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1 alogue for extraterrestrial life existing in extreme environments).
2 ided insights into survival strategies in an extreme environment.
3 tes, whose metabolism is responsible for the extreme environment.
4 and 'Desulforudis', persist throughout this extreme environment.
5 es to complete its early life stages in this extreme environment.
6 bacteria-are active and degrade wood in this extreme environment.
7 examine the biogeography of viruses in this extreme environment.
8 ched layers after prolonged exposure to this extreme environment.
9 omere biology for metabolic control under an extreme environment.
10 stments to facilitate thermoregulation in an extreme environment.
11 unexpectedly fast evolution catalyzed by the extreme environment.
12 iomes, at least not for white spruce in this extreme environment.
13 tudy speciation and ecological adaptation in extreme environment.
14 l explanations for how green plants adapt to extreme environments.
15 ded development that helps organisms survive extreme environments.
16 g a genome signature common to each of these extreme environments.
17 cs and chemistry of planetary atmospheres in extreme environments.
18 t enable the organism to adapt and thrive in extreme environments.
19 hnological applications of such materials in extreme environments.
20 greatly from the use of organisms adapted to extreme environments.
21 , Archaea were thought to be synonymous with extreme environments.
22 s to organismal function in nature, often in extreme environments.
23 oring the evolution of enzymatic function in extreme environments.
24 no sex difference in response to exposure to extreme environments.
25 in every conceivable place on Earth, even in extreme environments.
26 a component of microbial communities in non-extreme environments.
27 ures with desired mechanical responses under extreme environments.
28 e thought to contribute to the adaptation to extreme environments.
29 an be beneficial to Cr(2)AlC MAX phase under extreme environments.
30 could unlock the utility of biocatalysis in extreme environments.
31 ransformations occur in many materials under extreme environments.
32 s generated through repeated encounters with extreme environments.
33 that can provide a competitive advantage in extreme environments.
34 biosensor for monitoring microbial growth in extreme environments.
35 we discuss the physicochemical properties of extreme environments.
36 membrane-spanning lipids that enable life in extreme environments.
37 hlighting the phenotypic uniqueness of these extreme environments.
38 show promise as materials for protection in extreme environments.
39 ellular anatomy in shaping plant function in extreme environments.
40 sleep strategies that provide resilience in extreme environments.
41 inually revised by scientific exploration of extreme environments.
42 us quantity and diversity of life in Earth's extreme environments.
43 h stress and electromagnetic interference in extreme environments.
44 animation states allow organisms to survive extreme environments.
45 s are remarkable in their ability to survive extreme environments.
46 has potential genome editing applications in extreme environments.
47 urbations remain unexplored, particularly in extreme environments.
48 and molecular mass growth processes in these extreme environments.
49 e to prepare ring strained cage molecules in extreme environments.
50 ritical temperature for many applications in extreme environments.
51 cids and the unexpected kinetic stability in extreme environments.
52 dynamics, as they exhibit ultrastability in extreme environments.
53 thesis of highly ring-strained transients in extreme environments.
54 ries use a generic metabolic toolkit to face extreme environments.
55 tems and related complex materials evolve in extreme environments.
56 sign of ductile, high-temperature alloys for extreme environments.
57 and accuracy in SiC behavior predictions in extreme environments.
58 ce for understanding microbial adaptation to extreme environments.
59 ing our understanding of human adaptation in extreme environments.
60 ons for space agriculture and agriculture in extreme environments.
61 the understanding of microbial diversity in extreme environments.
62 ing plant lineages to colonize and thrive in extreme environments.
63 aling unique adaptations to their respective extreme environments.
64 essential for the use of these materials in extreme environments.
65 individuals in various clinical settings and extreme environments.
66 into phenotypic plasticity and adaptation to extreme environments.
67 of representative plants growing in Chilean extreme environments.
68 characterized by isolation, confinement, and extreme environments.
69 uring exercise or for individuals working in extreme environments.
70 be responsible for the formation of PAHs in extreme environments.
71 studying strong-field gravity and matter in extreme environments.
72 echnological and engineering applications in extreme environments.
73 a new avenue to study materials behaviour in extreme environments.
74 tic range of peritrichs capable of living in extreme environments.
75 ld relatives and species that are adapted to extreme environments.
76 s, including ones isolated from Earth's most extreme environments.
77 the diversity of eukaryotes living in these extreme environments.
78 rphs, including in conditions encountered in extreme environments.
79 del for the evolution of plant adaptation to extreme environments.
80 olumes and small samples in their natural or extreme environments.
81 ning and anti-fouling materials operating in extreme environments.
82 hat occur at relatively low abundance and in extreme environments.
86 are renowned for their ability to thrive in extreme environments, although they can be found in virt
87 ding of the adaptations of Ostreobium to its extreme environment and an important genomic resource to
89 rstanding of Ostreobium's adaptations to its extreme environment and its roles as a coral holobiont m
90 l ants were physiologically adapted to their extreme environment and whether summer heat or winter co
93 ion mechanisms of main-group XIV elements in extreme environments and affords deeper insights into fu
94 our understanding of methanogen survival in extreme environments and confers continued consideration
95 rials for survivability of oxygen sensors at extreme environments and demonstrated rapid response in
96 id-solid physicochemical interactions within extreme environments and extends our understanding of mo
97 hinnest coating ever shown to withstand such extreme environments and find applications as chemically
98 that can operate in and survive exposure to extreme environments and harsh chemicals such as fuel.
99 ize data from over 80 studies of protists in extreme environments and identify focal lineages that ar
101 ominance of nematodes in Mono Lake and other extreme environments and our findings of preadaptation t
102 glaciers exposes nutrient-poor substrates in extreme environments and provides a unique opportunity t
104 to develop functional multilayer coating for extreme environments and temperature applications but re
105 he study of metal homeostasis, adaptation to extreme environments and the evolution of naturally sele
107 , enhance our understanding of adaptation to extreme environments and will enable the utilization of
110 olic homeostasis maintenance for survival in extreme environments, and provides potential targets for
111 teral gene transfer to adjust the genome for extreme environments, and providing insight into the evo
112 ution of Metazoa, the biology of survival in extreme environments, and the role of horizontal gene tr
113 many case groups that thrive in sediments of extreme environments; and (iii) the molecular and isotop
118 NA repair machineries, organisms thriving in extreme environments are expected to have developed effi
119 remarkable adaptive strategies of insects to extreme environments are linked to the biochemical compo
123 more stable than graphite at the nanoscale, extreme environments are typically used to produce nanod
126 damage and control a material's response in extreme environments, as well as overcome strength-ducti
128 m different habitats, such as waters, soils, extreme environments, bioreactors, and human microbiomes
129 anism, relatives of which have been found in extreme environments but not reported before in humans.
130 example, NEM switches perform much better in extreme environments--but semiconductor switches benefit
132 powder-based 3D printing, powder metallurgy, extreme environment coatings, particle categorization, a
134 viruses infecting archaea living in the most extreme environments continue to show a remarkable diver
135 eveal characteristics relevant to life in an extreme environment distinguished by hypersalinity and h
136 gh temperature ceramics, which can withstand extreme environments exceeding 2000 degrees C in oxidizi
137 ave isolated unusual methanotrophs from such extreme environments, expanding the known functional and
138 logical monitoring, warehouse management and extreme environment exploration, to an individual consum
141 n a wide range of material phases due to the extreme environments found in space and are ideal candid
142 rganisms have adapted to survive a myriad of extreme environments from the earth's deserts to its pol
143 expanding our knowledge and understanding of extreme environments from which the early solar system e
145 on exobiology and the potential for life in extreme environments has generated a great deal of inter
146 multitude of archaea and bacteria inhabiting extreme environments has only become evident during the
148 ing and live imaging of archaeal cells under extreme environments, have underpinned a better understa
149 nel can be more accurately modeled under the extreme environments important for many geophysics and e
152 with performance meeting the requirements of extreme environments in nuclear reactors has been long p
154 track the progress of metallic materials for extreme environments in the past 35 years using the text
155 pin-down ages of pulsars or as probes of the extreme environments in which low-mass white dwarfs form
156 one-dwelling microbes are often resistant to extreme environments including exposure to desiccation,
157 ese communities to effectively adapt to this extreme environment, including the impact of giant earth
159 of organisms have been discovered inhabiting extreme environments, including temperatures in excess o
160 enetic signature and adaptation in different extreme environments, including the cold polar region, a
161 nuclear fusion reactions due to the coupled extreme environments, including the high thermal loads,
162 se predominantly microorganisms that inhabit extreme environments, inhospitable to most Eucarya and B
164 ors and whether the repeated colonization of extreme environments is facilitated by predictable and r
165 The need for improved functionalities in extreme environments is fuelling interest in high-entrop
166 Assessing the energy costs of development in extreme environments is important for understanding how
168 anding the response of ceramics operating in extreme environments is of interest for a variety of app
170 and mechanical stability of coiled coils in extreme environments is the sequence of events leading t
172 urrent pursuits for further exploration into extreme environments like aerospace, outer space, and Ar
173 have become essential for remote sensing in extreme environments like Antarctica, but detecting moss
174 The thermophilic alga C. merolae thrives in extreme environments (low pH and temperature between 40
175 of yeast stress granules is an adaptation to extreme environments, made possible by the presence of a
181 es in plants struggling for existence in the extreme environments of Chile, such as the Atacama Deser
185 the suggestion spurred interest in habitable extreme environments on Earth and throughout the Solar S
186 ls, and nuclides, and the search for life in extreme environments on Earth as well as on Mars and oth
187 birth and neonatal health in one of the most extreme environments on Earth, the Tibetan Plateau.
193 markable ability of liverworts to survive in extreme environments on land, and their discovery calls
194 olved complex strategies for adapting to the extreme environments on QTP and provide novel insights i
195 it opposite poles of the Earth, and dominate extreme environments over specialised local species.
199 hypotheses are organized around relevance to extreme environments, population ecology, and community
200 think of extremophiles, organisms adapted to extreme environments, prokaryotes come to mind first.
203 predictive model of phenotypic responses in extreme environments relative to the median environment.
206 ecies pools within regions suggests that the extreme environments select for species with specific tr
207 in this almost organic-carbon free multiple extreme environment showed variable numbers with up to 1
208 ly, but under intense selective pressures of extreme environments some existing structures or behavio
210 Traits that allow species to survive in extreme environments such as hot-arid deserts have indep
212 imple hydrocarbons play significant roles in extreme environments such as the interstellar medium and
213 tains reliable biometric assessment, even in extreme environments such as underwater or at various te
214 roteins from organisms that originated in an extreme environment, such as hyperthermophilic archaea (
215 de insights into potential life in even more extreme environments, such as Mars, as well as offering
216 dvanced structural materials that can endure extreme environments, such as severe neutron irradiation
217 that correlate with increased persistence in extreme environments, such as spaceflight, to include an
218 a foundation for examining life processes in extreme environments, such as the environment beneath th
220 ity of genomic mechanisms for dormancy in an extreme environment that challenges easy definitions - t
222 titive sequence representation between these extreme environments that may be related to genome funct
224 t allowed it to rapidly colonize a series of extreme environments that were apparently untouched by i
225 t equal, which may provide insights into the extreme environments that were encountered by our ancien
227 heir enzymes from, and their utilization in, extreme environments, the manipulation, alteration, and
228 dynamics and the occurrence of life in these extreme environments, the reasons behind the exceptional
229 intaining cell shape, and protecting against extreme environments to acting as a cell surface display
230 y, a group of Crenarchaeota that grow in non-extreme environments was found to be sufficiently diverg
231 ucidate how capsids maintain stability in an extreme environment, we use cryoelectron microscopy to d
232 beetles and other invertebrates inhabit this extreme environment when conditions become more favourab
233 ved functionality and have been proposed for extreme environments where the interfaces are expected t
234 e bacterial endophyte communities in Chilean extreme environments, where Bacillaceae and Enterobacter
235 is vital to the operation of electronics in extreme environments, where systems capable of high-rate
236 can survive, and potential live, within this extreme environment, which has implications for understa
237 in the Central Andes of Northern Chile is an extreme environment with high UV radiation, wide tempera
238 desert mosses in the world and thrives in an extreme environment with multiple but limited water reso
239 s tend to be excluded from climatically more extreme environments with a shorter growing season.
240 rtoire of bacteria and viruses in these poly-extreme environments with freezing temperatures, high ul
241 au (QTP) has the highest biodiversity for an extreme environment worldwide, and provides an ideal nat