microbial communities and their
241 s are essential to understand the effects of environmental change on the stability of lake communitie
242 ell affinity maturation, we demonstrate that environmental changes on an intermediate timescale can r
243 geese (Branta leucopsis) responded to strong environmental changes on spring-staging areas in Norway.
244 tremely challenging to predict the effect of environmental changes on the dynamics of ecological comm
245 While our understanding of the effect of environmental changes on the survival, growth, and movem
246 individuals can take advantage of cycles of environmental change operating at both short- and long-t
248 e complex phenotypic response of the soil to environmental change, partly due to the absence of predi
249 invoked as a driving mechanism for Ediacaran environmental change, possibly linked with evolutionary
253 odels of vegetation response to rapid global environmental change should incorporate the critically i
256 ey species, which are prone to responding to environmental changes, such as varied sea surface temper
259 dric species was generally more sensitive to environmental change than the anisohydric species was, a
260 fers a more expedient approach to addressing environmental change than waiting for full-scale environ
261 f people into new settlement areas and cause environmental change that promotes the transmission of v
265 esults predict the ecosystem consequences of environmental changes that cause non-random alterations
266 w PDD may be comparatively more sensitive to environmental changes that disadvantage entire plant lin
267 to and are vulnerable to ongoing climate and environmental changes that threaten their sustainability
271 lt organisms may "prime" their offspring for environmental change through a number of genetic and non
272 mechanisms interpreting and signaling these environmental changes to elicit downstream neuroendocrin
273 to conduct solution experiments to delineate environmental changes to specific nucleobases in respons
275 udies to consider multiple aspects of global environmental change together to gain a more complete un
277 . elegans to study how mechanisms that sense environmental changes trigger adaptive responses that en
278 strial ecosystems linked to volcanism-driven environmental change triggered significant biogeochemica
279 both coherent and differential responses to environmental change underscores the importance of targe
280 ossible order-order transitions depending on environmental changes, very promising applications have
281 al frameworks linking community responses to environmental change via traits which correspond to the
283 ecological and anthropogenic forms of urban environmental change, we demonstrate that communities of
284 ether these communities respond similarly to environmental changes, we measured taxonomic and trait-b
285 hallenges is the disappearing record of past environmental change, which can be key to surviving the
286 a is experiencing significant ecological and environmental change, which may facilitate the establish
287 Together, these observations indicate that environmental changes, which are ubiquitous in nature, i
288 n organism to maximise its responsiveness to environmental changes while minimising the diversion of
289 rendered fish communities more sensitive to environmental change, while communities with higher trai
290 ecific trait relationships hold stable under environmental changes, while only their elevations vary.
291 ssible to identify those most susceptible to environmental change, who thus have the most to gain fro
292 re challenged to mechanistically predict how environmental change will impact movement of carbon betw
293 Thus, current trajectories of anthropogenic environmental change will most probably facilitate futur
294 r, a mechanistic understanding of how global environmental changes will affect ecosystems is still la
295 imal migration is critical for assessing how environmental changes will affect highly mobile fauna at
296 munities with different histories respond to environmental change with regard to shifts in elevation
297 ctions, responding to that period's profound environmental changes with loss of distinct lineages and
298 erstanding collective bacterial responses to environmental changes, with implications for the effects
299 ere markedly distinct, and places biotic and environmental change within a longer-term narrative.
300 e the potential of populations to respond to environmental changes, yet adaptive genetic variation is