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1 across a period of substantial climatic and environmental change.
2 ecies are a major component of human-induced environmental change.
3 project the response of the Arctic to global environmental change.
4 homogenisation and biodiversity responses to environmental change.
5 ss could underestimate ecological impacts of environmental change.
6 nding of how tropical forests may respond to environmental change.
7 ability to evaluate its response to ongoing environmental change.
8 on, therefore stymying adaptation to further environmental change.
9 ce of migration and body size in the face of environmental change.
10 glaciers on Mars may likewise hold clues to environmental change.
11 ionary dynamics with detailed information on environmental change.
12 rs apparently reduced their vulnerability to environmental change.
13 rocesses that buffer the negative effects of environmental change.
14 o coastal resource managers during a time of environmental change.
15 behavior, which is the primary force driving environmental change.
16 t may provide the benefit of hedging against environmental change.
17 viduals behaviorally mitigate the effects of environmental change.
18 cycling, while also acting as 'sentinels' of environmental change.
19 sential to understand the threats of ongoing environmental change.
20 sociated with a species' ability to adapt to environmental change.
21 MSN pathways, making mice less sensitive to environmental change.
22 o understanding population persistence under environmental change.
23 ochromatin is dynamic and remodelled upon an environmental change.
24 ternative stable states (ASS) in response to environmental change.
25 in learning-rate regulation as a function of environmental change.
26 providing invaluable insights into long-term environmental change.
27 iation or reducing extinction in the face of environmental change.
28 rformance, interactions and vulnerability to environmental change.
29 C reservoir dynamics and global climate and environmental change.
30 as persisted despite phenological shifts and environmental change.
31 ons of CO2 and O3 are key features of global environmental change.
32 orks that we subsequently subjected to rapid environmental change.
33 iates individual and population responses to environmental change.
34 with a lesser direct role of climate-driven environmental change.
35 fective conservation strategies with ongoing environmental change.
36 e responses of mast seeding plants to future environmental change.
37 in sex differences being more likely due to environmental change.
38 apting one's rate of learning to the rate of environmental change.
39 atory diversity', might be more resilient to environmental change.
40 n about how they may be influenced by global environmental change.
41 d contain concomitant records of climate and environmental change.
42 ecies distributions and their dynamics under environmental change.
43 anding of their energetic responses to rapid environmental change.
44 ctions when predicting species' responses to environmental change.
45 diverse ecological settings has responded to environmental change.
46 of terrestrial ecosystems are vulnerable to environmental change.
47 hrough which to understand macrosystem-scale environmental change.
48 em sensitivity to multiple drivers of global environmental change.
49 this major feature of biodiversity to future environmental change.
50 uld both acquire adaptive behavior and track environmental change.
51 how people with ASD represent and respond to environmental change.
52 ng within the context of rapid anthropogenic environmental change.
53 the context of unprecedented human-mediated environmental change.
54 tion and establish resilience in the face of environmental change.
55 ecosystem functioning when subject to future environmental change.
56 nt size exhibit similar plastic responses to environmental change.
57 elping species avoid population decline from environmental change.
58 elowground processes being more sensitive to environmental change.
59 relationships), all in the context of global environmental change.
60 ponses could facilitate future adaptation to environmental change.
61 sensitive cytoskeleton may be susceptible to environmental changes.
62 w vegetation responds to asymmetric seasonal environmental changes.
63 biodiversity responds differently to similar environmental changes.
64 tive on the response of global vegetation to environmental changes.
65 animals adaptively respond to human-induced environmental changes.
66 Saccharomyces cerevisiae datasets related to environmental changes.
67 substrate and ERFVII function in response to environmental changes.
68 heir ranges to keep pace with climate-driven environmental changes.
69 regulating ecosystem-scale GHG responses to environmental changes.
70 tary hormones released in response to annual environmental changes.
71 cted from relationships found under moderate environmental changes.
72 to show different phenotypes in response to environmental changes.
73 omotion but also act as sensors that monitor environmental changes.
74 ymetallic resources and records of long-term environmental changes.
75 ons are dynamic and regulated in response to environmental changes.
76 species' ability to cope with human-induced environmental changes.
77 fundamental biological processes related to environmental changes.
78 m can be expected to promote adaptability to environmental changes.
79 are susceptible to dissociation triggered by environmental changes.
80 as the main forcing for a cascade of abrupt environmental changes.
81 prompt response mechanisms to react to rapid environmental changes.
82 ce would be enhanced with accelerated global environmental changes.
83 ute to the maintenance of homeostasis due to environmental changes.
84 ls use circadian rhythms to anticipate daily environmental changes.
85 lving genetic makeup, and sometimes dramatic environmental changes.
86 the 20th century or with other lifestyle or environmental changes.
87 ssential organelles that adapt to stress and environmental changes.
88 ly, its dynamic nature, and its responses to environmental changes.
89 to predict the response of the ecosystem to environmental changes.
90 asticity that enables organisms to adjust to environmental changes.
91 ines that facilitate microbial adaptation to environmental changes.
92 tems resilient to both internal failures and environmental changes.
93 can increase fitness even in the absence of environmental changes.
94 oevolutionary niches varies as a function of environmental changes.
95 djust their metabolic program in response to environmental changes.
96 xperience is crucial for animals to adapt to environmental changes.
97 y of the latter to physiological signals and environmental changes.
98 to understand the response of ecosystems to environmental changes.
99 multiprotein complexes driven by genomic or environmental changes.
100 rapid evolution of beak shape in response to environmental changes.
101 ta(34)Spyr) necessarily corresponds to local environmental changes.
102 lows plants to anticipate and adapt to daily environmental changes.
103 transcriptional regulation, and response to environmental changes.
104 ed life to evolve under cyclic day and night environmental changes.
105 rs when assessing forest responses to global environmental changes.
106 anisms developed systems to efficiently time environmental changes.
107 at an unprecedented rate due to human-driven environmental changes.
108 ystems that mediate the cellular response to environmental changes.
109 hows heterogeneous avian responses to recent environmental changes.
110 n of photosynthetic apparatus in response to environmental changes.
111 better understanding of species response to environmental changes.
112 chronic effects and interactions with other environmental changes.
114 ty changes should consider coarse-resolution environmental changes, account for differences in baseli
116 ere is very little information about whether environmental changes affect lineage progression during
117 handling characteristics that can respond to environmental changes after inflammation, such as pH cha
118 walnut species were not driven by extrinsic environmental changes alone, and a key role was probably
119 ss landscape, providing a mechanism by which environmental change alters the genetic landscape of mar
120 colour polymorphism acts as a buffer against environmental changes, although further studies are now
121 ue duree Patterning between climate-mediated environmental change and change in human societies has,
122 our ability to predict species responses to environmental change and develop effective conservation
123 study highlights the multifaceted effects of environmental change and fishing pressures in different
124 cting the sensitivity of these ecosystems to environmental change and for designing and evaluating dy
125 n fine-scale community composition following environmental change and for individuals from different
129 other clades where the relationship between environmental change and species richness change can be
130 f niche shifts in mediating the link between environmental change and the evolution of life histories
131 influenced by species-specific responses to environmental change and the scale of change in overstor
132 compensate for the direct adverse effects of environmental change and thereby rescue populations from
133 muli-responsive materials can sense specific environmental changes and adjust their physical properti
134 ts on the adaptation of coccolithogenesis to environmental changes and can be used for the estimation
137 expansions are becoming more frequent due to environmental changes and rare long-distance dispersal,
138 ormed four experiments mimicking 16 types of environmental changes and separated the compositional va
139 l measurement of dynamic cellular states and environmental changes and suggests new applications for
140 pretable results that meaningfully deal with environmental changes and their possible impacts on sens
141 thogen transmission, population responses to environmental change, and communication in natural popul
142 governing ecosystem dynamics may shift with environmental change, and ecosystem state may be decoupl
143 ht of twenty-first century globalization and environmental change, and evaluate national capacities t
144 e moth assemblages are strongly resilient to environmental change, and that they contain a much large
145 -soil interfacial behaviour is influenced by environmental changes, and how the strain distribution a
147 o ecosystem processes and plant responses to environmental change are strongly needed to reduce empir
149 s their responses to nonspecific binding and environmental changes are almost identical, whereby any
152 ct differences in their response to external environmental changes, as well as different sources.
153 rease in the same alleles, likely due to the environmental change associated with European colonizati
157 ed will not only impact their fate following environmental change but potentially also the trajectori
158 e well positioned to regulate learning about environmental change, but more direct evidence for a rol
159 ht to increase fitness and aid adaptation to environmental change, but the underlying mechanisms are
160 living species) has not only survived these environmental changes, but has maintained its distinct s
161 tal role in mitigating the effects of global environmental change by dissipating incident storm wave
162 networks in natural habitats and respond to environmental changes by shifts in the community structu
163 its occurring across periods of climatic and environmental change can cause temporal mismatches betwe
164 s that influence the responses of species to environmental change can help to predict future patterns
165 odified nucleoside and its responsiveness to environmental changes can be used to monitor cleavage in
166 sonally stratified lake to show that gradual environmental changes can induce oxic-anoxic regime shif
167 study of lake sediment cores to reconstruct environmental change) can address many key knowledge gap
168 a developmental time course overlapping with environmental change confounds interpretations as to whe
171 to understand how evolutionary responses to environmental change depend on the identity and number o
173 the origin of Homo lies in understanding how environmental changes disrupted gracile australopith nic
174 function change than the selectivity of the environmental change driver and (3) effects on ecosystem
175 to overlearn about volatility in the face of environmental change drives a corresponding reduction in
180 ave experienced unprecedented ecological and environmental changes, especially after the introduction
181 vulnerability of small island populations to environmental change, even in the absence of human influ
182 My) from one mode to another in response to environmental change, even when restoration of the full
183 ach for predicting the consequences of rapid environmental change for the structure of complex ecolog
184 ovide insights on the consequences of global environmental changes for the long-term persistence of m
185 e dynamics between gas hydrate stability and environmental changes from the height of the last glacia
187 These results support the hypothesis that environmental change has the potential to affect sex dif
190 iron levels are extremely low and subject to environmental change; however, mechanisms regulating iro
191 tal nanoparticles capable of sensing various environmental changes (humidity, gas, the presence of va
193 ation-moisture relationship was resistant to environmental change in field common gardens and field r
194 esults highlight the importance of including environmental change in the ecosystem approach to achiev
195 ern is considered in relation to large scale environmental changes in Africa over the past 300,000 ye
199 The United States (U.S.) has faced major environmental changes in recent decades, including agric
200 younger WGD events that occurred at times of environmental changes in the clade of Buckler mustard (B
202 hese findings demonstrate that anthropogenic environmental changes in urban and agricultural systems,
204 increasingly impacted by multiple drivers of environmental change, including climate warming and loss
205 ties that can shape development and adapt to environmental changes, including antibiotic perturbation
206 g globalization facilitates IAS arrival, and environmental changes, including climate change, facilit
207 These results demonstrate that renal micro-environmental changes induce MSC tropism and could influ
209 is nor the Cretaceous Terrestrial Revolution environmental changes induced immediate changes in diver
210 of soil bacterial communities caused by each environmental change into deterministic and stochastic c
211 e in species richness and biotic and abiotic environmental change is a major goal of evolutionary bio
213 nts, whereas the species' response to global environmental change is likely to follow a shared evolut
214 ons that exist, which will depend on the way environmental change is simulated and the type of experi
215 of the primary ways that organisms cope with environmental change is through regulation of the hypoth
216 nding microbial responses to warming-induced environmental changes is critical to evaluating their in
218 ministic change may become more important as environmental changes last longer, our findings showed t
220 The response of bacterial communities to environmental change may affect local to global nutrient
221 ich fungal-mediated carbon fluxes respond to environmental change may be influenced strongly by speci
224 nzyme amount due to stochastic variations or environmental changes may move the system to the unstabl
225 results suggest a molecular pathway by which environmental changes may rapidly alter responsiveness o
229 t developmental time courses coinciding with environmental changes obscure interpretations regarding
230 t a developmental trajectory coinciding with environmental change obscures origins of stage-dependent
231 asic functionality when errors, failures and environmental changes occur, is a defining property of m
232 og, and promises to provide new insight into environmental changes occurring during the Anthropocene.
233 ients but forecasts of species' responses to environmental change often assume species respond homoge
234 influences of anthropogenic disturbance and environmental change on communities, are key challenges
235 world, the ability to predict the impact of environmental change on ecological communities is essent
236 as been considerable focus on the impacts of environmental change on ecosystem function arising from
237 ibutes are commonly used to infer impacts of environmental change on multiyear species trends, e.g. d
238 erstanding the consequences of anthropogenic environmental change on natural populations throughout h
240 n biogeochemical cycles and of the impact of environmental change on the marine microbial ecosystem.
243 e, still little is known about the impact of environmental changes on an artificial chemical evolving
244 we investigate the recent impact of multiple environmental changes on European farmland birds, here f
246 onary responses of subsequent generations to environmental change, our findings suggest that microbia
247 in identifying tipping points in response to environmental change, our understanding of the ecologica
249 and how pteropods will be affected by global environmental change, particularly ocean acidification.
251 ustralia are scarce, hampering assessment of environmental change preceding and concurrent with human
252 nce migrants is believed to be responsive to environmental changes primarily under exogenous control.
253 ofound effects on the immune system and that environmental changes produce mice with immune systems c
254 derlying statistical regularity that signals environmental change profoundly affects adaptive behavio
255 chers invoke such external factors as sudden environmental change, rapid cognitive or morphological c
257 ogists, but species' functional responses to environmental changes remain an untapped source for the
258 cological communities will respond to global environmental change remains a challenging research prob
259 he mutational events that fuel adaptation to environmental change remains an important challenge for
260 nd predicting microevolutionary responses to environmental change requires unbiased estimation of qua
261 owing body of evidence revealing that global environmental change resulted in a major, temporally sta
262 term response to both single and multidriver environmental change revert after about 450 generations
263 sification are driven primarily by extrinsic environmental changes such as climatic oscillations in t
265 duced wood production, suggesting that other environmental changes such as increased atmospheric CO2
266 critical for bacterial pathogens to survive environmental changes, such as entry into host tissues(1
267 EMENT Animals adjust behavior in response to environmental changes, such as fluctuations in food abun
270 t T. alpinus is generally more responsive to environmental change than T. speciosus, but emphasize th
271 e more likely to trigger catastrophic global environmental change than their flood basalt- and/or dik
272 pecies are also typically more vulnerable to environmental change than their low-elevation counterpar
273 n the circumpolar region is causing dramatic environmental change that is increasing the vulnerabilit
274 a risk for medication-related events and the environmental changes that are possible to improve safe
275 vely), an interesting finding given the many environmental changes that late adolescents are encounte
276 eneral pattern that almost all anthropogenic environmental changes that took place in a grassland eco
277 demographic factors including the nature of environmental change, the carrying capacity of the envir
278 h as the spread of information or disease or environmental changes, then dynamic networks will provid
279 vities prove to be persistent in the face of environmental change, this approach also provides a fram
282 ributions of the many neural, endocrine, and environmental changes to the heightened reward sensitivi
283 olved multiple subclade radiations driven by environmental change toward a pre-existing adaptive opti
285 t the responses of phylogenetic structure to environmental change ultimately depend on how species ha
287 edge are occurring at a time of rapid global environmental change, urbanization, and biodiversity los
288 ity of a widespread ectotherm to anticipated environmental changes, we conducted a mesocosm experimen
289 pressions of Escherichia coli in response to environmental changes, we explore the robustness and ada
290 presence of algal photosymbionts, and global environmental changes, we identify that shared evolution
291 roup diversity but are largely unaffected by environmental changes, whereas extinctions are strongly
292 thropogenic activities in the globe leads to environmental changes, which may affect the loading, tra
293 isfold, depending on particular mutations or environmental changes, which may lead to protein aggrega
294 f the deterministic change across almost all environmental changes, which was robust for both taxonom
295 forts to understand evolution in response to environmental change while developing new hypotheses con
297 ory predicts that strong indirect effects of environmental change will impact communities when niche
298 or ecologists is predicting how human-driven environmental changes will affect the complex pattern of
299 Invasive species are a key driver of global environmental change, with frequently strong negative co
300 systems are among the most exposed to global environmental change, with reported effects on species b
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