ライフサイエンスコーパス: biochemical reaction

1 (e.g., some enzymes are involved in multiple biochemical reactions).

2 ime, shedding light on this canonical fungal biochemical reaction.

3 nzymes show the ability to catalyze the same biochemical reaction.

4 idate to produce the enzyme involved in this biochemical reaction.

5 nd timescale during the transient phase of a biochemical reaction.

6 ologs suggest that they catalyze a different biochemical reaction.

7 nnected muscles that are powered by inherent biochemical reactions.

8 roton transfer is critical in many important biochemical reactions.

9 e metabolites are substrate/product of known biochemical reactions.

10 sm depends on the throughput of food to fuel biochemical reactions.

11 it can accelerate or decelerate the rate of biochemical reactions.

12 they are crucial in various enzyme catalyzed biochemical reactions.

13 es are noisy due to the stochastic nature of biochemical reactions.

14 zed as an important cofactor in a variety of biochemical reactions.

15 in mechanistic investigation of chemical and biochemical reactions.

16 dent roles of phase separation in regulating biochemical reactions.

17 cellular circuitry that represents a set of biochemical reactions.

18 bability equation of networks of chemical or biochemical reactions.

19 to precisely quantify the effect of force on biochemical reactions.

20 ction for biomolecules, leading to efficient biochemical reactions.

21 n important participant in a wide variety of biochemical reactions.

22 ynthesis can be modeled as large networks of biochemical reactions.

23 lly distinct substrates and catalyze diverse biochemical reactions.

24 s a comprehensive resource of expert-curated biochemical reactions.

25 but contain an otherwise random set of known biochemical reactions.

26 impacted our understanding of many types of biochemical reactions.

27 ucleic acid synthesis, and a multiplicity of biochemical reactions.

28 ential cofactor involved in various cellular biochemical reactions.

29 f iron makes it an ideal cofactor in diverse biochemical reactions.

30 between spindle forces and local kinetochore biochemical reactions.

31 d for even-higher-throughput measurements of biochemical reactions.

32 to offer more functionality in catalytic and biochemical reactions.

33 lting solely from membrane force-constrained biochemical reactions.

34 tial part of understanding the mechanisms of biochemical reactions.

35 DNA molecules have been selected to catalyze biochemical reactions.

36 existing in enzymes are extremely active in biochemical reactions.

37 of previous LTP but rather involves separate biochemical reactions.

38 , included essential transport processes and biochemical reactions.

39 ions such as binding to DNA and catalysis of biochemical reactions.

40 ted set of metabolites to perform all of the biochemical reactions.

41 naling networks that are governed by similar biochemical reactions.

42 a designable substrate for the regulation of biochemical reactions.

43 important source of control in this class of biochemical reactions.

44 els that arise from the stochastic nature of biochemical reactions.

45 and is required for several hundred diverse biochemical reactions.

46 te the noise and randomness underlying their biochemical reactions.

47 lutions and to precisely control chemical or biochemical reactions.

48 n sufficient water to serve as a solvent for biochemical reactions.

49 abolite concentrations and thermodynamics of biochemical reactions.

50 icular to carry out time-resolved studies of biochemical reactions.

51 ng a role for molecular reach in controlling biochemical reactions.

52 without detailed knowledge of the underlying biochemical reactions.

53 g that membrane curvature itself can trigger biochemical reactions.

54 sical way of visualizing a linked cascade of biochemical reactions.

55 ork to investigate information processing in biochemical reactions.

56 ffording sequential and spatial control over biochemical reactions.

57 stent description of collective behaviors in biochemical reactions.

58 w accurate, quantitative ITC measurements of biochemical reactions.

59 al ATP production and numerous intracellular biochemical reactions.

60 changes of intracellular space can influence biochemical reactions, allowing cells to sense their siz

61 UMCR1 also had biochemical reactions and a ribotype pattern typical of

62 being responsible for efficiently directing biochemical reactions and biological energy transport.

63 the inherent stochasticity of intracellular biochemical reactions and cell growth.

64 widely-applicable theory on the influence of biochemical reactions and cellular growth on the phenoty

65 e been used as individual vessels to perform biochemical reactions and confine the products.

66 ot only for the micromixing but also for the biochemical reactions and detections.

67 with protons and hydroxide ions, facilitate biochemical reactions and establish the electrochemical

68 s, very little is known about the underlying biochemical reactions and genes involved in the biotrans

69 lds, enzymes, and compartments for essential biochemical reactions and icosahedral virus capsids, whi

70 omponents into membraneless organelles tunes biochemical reactions and improves cellular fitness duri

71 et of walK kinase and phosphatase mutants in biochemical reactions and in cells.

72 pply of reduced nicotine amide cofactors for biochemical reactions and in modulating the redox state

73 Epigenetics comprises the umbrella of biochemical reactions and mechanisms, such as DNA methyl

74 ave traditionally been described in terms of biochemical reactions and metabolites.

75 has been studied at the levels of individual biochemical reactions and organism physiology (e.g. basa

76 built by calibrating or delaying the rate of biochemical reactions and processes.

77 he coarse-grained description for a chain of biochemical reactions and show that the coarse-grained a

78 bolism, cell signaling, biopolymer assembly, biochemical reactions and stress granule responses to ce

79 Despite the fact that both the biochemical reactions and the underlying genetics are we

80 es are excellent at downscaling chemical and biochemical reactions and thereby can make reactions fas

81 Key aspects of biochemical reactions and transport processes within cel

82 First, transcription is modeled as a set of biochemical reactions, and a linear system model with cl

83 encoded complex networks of enzyme-catalyzed biochemical reactions, and the constraints they experien

84 de by processes associated with cell growth, biochemical reactions, and their control.

85 phoryl transfer plays a central role in many biochemical reactions, and this is one of the most studi

86 ed on gram staining, colony characteristics, biochemical reactions, and whole-cell fatty acid analysi

87 rporating species diffusion, fluid flow, and biochemical reactions are compared with published data f

88 Biochemical reactions are intrinsically stochastic, lead

89 Many important intracellular biochemical reactions are modulated by transition metals

90 In vitro biochemical reactions are most often studied in dilute s

91 Biochemical reactions are then measured directly by dete

92 Kinetic studies of biochemical reactions are typically carried out in a dil

93 fications reflect the occurrence of chemical/biochemical reactions arising from degradation processes

94 EGSs participate in this biochemical reaction as the data presented here show.

95 demonstrates the effectiveness of modulating biochemical reactions as a ROS source to exert cancer de

96 Thus, Cas1 casposases carry out similar biochemical reactions as the CRISPR Cas1-Cas2 complex bu

97 The generality of the biochemical reaction, as well as the easy substitution o

98 cal movement of the chromosome and the local biochemical reactions at the attached kinetochore region

99 Enzymes speed up biochemical reactions at the core of life by as much as

100 te challenging and often limits the possible biochemical reactions available for investigation.

101 Since statins inhibit many biochemical reactions besides cholesterol synthesis, we

102 alkalinize cytosol, which would affect many biochemical reactions beyond actin depolymerization.

103 positories via a single search, and includes biochemical reactions, biological pathways, small molecu

104 res the accurate specification of four sets: biochemical reactions, biomass metabolites, nutrients an

105 ofreading mechanisms increase specificity in biochemical reactions by allowing for the dissociation o

106 (SyPaB) is the implementation of complicated biochemical reactions by in vitro assembling a number of

107 athway is a coherent set of enzyme catalysed biochemical reactions by which a living organism transfo

108 binding proteins, signaling mechanisms, and biochemical reactions can be computationally organized i

109 The progress of irreversible chemical and biochemical reactions can be followed by hyperpolarized

110 mics--in which photoproducts of chemical and biochemical reactions can be influenced by creating suit

111 RIS), we found that buffers commonly used in biochemical reactions can remove silicon dioxide, a mate

112 c chromophores, as well as dyes generated in biochemical reactions, can be extracted, concentrated, a

113 shing a materials metric for the kinetics of biochemical reaction cascades.

114 d L-alanine, thus demonstrating the proposed biochemical reaction catalyzed by AruH.

115 To identify the biochemical reaction catalyzed by tafazzin, we expressed

116 metalloenzymes involves a complex series of biochemical reactions catalyzed by a plethora of accesso

117 tein is precisely controlled by two opposing biochemical reactions catalyzed by protein kinases and p

118 mic, DDX-controlled compartments establishes biochemical reaction centres that provide cells with spa

119 Pathways include biochemical reactions, complex assembly, transport and c

120 and mechanistic error, which occurs because biochemical reactions comprising the signaling mechanism

121 h by simultaneous imaging of two independent biochemical reaction conditions in a laminar flow device

122 Single-molecule imaging and manipulation of biochemical reactions continues to reveal numerous biolo

123 n (12)C(16)O(16)O and H2(18)O of an in vitro biochemical reaction controlled by erythrocytes CA and e

124 echanically sensitive proteins) on the local biochemical reactions controlling the KMT plus-end dynam

125 ncodes proteins that regulate three distinct biochemical reactions critical for Rab GTPase membrane c

126 The cascade of biochemical reactions culminated in pH changes controlle

127 nsitive selection of biologically meaningful biochemical reaction databases as Dirichlet-categorical

128 w reasonably well understood in terms of the biochemical reactions defining this water-saving mode of

129 changes and reaction patterns for all known biochemical reactions derived from atom-atom mapping acr

130 and non-redundant resource of expert-curated biochemical reactions described using species from the C

131 and non-redundant resource of expert-curated biochemical reactions designed for the functional annota

132 It remains an open question how biochemical reactions developed without the confinement

133 Here we present a simple two-component biochemical reaction-diffusion model based on relaxation

134 so implicate a clay hydrogel environment for biochemical reactions during early life evolution.

135 n of TF assembly and disassembly and various biochemical reactions during transcription of a single-c

136 ty in the assignment of predicted enzymes to biochemical reactions (e.g., some enzymes are involved i

137 how stochasticity propagates from individual biochemical reaction events in the bacterial innate immu

138 DUF1338-containing enzymes catalyze the same biochemical reaction, exerting the same physiological fu

139 Also, since formaldehyde is the byproduct of biochemical reactions for detecting creatinine and creat

140 nFinder, a C library for retrieving specific biochemical reactions from the curated systems biology m

141 redox reactions and cellular energy mediate biochemical reactions fundamental to the functioning of

142 Such biochemical reactions have become more important with th

143 The steady-state kinetic parameters for both biochemical reactions have been determined.

144 ion schemes based on organic, inorganic, and biochemical reactions have been developed, but their rob

145 Bond Changes (BCs) and Reaction Centres from biochemical reactions helps us understand the chemical c

146 te the steady-state fluxes of the underlying biochemical reactions; however, the regulatory mechanism

147 y evaluate the relative importance of linked biochemical reactions important for c-MET activation.

148 ctive, scheme that enables micromixing and a biochemical reaction in a single microfluidic chamber wi

149 As a consequence, every biochemical reaction in the cytoplasm has an associated

150 Phosphate's central role in most biochemical reactions in a living organism requires care

151 ATP is the source of energy for numerous biochemical reactions in all organisms.

152 ction involves automatic extraction of known biochemical reactions in Arabidopsis for both primary an

153 rganization that is required for controlling biochemical reactions in cells.

154 electrons, via cytochrome b5, for a range of biochemical reactions in cellular metabolism, including

155 reconstruction involves extraction of known biochemical reactions in D. rerio for both primary and s

156 e spatial and temporal regulation of complex biochemical reactions in eukaryotes.

157 overdose causes a multitude of interrelated biochemical reactions in hepatocytes including the forma

158 icroscopy now allows quantitative probing of biochemical reactions in living cells.

159 archaea and some eubacteria in a variety of biochemical reactions in methanogenesis, the formation o

160 Micromixing is a crucial step for biochemical reactions in microfluidic networks.

161 g and forming peptidyl bonds are fundamental biochemical reactions in protein chemistry.

162 nal proton transport along 'wires' that feed biochemical reactions in proteins is poorly understood.

163 These metabolites represented biochemical reactions in the (1) methionine cycle (choli

164 Many crucial biochemical reactions in the cell require not only enzym

165 which is not a reactant or a product of the biochemical reactions in the pathway.

166 ing has been shown to modify the kinetics of biochemical reactions in vitro; however, the effects of

167 e of droplets-in-air, allowing us to perform biochemical reactions, including DNA melting and detecti

168 termediate generated during various cellular biochemical reactions, including glycolysis.

169 ntilevers, which directly translate specific biochemical reactions into micromechanical motion, have

170 Stochasticity inherent to biochemical reactions (intrinsic noise) and variability

171 metabolic state of cancer cells, since most biochemical reactions involve transfer of nitrogen.

172 tudies have elicited a deep understanding of biochemical reactions involved in BCAA catabolism.

173 It consists of (i) a kinetic description of biochemical reactions involved in intracellular signalin

174 A special class of biochemical reactions involves a set of enzymes that gen

175 the mechanism of regulation of this complex biochemical reaction is incomplete.

176 Calorimetric detection of biochemical reactions is demonstrated as an extension of

177 The contribution made by biochemical reactions is expressed in variance generated

178 tegrated and interacting genes, proteins and biochemical reactions is unlikely to be realized in the

179 ymes is defined as their ability to catalyze biochemical reactions; it is manually classified by the

180 tudies of diffusion, molecular transport and biochemical reaction kinetics, and regulation of biomole

181 omplexes effect some of the most challenging biochemical reactions known, including hydrocarbon and w

182 -ketoacids undergo a wide range of efficient biochemical reactions leading to an array of industriall

183 to access the usually hidden information in biochemical reactions like intermediate products, time-d

184 ession levels of key enzymatic regulators of biochemical reactions linked to transmethylation and pol

185 s) are involved in a variety of chemical and biochemical reactions, making a more thorough understand

186 ir reactants and thus affect the kinetics of biochemical reactions, making in vivo reactions consider

187 ar bioenergetics and is consumed by numerous biochemical reactions, making it essential for most spec

188 On the level of individual biochemical reactions, many hundreds of metabolic isoenz

189 date were similar in growth characteristics, biochemical reactions, matrix-assisted laser desorption

190 echanical activation pathways and subsequent biochemical reactions may be measured in a dynamic and h

191 gins of a particular sample to the traces of biochemical reaction mechanisms.

192 of cell-like compartments for encapsulating biochemical reactions, nanostructured environments for f

193 itches and the orthogonal T7 RNA polymerase, biochemical reactions needed for in vivo biofluorination

194 stable proteins could engage in many of the biochemical reactions needed for living systems without

195 We present In silico Biochemical Reaction Network Analysis (IBRENA), a softwa

196 ential systems, which form the basis of many biochemical reaction network descriptions in systems bio

197 umerical equation-free methods to a detailed biochemical reaction network model, and show that it can

198 gh continued efforts to reconstruct the full biochemical reaction network that constitutes yeast meta

199 its autoxidation products have an extensive biochemical reaction network that includes reactions wit

200 s can be automatically processed to define a biochemical reaction network, the network implied by a s

201 n and tracing of stable isotopes through the biochemical reaction network.

202 Biochemical reaction networks (BRNs) in a cell frequentl

203 work showing the versatility of programmable biochemical reaction networks (BRNs) in analytical and d

204 e encoding and propagation of information by biochemical reaction networks and the relationship of su

205 Biochemical reaction networks are subjected to large flu

206 or of biological systems is realized through biochemical reaction networks capable of having two or m

207 pproach are to construct dynamical models of biochemical reaction networks for large datasets and com

208 revalent in nature, spanning all scales from biochemical reaction networks in single cells to food we

209 CASIN can convert ODE-based MATLAB models of biochemical reaction networks into the SBML format.

210 In vitro compartmentalization of biochemical reaction networks is a crucial step towards

211 subtle, quantitative differences between the biochemical reaction networks of target cell and host, a

212 e evolution of molecular species involved in biochemical reaction networks often arises from complex

213 Biochemical reaction networks tend to exhibit behaviour

214 cally assembled into a reconstruction of the biochemical reaction networks that underlie E. coli's fu

215 ity of the QSSA in stochastic simulations of biochemical reaction networks with disparate timescales.

216 The realization of artificial biochemical reaction networks with unique functionality

217 ation is shown on polynomial ODE systems for biochemical reaction networks, gene regulatory networks,

218 In biochemical reaction networks, many reactants may take p

219 lation, testing and reduction of theoretical biochemical reaction networks, the program can also be u

220 chastic analysis and simulation of models of biochemical reaction networks.

221 ing from flux balance analysis of multiscale biochemical reaction networks.

222 menon widely observed in nature including in biochemical reaction networks.

223 behavior that might be resident in important biochemical reaction networks.

224 discovery process in the case of stochastic biochemical reaction networks.

225 t on the sources and propagation of noise in biochemical reaction networks; in particular, we are abl

226 The approach is applicable to any biochemical reaction not in chemical equilibrium, includ

227 resents the first demonstration of real-time biochemical reactions observed via single molecule fluor

228 To promote the biochemical reactions of life, cells can compartmentaliz

229 curately captures the dynamics of underlying biochemical reactions only so long as it is applied unde

230 methanol or formaldehyde as end products of biochemical reactions or in environmental samples.

231 Because ambient temperature affects biochemical reactions, organisms living in extreme tempe

232 In aqueous solution, many biochemical reaction pathways involve reaction of an ald

233 of mineral surfaces in mimicking aspects of biochemical reaction pathways.

234 colate) that must be recycled by a series of biochemical reactions (photorespiratory metabolism).

235 mice and humans the circadian rhythm of many biochemical reactions, physiology, and behavior is gener

236 se that arises from the stochastic nature of biochemical reactions propagates through active regulato

237 this study indicate that UT accelerates the biochemical reaction rate, as evidenced by the increases

238 Molecular crowding modifies biochemical reaction rates and decreases macromolecule d

239 In vivo biochemical reaction rates and equilibria might differ s

240 Changes in temperature affect biochemical reaction rates and, consequently, neural pro

241 Living cells maintain a steady state of biochemical reaction rates by exchanging energy and matt

242 the direct response coefficients in terms of biochemical reaction rates, and clarify the potential an

243 Cells are packed at a density that maximizes biochemical reaction rates.

244 ether the retinoid cycle (i.e. the series of biochemical reactions required for vision through contin

245 Mechanistic understanding of biochemical reactions requires structural and kinetic ch

246 The behavior of biochemical reactions requiring repeated enzymatic subst

247 kinases (RTKs) modulates a system of linked biochemical reactions, sharply switching the RTK from a

248 ogy depends on knowledge of the rates of the biochemical reactions, so it is regrettable that few cel

249 These enzymes can perform similar biochemical reactions such as fork reversal; however, ge

250 Complex networks of biochemical reactions, such as intracellular protein sig

251 esents a powerful tool for the monitoring of biochemical reactions, such as protein-protein interacti

252 otein-protein interactions, with complicated biochemical reactions-such as nucleosome modifications-b

253 ain mesoscopic, weakly nonlinear (quadratic) biochemical reaction systems in a small volume, however,

254 study any enzyme-substrate systems, or other biochemical reaction systems in low concentration ranges

255 For cellular biochemical reaction systems where the numbers of molecu

256 We apply this approach to biochemical reaction systems, finding that the identifie

257 nd self-assembling spatial organization with biochemical reaction systems.

258 cantly simplify micromixing and a subsequent biochemical reaction that involves reagent heating in mi

259 A biochemical reaction that recapitulates the first half o

260 theory is general and can be applied to any biochemical reaction that shows an FHDC.

261 The same biochemical reactions that are required for viability on

262 tion of the rates of the many interconnected biochemical reactions that constitute plant metabolic ne

263 eukaryotic cells is to gain insight into the biochemical reactions that control cell fate and state.

264 forces at the cell surface membrane and the biochemical reactions that control the actin cytoskeleto

265 interactions is vital for understanding the biochemical reactions that drive cellular processes.

266 ic pathways can be described in principle by biochemical reactions that explicitly take into account

267 prising wealth of previously uncharacterized biochemical reactions that have potential applications i

268 technique for monitoring kinetics of various biochemical reactions that involve the generation of hyd

269 e Kennedy pathway involves highly endergonic biochemical reactions that must be fine-tuned with energ

270 This cycle consists of sequential biochemical reactions that occur in photoreceptor cells

271 es, I became fascinated with enzymes and the biochemical reactions that they catalyze.

272 his design to trigger organic, inorganic and biochemical reactions that undergo reversible, repeatabl

273 ery mitotic chromosome that enables specific biochemical reactions that underlie properties, such as

274 Enzymes are catalysts in biochemical reactions that, by definition, increase rate

275 C1) metabolism, and internalizes CO2 via two biochemical reactions: the reversed pyruvate:ferredoxin

276 erstanding of one of life's most fundamental biochemical reactions: the translation of a messenger RN

277 The main biochemical reactions thereby included enzymatic transfo

278 inc metal which can act as a mediator during biochemical reactions, this material has been used as a

279 photosynthesis or to compartmentalize other biochemical reactions to confer new capabilities on tran

280 This system allows kinetochore biochemical reactions to control and coordinate chromoso

281 plantable biofuel cell controlled by complex biochemical reactions to deliver power on-demand respond

282 abolism fuels all of life's activities, from biochemical reactions to ecological interactions.

283 one, even at concentrations high enough for biochemical reactions to proceed at normal rates.

284 replace robotic automation by miniaturizing biochemical reactions to the droplet scale.

285 rol cell shape during spreading, whereas the biochemical reactions underlying actin cytoskeleton dyna

286 als of similar age and the complexity of the biochemical reactions underlying haemostasis.

287 Although the biochemical reactions underlying positive control are re

288 glycosylation pathway, and then predict new biochemical reactions using a rule-based approach.

289 These dynamic condensates behave like biochemical reaction vessels, but little is known about

290 d interacting network of genes, proteins and biochemical reactions which give rise to life ultimately

291 Thousands of biochemical reactions with characterized activities are

292 tterns in living systems are often driven by biochemical reactions with enzymes as catalysts and regu

293 ribution to shear stress stimuli and diverse biochemical reactions with NO.

294 rk offers design principles for programmable biochemical reactions with potential applications to aut

295 ral regulatory mechanism to compartmentalize biochemical reactions within cells.

296 Compartmentalization of primitive biochemical reactions within membrane-bound water micro-

297 tochastic dynamics for individual cells with biochemical reactions within the cells, and diffusion of

298 naceous microcompartments to isolate certain biochemical reactions within the cytoplasm.

299 and negative epistatic interactions amongst biochemical reactions within the metabolic networks of E

300 oach assigns to each core an equal number of biochemical reactions without consideration of their sol