ライフサイエンスコーパス: key to understanding

1 ormations of water at the molecular level is key to understanding a variety of multiphase processes r

2 It is key to understanding a variety of spin-transport and top

3 lved in prostate gland development which are key to understanding abnormal growth processes associate

4 Knowledge of HLA-bound peptides is thus key to understanding adaptive immunity and to the develo

5 ts demonstrate that colonisation pressure is key to understanding alien species richness, show that a

6 o-Feshbach resonances (FFR) that have become key to understanding and controlling interactions-in ult

7 nerating dopaminergic neurons alone hold the key to understanding and curing PD.

8 The study of chromatin and its regulators is key to understanding and manipulating transcription.

9 tructures and interactions with CCR5 will be key to understanding and optimizing HIV inhibition.

10 ance and resulting demographic structure, is key to understanding and predicting population dynamics

11 that construction and maintenance costs are key to understanding animal architecture.

12 of antibody epitopes at the residue level is key to understanding antigen resistance mutations, desig

13 This result is key to understanding attentional selection in complex (n

14 cules become functional autoantigens holds a key to understanding autoimmune diseases.

15 ue to dosage compensation are discussed as a key to understanding avenues for potential treatment.

16 for this destabilization is likely to be the key to understanding base discrimination.

17 h organisms compete for limited resources is key to understanding behavioural and social evolution.

18 nderstanding the origins of oak diversity is key to understanding biodiversity of northern temperate

19 ms that switch competition to cooperation is key to understanding biological organization.

20 lationship between information and energy is key to understanding biological systems.

21 results to suggest that spiking dynamics are key to understanding biological visual object recognitio

22 We conclude that host plant quality is key to understanding both epidemic persistence and the s

23 Resolving this conflict is key to understanding both last glacial ecosystems and ex

24 at regulate the number of beta-cells will be key to understanding both the pathogenesis of diabetes a

25 SPL tyrosine and serine residues provides a key to understanding both.

26 nary studies of wild primates hold important keys to understanding both the shared characteristics of

27 function of different neuronal cell types is key to understanding brain function.

28 of AAV with its cellular receptor, AAVR, are key to understanding cell-entry and trafficking with the

29 vidual cells and in whole populations is the key to understanding cellular differentiation, organisma

30 ecules such as proteins and nucleic acids is key to understanding cellular life on the molecular scal

31 detailed understanding of PPIs is therefore key to understanding cellular physiology and can yield a

32 Understanding cellular structure is key to understanding cellular regulation.

33 The key to understanding chaotic mixing is to identify two t

34 use of native and synthetic redox probes is key to understanding charge transport mechanisms and to

35 Key to understanding colour reception in Drosophila is i

36 Such techniques could hold the key to understanding complex biological systems such as

37 These properties are regarded as key to understanding cooperation in mutualistic networks

38 The key to understanding cooperation lies in understanding t

39 fast evolution of microstructural defects is key to understanding "crackling" phenomena during the de

40 how varying exposure and transmission may be key to understanding disease dynamics in the threatened

41 te respiratory coronavirus 2 (SARS-CoV-2) is key to understanding disease pathogenesis, but few studi

42 o capture spatial and temporal data that are key to understanding disease progression.

43 s regulating corticostriatal transmission is key to understanding DLS-associated circuit function, be

44 rmal barrier coatings in operation holds the key to understanding durability of jet engine turbine bl

45 ment, and that cell-mediated immunity is the key to understanding E. coli vaccine-induced protection

46 ding circadian control of gene expression is key to understanding eukaryotic, including fungal, physi

47 ion and exceptional genomic potential is the key to understanding explosive adaptive radiation.

48 We propose that one potential key to understanding floral scent variation in this hype

49 of kinetic traps along the folding route is key to understanding folding kinetics under crowded cond

50 the folding of simple proteins may hold the key to understanding folding pathways and aid in structu

51 nal structures in DNA sequences may hold the key to understanding functional and evolutionary aspects

52 ional regulation in this genus, which may be key to understanding fundamental aspects of its parasito

53 rs that control chromatin fiber structure is key to understanding fundamental chromosomal processes.

54 post-translational modifications (hPTMs) is key to understanding fundamental epigenetic regulatory p

55 upt oxidative balance, have been proposed as key to understanding fundamental life-history trade-offs

56 Such tremor may hold the key to understanding fundamental processes at the deep r

57 dentification of TF binding sites (TFBSs) is key to understanding gene expression and whole regulator

58 e reverse genetic resources, which have been key to understanding gene function in diploid model orga

59 or break new blood vessel connections is the key to understanding guided vascular patterning.

60 ingerprint of environmental adversity may be key to understanding health and disease, as it encompass

61 The ultrafast evolution of microstructure is key to understanding high-pressure and strain-rate pheno

62 aising the hope that this anomaly could be a key to understanding high-temperature superconductivity.

63 Evolutionary responses to nutrition are key to understanding host shifts and the resulting poten

64 ribute to population growth rate (lambda) is key to understanding how animal populations will respond

65 of proteins at native mineral interfaces is key to understanding how biological systems regulate the

66 arose with respect to non-avian dinosaurs is key to understanding how birds achieved their remarkable

67 ally resolving GPCR transduction pathways is key to understanding how cell signaling occurs.

68 nascent macromolecular synthesis in vivo is key to understanding how cells and tissues progress thro

69 that affect co-regulated groups of genes: a key to understanding how cellular pathways and processes

70 ts for efficient oxygen (O(2)) activation is key to understanding how enzymes maintain efficacy and m

71 daptive evolution among different species is key to understanding how evolution works.

72 the genetic basis of expression variation is key to understanding how expression regulation evolves.

73 Neural systems implicated in reward could be key to understanding how food advertising drives food in

74 Mapping their distribution is key to understanding how his paintings have changed with

75 ral dynamics of S. enterica interactions are key to understanding how immunity acts on these infectio

76 l arrest and heterotypic buffering, that are key to understanding how pathological phase transitions

77 play of divergent selection and gene flow is key to understanding how populations adapt to local envi

78 ion in response to different environments is key to understanding how populations evolve.

79 on responds to the presence of oxygen is the key to understanding how sickling proceeds in a physiolo

80 tin-like modifier (SUMO)-binding proteins is key to understanding how SUMOylation regulates cellular

81 of human viruses, rather than recipients, is key to understanding how the bidirectional nature of the

82 Its exact enzymatic function is key to understanding how the cell regulates the response

83 hyperacute window after trauma may hold the key to understanding how the genomic storm is initiated

84 hat mediate distinct astrocyte functions, is key to understanding how the nervous system operates in

85 Yet answering this question is key to understanding how the spindle generates and respo

86 resolution lineage information is a critical key to understanding how the states of gene regulatory n

87 ductivity and growth in forest ecosystems is key to understanding how these ecosystems will respond t

88 Key to understanding how these factors combine to shape

89 ry ATM function(s) for tissue homeostasis is key to understanding how these functions contribute to t

90 g of faces, comparative studies may hold the key to understanding how these parallel circuits emerged

91 The key to understanding how this unique bacterium evades ho

92 Local structure and symmetry are keys to understanding how a material is formed and the p

93 relationships among different cell types is key to understanding human brain development.

94 ent archives from Beirut, Sidon and Tyre are key to understanding human impacts in harbour areas beca

95 How this feat is managed is key to understanding immunological tolerance and interve

96 Linking synaptic connectivity to dynamics is key to understanding information processing in neocortex

97 tochondrial metabolic response to hypoxia is key to understanding ischemia tolerance in the myocardiu

98 Determination of an exoplanet's mass is a key to understanding its basic properties, including its

99 s environment by altering gene expression is key to understanding its ecology.

100 ations for a particular computation is often key to understanding its function.

101 a protein during its biological activity is key to understanding its mechanism.

102 the human brain and that of other mammals is key to understanding its unique computational power.

103 -lymphopoiesis remains poorly defined, it is key to understanding leukemia initiation in early life.

104 Direct in vivo imaging of lymph flow is key to understanding lymphatic system function in normal

105 ng to oxygen cycles inside Earth, which hold key to understanding major geological events that impact

106 folding is a fundamental process in biology, key to understanding many human diseases.

107 gnition system but also how it may provide a key to understanding mechanisms for higher cognitive fun

108 ible immune competent preclinical models are key to understanding mechanisms of action, interactions

109 enetic distance and ecological similarity is key to understanding mechanisms of community assembly, a

110 Hemisphere during the Younger Dryas (YD) is key to understanding mechanisms of millennial climate ch

111 cting the physiology of extinct organisms is key to understanding mechanisms of selective extinction

112 t evolution of hepatitis C virus (HCV) holds keys to understanding mechanisms responsible for the est

113 on, in ordered membrane domains (rafts) is a key to understanding membrane domain function, it is imp

114 face hydrophobic interactions in proteins is key to understanding molecular recognition, biological f

115 mmetry breaking and shape transformations is key to understanding morphogenesis.

116 control interplays between these tissues is key to understanding morphogenetic evolution.

117 These may be a key to understanding motor development, motor learning,

118 a), a major nocturnal predator, provided the key to understanding MsCYP6B46's function: spiders clear

119 Key to understanding multimodal computations is determin

120 progenitor cells (OPCs) into mature OLGs are key to understanding myelination and remyelination.

121 with a complex and ever-changing world is a key to understanding natural behavior.

122 epare secretory vesicles (SVs) for fusion is key to understanding neuronal and hormonal communication

123 myriad of dynamic environmental signals, is key to understanding normal and pathological blood vesse

124 Grid integration studies are key to understanding our ability to integrate variable g

125 Therefore, changes in ice stream flow are key to understanding paleoclimate, sea level changes, an

126 and virology of animal influenza viruses is key to understanding pandemic risk and informing prepare

127 bowel disease (IBD) susceptibility genes is key to understanding pathogenic mechanisms.

128 Biomedical events are key to understanding physiological processes and disease

129 characterizing their population dynamics is key to understanding plant genome complexity.

130 nt unstable modes dynamically evolve remains key to understanding plasma behavior and control.

131 ucts, residual upgrading, and complexity are key to understanding possible future changes in refinery

132 action, secretion, and hepatic extraction is key to understanding postprandial glucose metabolism in

133 ome interactions, position, and stability is key to understanding processes that require access to DN

134 We hypothesized that a key to understanding PVL's action on host cells and, pos

135 re disturbance, human agency, and climate is key to understanding rapid population declines of fire-s

136 ts leading to osteosarcoma, and is therefore key to understanding RB1 as a target in malignancy.

137 standing secondary cell wall architecture is key to understanding recalcitrance i.e. identifying feat

138 ying the determinants of RIN4 degradation is key to understanding RESISTANT TO P.

139 A key to understanding RNA function is to uncover its comp

140 It follows that the key to understanding spindle morphogenesis will be to el

141 These findings are key to understanding squamous epithelial homeostasis and

142 the range of physiological values (6.5-7) is key to understanding structure-function relationships of

143 at different stages of thymic development is key to understanding T-cell selection.

144 A key to understanding the 2D metallic state is the metal-

145 ly linking movement behaviors and ecology is key to understanding the adaptive evolution of locomotio

146 A precise quantification of this map is key to understanding the anatomical relationships betwee

147 These findings are key to understanding the biological functions of modifie

148 CTCs hold the key to understanding the biology of metastasis and provi

149 embrane dynamics and cortex contractility is key to understanding the biomechanical control of cell m

150 Perturbation of neuronal activity is key to understanding the brain's functional properties,

151 eference distribution are unclear but may be key to understanding the causal role of M1 in limb contr

152 that regulate osteoclast activity provides a key to understanding the causes of these diseases and de

153 s to the generation of force and movement is key to understanding the cellular roles that these motor

154 (CaM) emphasize that inherent flexibility is key to understanding the complex conformational changes

155 Dissecting tumor heterogeneity is a key to understanding the complex mechanisms underlying d

156 overexposure in mass stranded cetaceans as a key to understanding the complex processes and implicati

157 r-soluble species from asphaltene samples is key to understanding the contribution of photochemically

158 uman disease and animal models of disease is key to understanding the contributory role of the lympha

159 changes in body orientation during turns is key to understanding the control strategies used in avia

160 These features are key to understanding the core biophysical constraints on

161 n important role in galaxy evolution and are key to understanding the correlation between central-bla

162 ggests that secondary structure may hold the key to understanding the determinants of this modificati

163 arance of modern humans in a given region is key to understanding the dispersal process and the repla

164 A key to understanding the dynamics of the phosphoproteome

165 Plant population responses are key to understanding the effects of threats such as clim

166 he fate of second-generation RO2 radicals is key to understanding the efficient SOA formation and the

167 hat the quantum dynamics of carbon nuclei is key to understanding the electronic and optical properti

168 ral investigation of fibrosis to provide one key to understanding the electrophysiological/clinical a

169 Because the atmosphere is key to understanding the environmental behavior of volat

170 rs into higher-order structures is therefore key to understanding the epigenetic regulation of DNA ac

171 cellular hallmarks of normal ageing might be key to understanding the events that convert normal agei

172 nd has revealed several features that may be key to understanding the evolution and function of the e

173 ng the challenges faced by social animals is key to understanding the evolution of cognition.

174 g cryptic innovations on the tree of life is key to understanding the evolution of complex traits, in

175 history strategies of microbial symbionts is key to understanding the evolution of cooperation with h

176 ification among the more than 70 lineages is key to understanding the evolution of eukaryotes.

177 standing their evolutionary relationships is key to understanding the evolution of life.

178 gulation of ovarian apoptosis could hold the key to understanding the evolution of midlife fertility

179 Our study indicates that the key to understanding the evolution of the tentorium is i

180 sms by which functional adaptation occurs is key to understanding the evolution of this important pro

181 cursor reactivities were elucidated and were key to understanding the final reaction conditions.

182 cies of both the recent and ancient past are key to understanding the forces shaping global patterns

183 of new branches from preexisting ones is the key to understanding the formation of tubular systems.

184 Key to understanding the function of effectors is the id

185 proteins and their associated glycans is the key to understanding the function of glycoproteins in bi

186 of cellular and molecular structural data is key to understanding the function of macromolecular asse

187 mprovements to earth system models will be a key to understanding the future of forests and their fee

188 ic mutations from cancer genome sequences is key to understanding the genetic basis of disease progre

189 role of turbulence in the early nebula is a key to understanding the growth of solids larger than me

190 Timing and magnitude of surface uplift are key to understanding the impact of crustal deformation a

191 ons, and conservation, as presented here, is key to understanding the impact of mutations in evolutio

192 How muscles are used is a key to understanding the internal driving of fish swimmi

193 This differential interaction is key to understanding the kinetics of epitope proofreadin

194 EMO's critical role in IKK activation, and a key to understanding the link between cytokine-receptor

195 Clarifying this relationship is key to understanding the long-term effects of head impac

196 pool, constraining sources of marine DBC is key to understanding the long-term persistence of carbon

197 itecture of functionally important traits is key to understanding the maintenance of reproductive bar

198 Key to understanding the mechanisms of pathogenesis is t

199 he complex between Ric8A and Galpha hold the key to understanding the mechanisms underlying noncanoni

200 minent motor and cognitive abnormalities, is key to understanding the mechanisms underlying the HD be

201 teraction with the cytoskeletal filament are key to understanding the mechanochemistry of molecular m

202 icle argues that developmental processes are key to understanding the mirror neuron system, yet negle

203 The genomes of non-bilaterian metazoans are key to understanding the molecular basis of early animal

204 progress through the ATP hydrolysis cycle is key to understanding the molecular basis of their mechan

205 ons within the overall multimeric complex is key to understanding the molecular mechanisms of macromo

206 lation events to kinases and phosphatases is key to understanding the molecular organization and sign

207 work-level interaction among genes, which is key to understanding the molecular perturbations in canc

208 the factors that determine such switches is key to understanding the movement of these groups.

209 ntigenic characterizations of swine IAVs are key to understanding the natural history of these viruse

210 terpretation of these measurements holds the key to understanding the nature of DO events.

211 re dynamics of ultraviscous liquids hold the key to understanding the nature of glass transition and

212 l neural representation of the self may be a key to understanding the nature of such impairments.

213 ed and how acoustic signals are perceived is key to understanding the neurobiology of social behavior

214 xyl species and the formation of hydride are key to understanding the observed behaviour.

215 shows that alternative--top-down--routes are key to understanding the organic inventory in space.

216 A key to understanding the origin and evolution of the hum

217 lant groups to evolve stomata, hornworts are key to understanding the origin and function of stomata.

218 An implication of our study is that the key to understanding the origin of Homo lies in understa

219 mic structures of small gold clusters is the key to understanding the origin of metallic bonds and th

220 Key to understanding the origin of wings will be knowled

221 digrades are meiofaunal ecdysozoans that are key to understanding the origins of Arthropoda.

222 anding how anxiety affects generalization is key to understanding the overgeneralization experienced

223 Thus, the key to understanding the pathogenesis of chronic lung di

224 Tissue and cellular tropism is one key to understanding the pathogenesis of SARS-CoV-2.

225 ll biology of ferroportin and its mutants is key to understanding the pathogenesis of this increasing

226 on of the early events in amyloidogenesis is key to understanding the pathology of, and developing th

227 combination with genetic factors, holds the key to understanding the phenotypic diversity seen in AD

228 thylated 2-4 times before it is destroyed is key to understanding the possibility of a methyl group d

229 Nevertheless, TS8 is key to understanding the potential energy surface; there

230 ate of an individual ('deep phenotyping') is key to understanding the prevention, initiation, progres

231 at pattern and maintain dendritic arbors are key to understanding the principles that govern nervous

232 wo HSV membrane proteins, gE/gI and US9, are key to understanding the processes by which viral glycop

233 ip between protein sequence and structure is key to understanding the protein universe.

234 Resolving this issue is key to understanding the proximal cause of the warming,

235 lar profiles of a tumour during treatment is key to understanding the recurrence mechanisms and devel

236 influence the self-association of IF(1) is a key to understanding the regulation of its inhibitory pr

237 Transcriptomes are key to understanding the relationship between genotype a

238 Here we show that the key to understanding the resilience of online hate lies

239 effects between plants and microclimates are key to understanding the response of forest biodiversity

240 are critical to cell differentiation and are key to understanding the role of epigenetics in complex

241 The key to understanding the role of genes in disease relate

242 The PP1c-binding proteins are therefore the key to understanding the role of PP1 in particular biolo

243 f ALS-associated TDP-43 mutations may be the key to understanding the role of TDP-43 in neurodegenera

244 energy scale of intermolecular binding - are key to understanding the self-assembly of those systems.

245 t the aggregate's geometry during sorting is key to understanding the sorting dynamics and explains t

246 Key to understanding the structural-catalytic synergy is

247 antibiotic exposure(3-7), which may hold the key to understanding the structure and functions of the

248 function of leukocyte E-selectin ligands is key to understanding the tempo and specificity of immuno

249 The concept of bifurcation could be the key to understanding the threshold between these two sta

250 itable land and marriage opportunities), are key to understanding the timing of out-migration.

251 The specific nature of life events is key to understanding the timing of suicidal behavior.

252 pact of specific quenchers on DOM could be a key to understanding the true formation potential for re

253 Solving how this network is regulated is key to understanding the underlying mechanisms of tumor

254 nd use of carbon in biomineral formation are key to understanding the vulnerability of shellfish aqua

255 inforcement associated with addiction is the key to understanding the vulnerability to the transition

256 t and that their interdependence could offer keys to understanding the complex regulatory mechanisms

257 reactive dissolution processes that will be key to understanding their behaviors and interpreting bi

258 Defining substrate-binding sites of sHSPs is key to understanding their cellular functions and to har

259 , and resolving the drivers of aerosol pH is key to understanding their environmental effects.

260 However, this is key to understanding their etiology and designing studie

261 nd thus the identification of Ubl targets is key to understanding their function.

262 cation and dynamics of RNAs in live cells is key to understanding their function.

263 sequences in specific methylation states, a key to understanding their functions.

264 isualizing their conformational dynamics are key to understanding their functions.

265 Obtaining their structures is the key to understanding their interaction details.

266 nnections within cortical networks, which is key to understanding their operational regime and the co

267 e modifications and transcription factors is key to understanding their regulatory and developmental

268 oprid) to this decline is controversial, and key to understanding their risk is whether the astonishi

269 ncRNA expression across cells and tissues is key to understanding their role in determining phenotype

270 Knowledge of their community dynamics is key to understanding their role in marine food webs and

271 cation of nucleosomes along the chromatin is key to understanding their role in the regulation of gen

272 nal analysis of protein structure and may be key to understanding their utility for different problem

273 bolically model complex networked systems is key to understanding them, an open problem in many disci

274 Key to understanding these bipartite networks are the ne

275 hrough which DELLAs regulate GA responses is key to understanding these responses from a mechanistic

276 The key to understanding these structures is the interplay b

277 The key to understanding this counterintuitive result for fr

278 eome changes over the course of infection is key to understanding this host-virus interplay.

279 The key to understanding this is in how ecology itself has e

280 The key to understanding this phenomenon lies in the system'

281 ster groups of all other winged insects, are key to understanding this radiation.

282 cross other cognitive domains and provides a key to understanding time-resolved interactions between

283 he mammalian genome is structured in vivo is key to understanding transcriptional regulation.

284 ted characteristic of prion variants that is key to understanding transitions between prion states.

285 these submicroscopic infections is therefore key to understanding transmission dynamics and successfu

286 that intratumor heterogeneity likely is the key to understanding treatment failure.

287 rocesses that limit recruitment may hold the key to understanding tropical tree diversity.

288 produced in humans versus cell lines may be key to understanding vaccine failure and developing bett

289 standing interspecific viral transmission is key to understanding viral ecology and evolution, diseas

290 A key to understanding visual cognition is to determine wh

291 differentiates between object categories is key to understanding visual cognition.

292 to other members of the FGF family may prove key to understanding vulnerability or resilience in affe

293 e regulation of cardiac lipid kinases may be key to understanding when and how cardiac ion transporte

294 mies, suggesting that genetic relatedness is key to understanding when the suppression of individual

295 dolescents, unmarried and rural poor women), key to understanding whether FP progress is equitable.

296 ates the boundaries of phase co-existence is key to understanding whether LLPS is an equilibrium or i

297 Their discovery is key to understanding whether supermassive black holes ca

298 A key to understanding why signaling depends on ligand end

299 ross-linking of collagen changes with age is key to understanding why the mechanical properties of ti

300 Deciphering bacterial spread is key to understanding Y. pestis and the immune responses