ライフサイエンスコーパス: evolutionary biology

1 study of adaption and phylogenetic history (evolutionary biology).

2 are cornerstone relationships in ecology and evolutionary biology.

3 he inheritance and induction modes to animal evolutionary biology.

4 gh species diversity is an important goal in evolutionary biology.

5 hes to resolve long outstanding questions in evolutionary biology.

6 des is one of the most fundamental topics in evolutionary biology.

7 diterranean region is a challenging issue in evolutionary biology.

8 stabilizing selection is still a paradox in evolutionary biology.

9 ecies diversity is a fundamental question in evolutionary biology.

10 potential applications in biotechnology and evolutionary biology.

11 systems are highly debated topics in modern evolutionary biology.

12 ss landscapes is a long-standing question in evolutionary biology.

13 esistance emergence based on principles from evolutionary biology.

14 rapid climate change is a critical goal for evolutionary biology.

15 raits is a central but challenging puzzle in evolutionary biology.

16 ss the ranges of species is a major focus of evolutionary biology.

17 hroughput sequencing to address questions in evolutionary biology.

18 ommonly used in the fields of structural and evolutionary biology.

19 cal adaptation is of fundamental interest in evolutionary biology.

20 in the history of life and a core problem in evolutionary biology.

21 sed to neutral evolution, is a major goal of evolutionary biology.

22 al change remains an important challenge for evolutionary biology.

23 stic networks remains a central challenge in evolutionary biology.

24 f these factors remains a major challenge in evolutionary biology.

25 tant implications for both developmental and evolutionary biology.

26 ation to cooperation is a major challenge in evolutionary biology.

27 essure are intriguing topics in the field of evolutionary biology.

28 ains one of the most important challenges of evolutionary biology.

29 er to aid others is an important question in evolutionary biology.

30 ural populations is of central importance in evolutionary biology.

31 daptive features is a perennial challenge in evolutionary biology.

32 such as stem cell biology, regeneration and evolutionary biology.

33 ary adaptations is a central focus of modern evolutionary biology.

34 isease; and the comparison across species in evolutionary biology.

35 long been one of the outstanding problems of evolutionary biology.

36 yotic tree is a major unresolved question in evolutionary biology.

37 served at the leaves is a problem arising in evolutionary biology.

38 uss the role of proof-of-concept modeling in evolutionary biology.

39 f phenotypic divergence is a central goal in evolutionary biology.

40 Ma, both within and outside of the fields of evolutionary biology.

41 evolutionary processes is a central goal of evolutionary biology.

42 to phenotypic diversity is a central goal in evolutionary biology.

43 enched in the literature, especially outside evolutionary biology.

44 cooperation in nature is a key challenge in evolutionary biology.

45 f wide relevance to developmental, cell, and evolutionary biology.

46 or HI with implications for many branches of evolutionary biology.

47 nt for many other areas of developmental and evolutionary biology.

48 tness map of adaptation is a central goal in evolutionary biology.

49 operation and other fundamental questions in evolutionary biology.

50 idual producers is a long-standing puzzle of evolutionary biology.

51 t into the roles of parasites in ecology and evolutionary biology.

52 ns in functional traits is a central goal of evolutionary biology.

53 ecome a long-discussed issue in the field of evolutionary biology.

54 ence of cooperation is a central question in evolutionary biology.

55 f speciation in courses such as Genetics and Evolutionary Biology.

56 the tree of life remains a key challenge in evolutionary biology.

57 were used to address problems in ecology and evolutionary biology.

58 adaptive phenotypes is a central problem in evolutionary biology.

59 ombination have long been a central theme of evolutionary biology.

60 tant implications for both developmental and evolutionary biology.

61 dow analysis has been extensively applied in evolutionary biology.

62 divergence is a long-standing controversy in evolutionary biology.

63 analysis is increasingly used in ecology and evolutionary biology.

64 ne of the core problems in developmental and evolutionary biology.

65 evolve remain important unsolved puzzles in evolutionary biology.

66 us and debate in the fields of molecular and evolutionary biology.

67 key, and provide guidelines for their use in evolutionary biology.

68 te of phylogenetic analysis tools for use in evolutionary biology.

69 ronmental adaptation is a central problem of evolutionary biology.

70 iological and medical genetics as well as on evolutionary biology.

71 s cooperate remains an important question in evolutionary biology.

72 response to selection dominates the field of evolutionary biology.

73 es diversity among clades is a major goal of evolutionary biology.

74 f cooperation is one of the great puzzles in evolutionary biology.

75 molecules to be analyzed using the tools of evolutionary biology.

76 netic paths remains an important question in evolutionary biology.

77 esearch in mammalian genetics, genomics, and evolutionary biology.

78 ntegrated, as has happened in other areas of evolutionary biology.

79 ndamental, yet largely unresolved, issues in evolutionary biology.

80 are insufficient to establish competency in evolutionary biology.

81 trophic lateral sclerosis and an emphasis on evolutionary biology.

82 Origin of Species could prompt a new look at evolutionary biology.

83 ertilization is one of the oldest puzzles in evolutionary biology.

84 seen as one of the great triumphs of modern evolutionary biology.

85 are long-standing goals of developmental and evolutionary biology.

86 henotype of the LUCA is a major challenge in evolutionary biology.

87 its originate is a foundational challenge in evolutionary biology.

88 es is a key research question in ecology and evolutionary biology.

89 s of adaptive traits is a major challenge in evolutionary biology.

90 olution has been a long-standing question of evolutionary biology.

91 limation evolve remains a major challenge in evolutionary biology.

92 ts across all sub-disciplines in ecology and evolutionary biology.

93 pic variation is one of the central tasks of evolutionary biology.

94 oal at the intersection of developmental and evolutionary biology.

95 of novelty is an active area of research in evolutionary biology.

96 ygote advantage) is a fundamental concept in evolutionary biology.

97 ukaryotes represents an unresolved puzzle in evolutionary biology.

98 origins of novelty are a central interest of evolutionary biology.

99 roduction is a central tenet of genetics and evolutionary biology.

100 otic environmental change is a major goal of evolutionary biology.

101 rchitecture of speciation is a major goal in evolutionary biology.

102 ntially major implications for their broader evolutionary biology.

103 Darwinian fitness is a central concept in evolutionary biology.

104 gulatory variation is a long-standing aim in evolutionary biology.

105 natural selection, was a seminal advance in evolutionary biology.

106 al complexity is an outstanding challenge in evolutionary biology.

107 ation within species has long been a goal of evolutionary biology.

108 estion at the interface of developmental and evolutionary biology [1-3].

109 in darkness is a poorly understood aspect of evolutionary biology [1].

110 iations have long served as model systems in evolutionary biology.(1)(,)(2) However, it has only rece

111 esented one of the "abominable mysteries" in evolutionary biology [2].

112 e traditional provenance of cell biology and evolutionary biology, a comprehensive synthesis of evolu

113 ential to resolve long-standing questions in evolutionary biology about the role of gene exchange in

114 Sex ratio theory, a mainstay of evolutionary biology, accounts for this variation.

115 This integration of molecular and evolutionary biology allows us to understand how the var

116 There is growing recognition in both evolutionary biology and anthropology that dispersal is

117 ese two kinds of causality - the purviews of evolutionary biology and biochemistry, respectively - ar

118 nlocking many of the unresolved questions in evolutionary biology and biogeography.

119 wild mammals is a crucial challenge in both evolutionary biology and biogerontology.

120 to come and the possibility of collaborative evolutionary biology and biophysical efforts.

121 gn host is of fundamental importance in both evolutionary biology and biotechnology, enabling horizon

122 rimental methods for synthetic, systems, and evolutionary biology and broadens access to cutting-edge

123 s spectrum, biogeographical characteristics, evolutionary biology and conservation biology.

124 m marker genotype data in molecular ecology, evolutionary biology and conservation studies.

125 extending beyond immunology and medicine to evolutionary biology and conservation.

126 derstanding this relation is central to both evolutionary biology and developmental genetics.

127 ence of cooperation a fundamental paradox in evolutionary biology and ecology.

128 selection has long been a basic question in evolutionary biology and ecology.

129 which has emerged as a key model organism in evolutionary biology and ecology.

130 fe history strategies is an enduring goal of evolutionary biology and ecology.

131 ranscriptome to two fundamental questions in evolutionary biology and endocrinology.

132 as provided a rich source of information for evolutionary biology and engaged considerable public int

133 ties for addressing fundamental questions in evolutionary biology and for better conserving biodivers

134 mics dataset has become a common practice in evolutionary biology and human genetics.

135 Here we explored the use of deep learning in evolutionary biology and implemented a program, called I

136 bility of evolution is a central question in evolutionary biology and most often addressed in experim

137 In many disciplines, especially in evolutionary biology and oncology, the developmental per

138 tool used to model strategic interactions in evolutionary biology and social science.

139 lying their divergence, is a central goal of evolutionary biology and speciation research.

140 vided detailed and important information for evolutionary biology and taxonomy.

141 n between non-relatives is a puzzle for both evolutionary biology and the social sciences.

142 is fundamental to understanding chemical and evolutionary biology, and for the exploitation of enzyme

143 ution of eusociality is a perennial issue in evolutionary biology, and genomic advances have fueled s

144 wear patterns has advanced our knowledge in evolutionary biology, and has opened up opportunities fo

145 ntial for translational medical genetics and evolutionary biology, and our approach is readily applic

146 ationships between physiology, behaviour and evolutionary biology, and the application of crop protec

147 and preferences is a fundamental problem in evolutionary biology, and the mechanisms remain highly c

148 ation; phylogenetics, molecular studies, and evolutionary biology; and biocontrol.

149 mong the most fundamental questions in viral evolutionary biology are how fast viruses evolve and how

150 oblematic because the comparative methods of evolutionary biology are ill suited to explain unique ev

151 th deep implications for neurophysiology and evolutionary biology, are not grounded on solid evidence

152 hese have implications for developmental and evolutionary biology as well as public policy.

153 s a key parameter in population genetics and evolutionary biology, as it quantifies the expected dist

154 important area of study in developmental and evolutionary biology, as well as ecology.

155 mental question for cell, developmental, and evolutionary biology, as well as for biomedicine.

156 hing contemporary evo devo to the fringes of evolutionary biology because it does not describe the ca

157 a set of DNA sequences is a core problem in evolutionary biology, because this history encodes infor

158 in functions evolve is a central question in evolutionary biology, biochemistry, and biophysics.

159 * Plant population genomics informs evolutionary biology, breeding, conservation and bioener

160 is one of the more distinctive metaphors of evolutionary biology, but no test of its claim that spec

161 epidoptera have long been a favored model in evolutionary biology, but to date descriptions of brain

162 from several groups that have considered how evolutionary biology can be useful in medicine, what phy

163 is for a vast area of research spanning from evolutionary biology, community and functional ecology,

164 a screening strategy that capitalizes on the evolutionary biology concept of neutral drift, and combi

165 One of the longest running debates in evolutionary biology concerns the kind of genetic variat

166 One of the last uncharted territories in evolutionary biology concerns the link with cell biology

167 d misrepresented more than any other idea in evolutionary biology, confusion that continues to the pr

168 It has found important applications in evolutionary biology, conservation and ecology, such as

169 It has important applications in evolutionary biology, conservation genetics and plant an

170 e, innovative and impactful, yet ecology and evolutionary biology continues to be dominated by white

171 ial genomes remains an unsolved challenge in evolutionary biology, despite long-standing debate about

172 or integrating psychology, neuroscience, and evolutionary biology differ from the approach exemplifie

173 f phenotypic change is important for several evolutionary biology disciplines, including phenotypic p

174 lates radical rethinking of key questions in evolutionary biology (e.g., the relations among evolutio

175 se data patterns, a systems biology (SB) and evolutionary biology (EB) approach was evaluated, which

176 A large body of work from evolutionary biology, economics, and ecology has shown t

177 Combining insights from evolutionary biology, economy, and the political and psy

178 Many fundamental questions in evolutionary biology entail estimating rates of lineage

179 nt with modification"--has been the focus of evolutionary biology for 150 years.

180 Rank orders have been studied in evolutionary biology for almost a hundred years.

181 picuous coloration has been a major focus of evolutionary biology for much of the last century.

182 One possible explanation offered by evolutionary biology for survival of deleterious genes i

183 opportunities for testing central tenets of evolutionary biology formulated by Darwin in the Origin

184 Whereas adaptationism, widely accepted in evolutionary biology, gives primacy to extrinsic factors

185 This classic question in evolutionary biology has a deep history and has been stu

186 Ongoing innovation in phylogenetics and evolutionary biology has been accompanied by a prolifera

187 While evolutionary biology has long focused on teasing apart t

188 Physiology and evolutionary biology have developed as two separated dis

189 ng time diversity have enriched the field of evolutionary biology have received less attention despit

190 Anthropologists, borrowing techniques from evolutionary biology, have demonstrated that some common

191 cal explanation for an important question in evolutionary biology: how is community-level Mullerian m

192 Gene flow is an important component in evolutionary biology; however, the role of gene flow in

193 c and phenotypic variation is a key focus of evolutionary biology, human genetics and plant breeding.

194 This rapidly increasing knowledge of the evolutionary biology, immunology, structural biology, an

195 t must involve natural history, ecology, and evolutionary biology in addition to genomics studies tha

196 New applications of evolutionary biology in medicine are being discovered at

197 e the integration of Mendelian genetics into evolutionary biology in the early 20th century, evolutio

198 y advocating a piecemeal toolkit approach to evolutionary biology, in lieu of any grand unified theor

199 These byproducts, known as spandrels in evolutionary biology, include the structural substrate o

200 is involved in several processes central to evolutionary biology including phenotypic plasticity, ev

201 It is relevant to important questions in evolutionary biology, including sympatric speciation, ge

202 Fluid dynamics and evolutionary biology independently provided evidence of

203 By discussing examples from evolutionary biology, intrinsically disordered proteins

204 he origins of cynical, strategic thinking in evolutionary biology, investigate how this illuminated t

205 Our general conclusion is that evolutionary biology is a crucial basic science for medi

206 A major problem in evolutionary biology is explaining the success of mutual

207 Although the vast majority of research in evolutionary biology is focused on adaption, a general t

208 A fundamental question in evolutionary biology is how genetic novelty arises.

209 A major question in evolutionary biology is how mating patterns affect the f

210 A central unresolved issue in evolutionary biology is how metabolic innovations emerge

211 Evolutionary biology is not just another topic vying for

212 A fundamental concept in evolutionary biology is that life tends to become more c

213 One of the outstanding questions in evolutionary biology is the extent to which mutually ben

214 One of the most fundamental questions in evolutionary biology is the origin of the lineage leadin

215 An open question in evolutionary biology is the relationship between standin

216 A contemporary goal in both ecology and evolutionary biology is to develop theory that transcend

217 A major aim of evolutionary biology is to explain the respective roles

218 A major objective for evolutionary biology is to identify regions affected by

219 A challenge for evolutionary biology is to reconcile the diversity of la

220 A central challenge of developmental and evolutionary biology is to understand how anatomy is enc

221 A major challenge in evolutionary biology is to understand how complex traits

222 A major goal of evolutionary biology is to understand how diverging popu

223 A major focus in evolutionary biology is to understand how the evolution

224 An important goal of evolutionary biology is to understand the constraints th

225 An important goal in evolutionary biology is to understand the genetic change

226 Yet a major challenge for evolutionary biology is to understand the role of ecolog

227 A central challenge of developmental and evolutionary biology is to understand the transformation

228 One great remaining problem in evolutionary biology is to understand which common ances

229 A major question in the field of evolutionary biology is to what extent such an adaptive

230 A central challenge in evolutionary biology is understanding how genetic mutati

231 A major question for evolutionary biology is what these diverse systems have

232 One of the major unanswered questions in evolutionary biology is when and how the transition betw

233 A core question in evolutionary biology is whether convergent phenotypic ev

234 ost long-standing and important mysteries in evolutionary biology is why biological diversity is so u

235 One of the great mysteries of evolutionary biology is why closely related lineages acc

236 However, an open, important question in evolutionary biology is why hierarchical organization ev

237 a pathogen and has theoretical importance in evolutionary biology, it is not known whether it ever re

238 Evolutionary biology itself has taken such a turn recent

239 Our results unite two important topics in evolutionary biology: life history and sex allocation.

240 sses, which have been extensively studied in evolutionary biology, limits cancer predictability and d

241 into larger scale population models used in evolutionary biology, macroeconomics, or sociology.

242 his hypothesis has become a powerful tool in evolutionary biology, making it possible to use molecula

243 gely dominated by other disciplines, such as evolutionary biology, mathematics, anthropology, archaeo

244 ects on human health by integrating ecology, evolutionary biology, microbiology, bioinformatics, and

245 iversals, suggesting that a new synthesis of evolutionary biology might become feasible in a not so r

246 scular disease in relation to the well known evolutionary biology model of growth and reproduction tr

247 ions in invasion biology, and in ecology and evolutionary biology more broadly.

248 Like other basic sciences, evolutionary biology needs to be taught both before and

249 Formerly confined to ecology and evolutionary biology, neutral models are spreading.

250 transmission plays an important role in the evolutionary biology of avian influenza viruses-a manife

251 ies, raising interesting questions about the evolutionary biology of music.

252 This review explores the evolutionary biology of peanut and its seed proteins and

253 Further progress in our understanding of the evolutionary biology of stress and mutagenesis will requ

254 Our review focuses on aspects of the evolutionary biology of these fungi that have remained u

255 ory ossicles is one of the central topics in evolutionary biology of vertebrates.

256 l many complex systems, such as in genetics, evolutionary biology or sociology and knowledge of the p

257 ay offer key insight into major questions in evolutionary biology, particularly whether the origins o

258 dvance a wide array of disciplines including evolutionary biology, pathogen surveillance, and biotech

259 We draw on insights from molecular and evolutionary biology perspectives to identify three gene

260 e a subset of the different aspects of plant evolutionary biology, provide a guide for structuring co

261 Applied evolutionary biology provides a suite of strategies to a

262 of the most important natural experiments in evolutionary biology, providing insights into virus adap

263 plained by the canonical approaches found in evolutionary biology, psychology, or economics.

264 k (Gasterosteus aculeatus), a model fish for evolutionary biology reported to have a miRNome larger t

265 evolution, but also to appreciate how modern evolutionary biology research is practiced.

266 haracter matrices to support systematics and evolutionary biology research.

267 currently revolutionizing developmental and evolutionary biology, revealing new cell types and state

268 . G. Simpson, one of the chief architects of evolutionary biology's modern synthesis, proposed that d

269 onalized medicine are underpinned in part by evolutionary biology's Modern Synthesis.

270 In medical school, evolutionary biology should be taught as one of the basi

271 also consistent with research in comparative evolutionary biology showing rapid neocortical expansion

272 It has been a model system in evolutionary biology since Darwin.

273 tive traits has been at the centre of modern evolutionary biology since Fisher; however, evaluating h

274 nce evolution have been central questions in evolutionary biology since the 1960s.

275 Flatfishes have attracted attention in evolutionary biology since the early history of the fiel

276 cal implications of findings in genomics for evolutionary biology since the Modern Synthesis.

277 t the heart of many of the challenges facing evolutionary biology, sociology, economics, and beyond.

278 for addressing a wide range of questions in evolutionary biology, such as those that elucidate histo

279 questions that date back to the beginning of evolutionary biology, such as whether evolution proceeds

280 ness landscapes are a fundamental concept in evolutionary biology that relate the genotype of individ

281 ta to address a long-standing uncertainty in evolutionary biology, the identity of avian wing digits.

282 he use of computational methods derived from evolutionary biology to answer broad-scale questions abo

283 To use insights from evolutionary biology to assess the current evidence for

284 for these and other fundamental questions in evolutionary biology to be addressed at the molecular le

285 models demonstrate the potential of applied evolutionary biology to improve public health and diseas

286 n biology, and its influence has spread from evolutionary biology to other fields including the socia

287 approach addresses one of the major goals of evolutionary biology: to quantify the role of stochastic

288 Endosymbioses, therefore, point evolutionary biology toward an important dimension of ev

289 e unknown, leaving a fundamental question in evolutionary biology unanswered.

290 They also provide insight into the evolutionary biology underlying novel adaptations and ar

291 phy. Fontana, London, 1976) once argued that evolutionary biology was unscientific as its hypotheses

292 to address a long-standing question in plant evolutionary biology: whether or not apparently defensiv

293 A synthesis of grass evolutionary biology with grassland ecosystem science wi

294 llows truly holistic approaches, integrating evolutionary biology with mechanistic molecular biology

295 ic diversity is a long-standing challenge in evolutionary biology, with implications for predicting d

296 ithin populations is a long-standing goal in evolutionary biology, with important implications for co

297 rn study of sexual selection, so students of evolutionary biology would be well advised to revisit hi

298 d populations is fundamental to the study of evolutionary biology, yet it remains an elusive goal, pa

299 to the environment is a central question in evolutionary biology, yet linking detected signatures of

300 ecies' is a key concept for conservation and evolutionary biology, yet the lines between population a