ライフサイエンスコーパス: molecular biology

1 ng a new way to look at the central dogma of molecular biology.

2 contributions to research in physiology and molecular biology.

3 elf-assembly to pharmaceutical chemistry and molecular biology.

4 iding principle by which scientists approach molecular biology.

5 enance can be traced to the earliest days of molecular biology.

6 o was one of the most unexpected findings in molecular biology.

7 ot yet provided firm leads to its underlying molecular biology.

8 recent additions from the powerful tools of molecular biology.

9 the basis of numerous classic experiments in molecular biology.

10 x and recalcitrant to standard techniques of molecular biology.

11 ory at a pivotal point in the history of RNA molecular biology.

12 sion of high-throughput data in genomics and molecular biology.

13 and manipulation of phosphate monoesters in molecular biology.

14 in powerful techniques that underpin modern molecular biology.

15 requent analytical tasks in biochemistry and molecular biology.

16 d sequences remains a challenging problem in molecular biology.

17 rgely ignored following the advent of modern molecular biology.

18 the past decade portend a paradigm shift in molecular biology.

19 the International Union of Biochemistry and Molecular Biology.

20 x PTM code is one of the great challenges in molecular biology.

21 istochemistry, vascular corrosion casts, and molecular biology.

22 er studies on the role of G4 DNA in cell and molecular biology.

23 ical value to the fields of pharmacology and molecular biology.

24 of the most thriving arenas of cellular and molecular biology.

25 asets is becoming a fundamental component of molecular biology.

26 n sequencing has become an important tool in molecular biology.

27 Consequently, they may enhance model-driven molecular biology.

28 oning over 40 years ago marked the advent of molecular biology.

29 ar recognition by proteins is fundamental to molecular biology.

30 ific regions in a genome is a cornerstone of molecular biology.

31 ulation has become a major research topic in molecular biology.

32 hereby uncovering fundamental aspects of its molecular biology.

33 roteins along DNA occurs on a new vehicle in molecular biology, a 'molecular sled' named pVIc.

34 As molecular biology advanced, and the capability to isolat

35 ing the past two decades, the application of molecular biology allowed cloning, production and charac

36 Because molecular biology analyses in archaea become more and mo

37 our and lungs were removed for histology and molecular biology analysis.

38 h increasingly sophisticated technologies in molecular biology and "omic" platforms to analyze patien

39 evealed new information regarding underlying molecular biology and associated regulatory mechanisms.

40 thod, we applied it to various operations in molecular biology and automated cell staining including

41 gely a result of the spectacular advances in molecular biology and biotechnology achieved in the past

42 Technologic advances in molecular biology and biotechnology are increasingly bei

43 olecules which are an important part of many molecular biology and biotechnology projects.

44 h potential for applications in quantitative molecular biology and biotechnology, yet the microscopic

45 rable for a range of routine applications in molecular biology and biotechnology.

46 d to the study of each scale (e.g. genetics, molecular biology and cognitive neuroscience).

47 Standard wet and dry laboratory skills in molecular biology and computational analysis are require

48 cs of biological macromolecules underlie the molecular biology and correct functioning of cells.

49 the innovations in both protein engineering/molecular biology and crystallography techniques that ha

50 activity of live cells are of interest from molecular biology and drug discovery.

51 have resulted in growing knowledge about the molecular biology and ecology of these plants and functi

52 rating evolutionary biology with mechanistic molecular biology and ecology, promising applications in

53 enzymatically through a novel combination of molecular biology and electrochemistry.

54 umerous direct applications in computational molecular biology and elsewhere.

55 t the Medical Research Council Laboratory of Molecular Biology and emeritus fellow of Wolfson College

56 f developmental biology, genetics, genomics, molecular biology and ethology to understand unique feat

57 While the use of RNA interference (RNAi) in molecular biology and functional genomics is a well-esta

58 and progressed to utilize the techniques of molecular biology and gene-targeted mice.

59 d-mediated conjugation ushered in the era of molecular biology and genetics.

60 l in understanding virtually every aspect of molecular biology and genetics.

61 any virus is crucial to fully understand its molecular biology and guide the development of effective

62 iology, Deputy Chairman of the Laboratory of Molecular Biology and Head of its Division of Structural

63 ase with follow-up studies using traditional molecular biology and histopathology techniques.

64 Here we use molecular biology and homology modeling to identify resi

65 serves as a model for studies of alphavirus molecular biology and host-pathogen interactions.

66 detailed introduction to fundamental RNA-seq molecular biology and informatics concepts.

67 ll has celebrated the powers of reductionist molecular biology and its major successes for four decad

68 id Baltimore and Howard Temin revolutionized molecular biology and laid the foundations for retroviro

69 acid (LNA) monomers are used extensively in molecular biology and medicinal chemistry to modulate ge

70 ombinant DNA technology that has transformed molecular biology and medicine.

71 ction enzymes and their continuing impact on molecular biology and medicine.

72 inhibition was examined using cell culture, molecular biology and mouse models; and the relevance of

73 Recent breakthroughs in molecular biology and next generation sequencing technol

74 gnition of dsDNA targets for applications in molecular biology and nucleic acid diagnostics.

75 These methodologies range from classical molecular biology and optical approaches, such as bisulf

76 Recent advances in molecular biology and optical imaging are being applied

77 Future study of the molecular biology and pathogenesis of OCC should offer a

78 recent advances in our understanding of the molecular biology and pathogenesis of this unique urogen

79 ing primarily derived from discovery focused molecular biology and physics.

80 d to an increased understanding of norovirus molecular biology and replication, pathogenesis, cell tr

81 n unprecedented rate owing to innovations in molecular biology and the development of targeted therap

82 er, little is known about SHFV's ecology and molecular biology and the mechanism by which it causes d

83 ogress has been made in the knowledge of the molecular biology and the prognostic assessment of MF.

84 nts in our understanding of its genetics and molecular biology and their translational relevance.

85 Advances in RNA biochemistry, structural and molecular biology, and bioinformatics have revealed othe

86 s at the level of cell capture, phenotyping, molecular biology, and bioinformatics promise an excitin

87 ocal microscopy, immuno-electron microscopy, molecular biology, and cell culture.

88 ents current tospovirus taxonomy, diversity, molecular biology, and cytopathology as an introduction

89 pulations is a fundamental goal of virology, molecular biology, and disease ecology.

90 tion assays are widely used in pharmacology, molecular biology, and drug discovery.

91 Discoveries in cytogenetics, molecular biology, and genomics have revealed that genom

92 g of their roles in eosinophil cell biology, molecular biology, and immunobiology in health and disea

93 ations of computational modeling technology, molecular biology, and in vitro reconstitution biochemis

94 action, two open and fundamental problems in molecular biology, and it may have significant potential

95 Here we combined electrophysiology, molecular biology, and radioimmunoassay to show that the

96 However, the different etiologies, molecular biology, and recurrence patterns associated wi

97 esis is one of the most common techniques in molecular biology, and reference molecular weight marker

98 s is enabled by recent advances in genomics, molecular biology, and systems biology, and will continu

99 urther developments in Earth system science, molecular biology, and trait data for islands hold conti

100 ause of their large, complex genomes, unique molecular biology, and unresolved in-group relationships

101 ity, low-cost molecular weight standards for molecular biology applications.

102 IV-1/SIV-infected cells we employed cell and molecular biology approaches to investigate the effect o

103 Several in silico and molecular biology approaches were used to test our hypot

104 pharmacologic, biochemical, biophysical, and molecular biology approaches.

105 vel reagents using traditional enzymatic and molecular biology approaches.

106 concentrations, we applied various omics and molecular biology approaches.

107 t phenotype was characterized using cell and molecular biology approaches.

108 Several methods with different molecular biology are under development and the first fi

109 of experimental results in biochemistry and molecular biology, as well as for proteome-wide studies

110 different fields, such as developmental and molecular biology, as well as technologies, such as micr

111 hnologies have allowed many gene locus-level molecular biology assays to become genome-wide profiling

112 nd are commonly used as tools in a number of molecular biology assays, many details of the kinetic me

113 iratory pathogen panel (RP panel) is a novel molecular biology-based assay, developed by GenMark Diag

114 Though, this work needs various molecular biology-based optimizations to promote this te

115 tient samples, we aimed at understanding the molecular biology behind JMML and identified a previousl

116 rs or isolated neutrophils were utilized for molecular biology, biochemistry and pathology analysis.

117 dies in evolution, genetics, plant breeding, molecular biology, biochemistry and systems biology.

118 troviruses, my use of the tools of genetics, molecular biology, biochemistry, and biophysics has span

119 By combining molecular biology, biochemistry, and biophysics techniqu

120 air-liquid interface and examined them using molecular biology, biochemistry, and live-cell imaging.

121 that virtually all contemporary research in molecular biology, biochemistry, and other biosciences u

122 lational science including biology, cell and molecular biology, biochemistry, physiology, pharmacolog

123 ol kit of kinetics, kinetic isotope effects, molecular biology, biophysics, and bioinformatics provid

124 nto the host genome is a fundamental task in molecular biology, biotechnology and gene therapy.

125 s for nucleic acid targeting applications in molecular biology, biotechnology, and medicinal chemistr

126 d for nucleic acid targeting applications in molecular biology, biotechnology, and medicinal chemistr

127 971, I came across a paper in the Journal of Molecular Biology by Larry Simpson, a classmate of mine

128 he other hand, many core methods of cell and molecular biology cannot be applied to human subjects.

129 In a recent report in Nature Structural and Molecular Biology, Cohen et al. (2015) present intriguin

130 ial design, based on collective knowledge of molecular biology combined with limited transposon mutag

131 Water's value for molecular biology comes from both the structural and dyn

132 om limited observable data is significant in molecular biology, communication and many other areas.

133 iate adoption by the academic and industrial molecular biology community.

134 ed in this work show that our combination of molecular biology, computational biology, and mathematic

135 tein interactions (PPIs) is at the center of molecular biology considering the unquestionable role of

136 few decades, major advances in the field of molecular biology, coupled with advances in genomic tech

137 tabase Issue includes descriptions of 58 new molecular biology databases and recent updates to 123 da

138 2 papers that include descriptions of 56 new molecular biology databases, and updates on 115 database

139 Structural molecular biology depends crucially on computational tec

140 and first Editor-in-Chief of the Journal of Molecular Biology, Deputy Chairman of the Laboratory of

141 The central dogma of molecular biology describes the translation of genetic i

142 This review highlights similarities in molecular biology, diagnosis, treatment, and outcomes be

143 n source Python library for simulating basic molecular biology DNA unit operations such as restrictio

144 In the last 40 years, advances in molecular biology, DNA recombination technology, and gen

145 In cell and molecular biology, double-stranded circular DNA construc

146 suspensions in the fields of biotechnology, molecular biology, drug discovery, and cosmetics.

147 avidin is one of the most important hubs for molecular biology, either multimerizing biomolecules, br

148 iophysical, and biochemical tools as well as molecular biology, electrophysiology, and bioinformatics

149 Using behavioral neuroscience, molecular biology, electrophysiology, and pharmacology,

150 bed procedure can be performed with standard molecular biology equipment and a FACS machine.

151 ack of systematic analysis of L-forms in the molecular biology era.

152 presentation at 2015 Intelligent Systems for Molecular Biology/European Conference on Computational B

153 A researcher with molecular biology experience should be able to follow th

154 Through pharmacological and molecular biology experiments we report data showing tha

155 gh-efficiency DNA ligation is vital for many molecular biology experiments, and it is best achieved u

156 differentiation therapy by performing "dry" molecular biology experiments.

157 An individual with relevant molecular biology expertise can complete library prepara

158 ve learned about various aspects of cell and molecular biology from the many individual high-throughp

159 DNA ligases have broad application in molecular biology, from traditional cloning methods to m

160 e last 30 years in immunology, cytogenetics, molecular biology, gene expression profiling, mass spect

161 They became the enabling tools of molecular biology, genetics and biotechnology, and made

162 d graduate school in 1963, the golden age of molecular biology had just begun, and myoglobin was the

163 as stable isotope probing (SIP) coupled with molecular biology has been a breakthrough toward linking

164 Molecular Biology has been at the heart of the 'big data

165 In the 21st century, molecular biology has improved our understanding of GAS

166 Although many recent advances in molecular biology have allowed limb regeneration and tis

167 t advances in both quantitative genetics and molecular biology have contributed to understanding func

168 Advancements in molecular biology have improved the ability to character

169 monic labels and sensors have revolutionized molecular biology, helping visualize cellular and biomol

170 In a recent issue of Nature Structural & Molecular Biology, Heuer et al. (2017) present a 3.9-A c

171 Researchers should have skills in yeast molecular biology, immunolabeling techniques and access

172 Using biochemical, molecular biology, immunostaining and transmission elect

173 his postdoctoral fellow at the Laboratory of Molecular Biology in 1967 and as his biographer 45 years

174 ectrophysiology, confocal Ca(2+) imaging and molecular biology in a rat model of ischaemic HF.

175 evices that enable the study of cellular and molecular biology in mammalian cells.

176 ripotent stem cell technology, genomics, and molecular biology in this unique population to understan

177 ender segregation in some sub-disciplines in molecular biology, in particular in genomics where we fi

178 enterica are models for many experiments in molecular biology including chemotaxis, and most of the

179 genes provide unique insights into the fly's molecular biology, interactions with the host animal and

180 A central dogma of molecular biology is that the sequence of a protein dict

181 A challenge in molecular biology is to distinguish the key subset of re

182 An overarching goal in molecular biology is to gain an understanding of the mec

183 A current goal of molecular biology is to identify transcriptional network

184 A common task in molecular biology is to infer functional, structural or

185 An important goal in molecular biology is to understand functional changes up

186 tional Conference on Intelligent Systems for Molecular Biology (ISMB) and the 12th European Conferenc

187 IG) before the annual Intelligent Systems in Molecular Biology (ISMB) conference.

188 the International Union of Biochemistry and Molecular Biology (IUBMB).

189 ed in minutes with common tools found in all molecular biology laboratories.

190 ynthesis of biosynthetic pathways in general molecular biology laboratories.

191 pre-analyzed sequence data from the European Molecular Biology Laboratory European Nucleotide Archive

192 tion, first Director-General of the European Molecular Biology Laboratory, and 33rd President of St.

193 d/or easy to implement in a state-of-the-art molecular biology laboratory.

194 nd a protocol that can be implemented in any molecular biology laboratory.

195 protocol should be accessible to any general molecular biology laboratory.

196 s brought nanometer-precision fabrication to molecular biology labs, offering myriads of potential ap

197 Based on classical studies in molecular biology, many have viewed microbes as followin

198 dapts and combines previous well-established molecular biology methods to provide a streamlined strat

199 , we propose perspectives on how advances in molecular biology, microscopy, and nucleotide sequencing

200 In molecular biology, molecular events describe observable

201 vances have accompanied the breakthroughs in molecular biology, nanomaterial sciences, and most impor

202 molecules one of the most relevant topics of molecular biology nowadays.

203 results provide the first insights into the molecular biology of a unique coordinated gene expressio

204 A robust cell line to study the novel molecular biology of ascovirus replication in vitro is l

205 and findings pertaining to genetics and the molecular biology of ASD.

206 ly understood, there is heterogeneity in the molecular biology of cancer across race and ethnicities.

207 ucial information regarding the cellular and molecular biology of cancer.

208 erations to cellular properties, morphology, molecular biology of carbohydrates, proteins and lipids,

209 Here we review the structural and molecular biology of curli biogenesis, with a focus on t

210 ensive computational work characterizing the molecular biology of gene fusions; (ii) development rese

211 Advances in the understanding of the molecular biology of glioblastoma are being rapidly tran

212 ve been achieved in the understanding of the molecular biology of glioblastoma multiforme (GBM); thus

213 ll biology aids in exploring the comparative molecular biology of GLRaVs and deciphering the complex

214 nt supporting cells, so the biochemistry and molecular biology of hair cells can be difficult to stud

215 Advances in understanding the molecular biology of HCV have ushered in a new era in th

216 fection as a block to HIV-1 eradication, the molecular biology of HIV-1 latency remains incompletely

217 lly recapitulate the phenotype, cellular and molecular biology of human CML progression.

218 Little is known about the molecular biology of JMRV.

219 ent understanding of the natural history and molecular biology of low-risk prostate cancer, and revie

220 Here, we focus on the cell and molecular biology of mammalian autophagy and review the

221 tutive JAK-STAT activation, the cellular and molecular biology of myeloproliferative neoplasms (MPN)

222 that may develop from an appreciation of the molecular biology of natural systems.

223 n have greatly expanded our knowledge of the molecular biology of NPC, yet much remains to be uncover

224 and more comprehensive understanding of the molecular biology of pancreatic ductal adenocarcinoma.

225 ly focused primarily on the biochemistry and molecular biology of PARP-1 in DNA damage detection and

226 Understanding the underlying molecular biology of perceived age is vital for identify

227 These findings provide links between the molecular biology of SFV and its biological properties a

228 lives of cells, but as this special issue of Molecular Biology of the Cell attests, the nonchemical a

229 We developed the Molecular Biology of the Cell Ontology based on standard

230 vation and other aspects of the cellular and molecular biology of the photoreceptors have convinced s

231 dings shed further light on the cellular and molecular biology of the post-IL-12 regulatory rebound a

232 ose collaboration with animal studies on the molecular biology of the spinal cord, will continue to d

233 subsequent acquisition of insights into the molecular biology of these genes provide grounds for opt

234 Studying the basic molecular biology of these viruses is of great importanc

235 here has been no global investigation of the molecular biology of this parasite.

236 ating imaging studies into understanding the molecular biology of transcription.

237 approach using contemporary technologies in molecular biology, -omics, and cell biology aids in expl

238 e basis of recent advances in structural and molecular biology on bacterial cellulose synthases, we r

239 pleted by someone with minimal experience in molecular biology or biophysics.

240 crease selectivity and sensitivity, by using molecular biology or other modern techniques are also di

241 tructural Studies, a Founder of the European Molecular Biology Organization, first Director-General o

242 , with further sponsorship from the European Molecular Biology Organization, the Federation of Europe

243 ting several scientific disciplines, such as molecular biology, particle physics, and astronomy.

244 In the 21st century, molecular biology permits vaccine development that was n

245 olecules has found widespread application in molecular biology, photochemistry, polymer chemistry, qu

246 e indispensable for the study of fundamental molecular biology processes due to their relatively simp

247 zed, and variously derivatized with standard molecular biology protocols.

248 le tool for simplification and automation of molecular biology protocols.

249 Compelling molecular biology publications have reported the implica

250 rizing and quantifying trace contaminants in molecular biology reagents and instruments in cases wher

251 John Kendrew's birth in 1917, the Journal of Molecular Biology recognizes his seminal contributions t

252 today's advanced techniques with decades of molecular biology research has yielded huge amounts of p

253 lation is still difficult yet fundamental in molecular biology research.

254 Pharmacological and molecular biology results support a model where ETR1 and

255 We used high-resolution kinematic analyses, molecular biology, rheology, and advanced imaging techni

256 In modern molecular biology, RNA has emerged as a versatile macrom

257 tocol requires intermediate cell culture and molecular biology skills, and it is adaptable to the eff

258 The experimental protocol requires basic molecular biology skills, whereas data analysis requires

259 The central dogma of molecular biology states that DNA makes RNA makes protei

260 The central dogma of molecular biology states that the flow of genetic inform

261 ant factors in a number of fields, including molecular biology, stereoselective catalysis, and anion

262 Histochemical and molecular biology studies have enabled us to classify th

263 eproducible and can be applied for any plant molecular biology study.

264 igh quality DNA is the pre-requisite for any molecular biology study.

265 ways, these databases cover a broad range of molecular biology subjects, including genome structure,

266 driven great strides in our understanding of molecular biology such that now we are able to study at

267 ranslation, offering diverse applications in molecular biology, synthetic biology, and biotechnology.

268 dary antibodies are essential tools for many molecular biology techniques and diagnostic tests.

269 The materials and molecular biology techniques described in this protocol

270 Using a variety of molecular biology techniques in both cultured neuroepith

271 Using molecular biology techniques including making a chimeric

272 PKSs, thereby augmenting the contribution of molecular biology techniques to the acceleration of natu

273 e-expression profiles, confirmed by standard molecular biology techniques, revealed that strontium-su

274 Despite recent progresses in molecular biology techniques, sequence information of ex

275 y integrating microfabrication with cell and molecular biology techniques, we provide a quantitative

276 3-NF-kappaB reporter cell line with standard molecular biology techniques.

277 ource software, graphing software and common molecular biology techniques.

278 STED laser, open-source software and common molecular biology techniques.

279 breakthroughs in epidemiology, genetics, and molecular biology that have brought reactivation of feta

280 biological research, across the spectrum of molecular biology to cellular biology, involving fields

281 Logos are commonly used in molecular biology to provide a compact graphical represe

282 There are many challenges facing the use of molecular biology to provide pertinent information in a

283 y has brought improved tools of cellular and molecular biology to the study of phagocytosis and its c

284 -protein reporters that harness the power of molecular biology to visualize specific molecular proces

285 allowing us to apply even more of the modern molecular biology toolkit to single cells.

286 DNA adducts, and the use of LC-MS along with molecular biology tools for understanding the human heal

287 sed on various nanotechnology approaches and molecular biology tools including miRNA biosensors.

288 ls, microchemical analytical techniques, and molecular biology tools to explore many unanswered quest

289 used in conjunction with the various extant molecular biology tools to streamline the synthetic biol

290 From generic assumptions about the molecular biology underlying channel expression, we deri

291 unprecedented progress in understanding the molecular biology underlying pediatric gliomas, fueling

292 e semantically similar to the description of molecular biology unit operations found in literature.

293 ce to the research community to explore ZIKV molecular biology, vaccine development, antiviral develo

294 of diffuse alveolar damage, E-cadherin, and molecular biology variables.

295 As the age of molecular biology was unfolding, I pursued a PhD in nutr

296 Using electron microscopy and molecular biology, we examined protocol renal transplant

297 d potential to revolutionize the practice of molecular biology well beyond genome editing.

298 ities (e.g., in 2011, 54% of U.S. Ph.D.'s in molecular biology were women versus only 31% in philosop

299 n (WDM) is an emerging format for conducting molecular biology with unique characteristics to address

300 dytelic) change that, if paralleled by their molecular biology, would evidence extreme evolutionary s