ライフサイエンスコーパス: molecular genetics

1 have broad applications to gene therapy and molecular genetics.

2 relationships between imaging phenotypes and molecular genetics.

3 he roles of specific residues were probed by molecular genetics.

4 become an increasingly powerful strategy in molecular genetics.

5 amenable to manipulation using classical and molecular genetics.

6 rmined is consequently a pressing problem in molecular genetics.

7 s, and alcohol in animal models and in human molecular genetics.

8 translation-prevention research and in basic molecular genetics.

9 foundational experimental systems for modern molecular genetics.

10 ty of technical skills in both classical and molecular genetics.

11 chanisms was transformed by the new tools of molecular genetics.

12 genomes are among the current challenges in molecular genetics.

13 sult of the advances in, and application of, molecular genetics.

14 tudies that cover both clinical features and molecular genetics.

15 me by the use of recombinant DNA methods and molecular genetics.

16 ories into schistosome molecular biology and molecular genetics.

17 and excellent experimental tractability for molecular genetics.

18 pidemiology, 3) gene finding methods, and 4) molecular genetics.

19 ions such as intracellular visualization and molecular genetics.

20 of the major landmarks of late 20th century molecular genetics.

21 OCT findings, ERG phenotype, and microscopy/molecular genetics.

22 rs of TACK archaea and have well-established molecular genetics [6-9].

23 Molecular genetics along with optogenetic and pharmacoge

24 Molecular genetics analyses revealed the insertion of a

25 In this report, using molecular genetics, analytical chemistry, and mass spect

26 teaching, I co-authored several textbooks on molecular genetics and a biography of George Beadle.

27 rmation derived from clinical research using molecular genetics and advanced imaging techniques has p

28 Using molecular genetics and an experimental model of the tick

29 Molecular genetics and biochemical approaches reveal tha

30 Here, using molecular genetics and biochemical approaches, a series

31 This study uses the combined power of molecular genetics and biochemistry to highlight the rol

32 id dominant plant, is fast becoming a useful molecular genetics and bioinformatics tool due to its ke

33 utophagy in eukaryotes and allows the use of molecular genetics and biology in different model system

34 The site is currently focused on the molecular genetics and biology of T1D susceptibility and

35 However, recent advances in molecular genetics and brain imaging implicate dopaminer

36 Developments in molecular genetics and brain imaging may clarify how bra

37 rrectly read 'Department of Biochemistry and Molecular Genetics and Breast Surgery, Ehime University

38 ng the paradigm of what is possible in wheat molecular genetics and breeding.

39 Here we combine a proteomic study with a molecular genetics and cell biology approach to determin

40 avenues of research including epidemiology, molecular genetics and cell biology have identified link

41 Here, we explore the molecular genetics and cell biology that govern jaw join

42 olved scientific questions pertaining to the molecular genetics and cellular biology of these tumors.

43 resolution, we show through a combination of molecular genetics and chemical perturbations that direc

44 An international team has used molecular genetics and chemical tagging to trace how bab

45 an example of the powerful interplay between molecular genetics and clinical care.

46 and Festuca pratensis by using classical and molecular genetics and comparative genomics.

47 l species to crop species has revolutionized molecular genetics and crop improvement strategies.

48 manipulation, land-use and habitat surveys, molecular genetics and demographic and spatial modelling

49 of their biology is needed, with emphasis on molecular genetics and disease modeling.

50 rphological features, but recent progress in molecular genetics and embryology has revealed deep simi

51 ple regression analysis, we have studied the molecular genetics and evolution of short wavelength-sen

52 y interesting regions of the genome for both molecular genetics and evolutionary studies; yet, for mo

53 Using molecular genetics and functional genomics, we find that

54 ing specific targets for characterization by molecular genetics and functional genomics.

55 ene, PMP22, the technological advancement in molecular genetics and gene technology has allowed scien

56 gy are fundamental to state-of-the-art plant molecular genetics and GM crop improvement.

57 Molecular genetics and heterologous expression implicate

58 ntegrative diagnosis taking histomorphology, molecular genetics and imaging into account are reviewed

59 Recent advances in molecular genetics and imaging technologies have begun t

60 By contrasting the biology, molecular genetics and immunology of these two unusual c

61 Here we used molecular genetics and in vivo calcium imaging to invest

62 Molecular genetics and in vivo imaging of cell behaviors

63 Improving our understanding of molecular genetics and leukemic transformation holds pro

64 Moreover, the use of molecular genetics and new experimental strategies has b

65 Molecular genetics and observational case studies of 2 f

66 m1054 mutant a useful model for studying the molecular genetics and pathogenesis of PCD.

67 ause of advances in the understanding of the molecular genetics and pathogenesis of the disease, inco

68 recent advances in this field regarding the molecular genetics and pathogenic mechanisms of CDAs, th

69 Recent advances in molecular genetics and phylogenetic reconstruction have

70 d by the gap between cellular immunology and molecular genetics and profited from the advances of the

71 en studied at levels of cellular physiology, molecular genetics and protein biochemistry.

72 Most studies of human molecular genetics and social environment interactions o

73 However, recent advances in molecular genetics and structural biology are helping to

74 Advances in molecular genetics and structural biology indicate stron

75 Here, molecular genetics and structure-activity analyses show

76 Combining molecular genetics and surname analysis illuminates popu

77 Using molecular genetics and the annotated Drosophila melanoga

78 taneous disorders in the wake of advances in molecular genetics and the development of mouse models o

79 Technological advancements in fields such as molecular genetics and the human microbiome have resulte

80 Advances in molecular genetics and the pathogenesis of ARVC could af

81 Combining emerging technologies with molecular genetics and traditional animal models promise

82 he most fruitful marriage of the advances in molecular genetics and treatment will be the design of a

83 This study combines in silico, molecular genetics, and biochemical analyses to characte

84 the tools of disease physiology, single-gene molecular genetics, and genomics.

85 eams with skills in clinical diagnostics and molecular genetics, and hard work by scores of trainees

86 tz crystal microbalance, circular dichroism, molecular genetics, and immunofluorescence to study spec

87 ances in experimental pathology, immunology, molecular genetics, and neuroimaging, as well as the dis

88 plication of modern chemistry, biochemistry, molecular genetics, and optical physics to these old str

89 isciplinary approach combining biochemistry, molecular genetics, and structural biology, that meningo

90 od, including the precise cell(s) of origin, molecular genetics, and the mechanisms responsible for t

91 an integrated genomics, bioinformatics, and molecular genetics approach to dissect regulatory networ

92 Using a complementary molecular genetics approach to enhance cell-cell interac

93 Here we explore a molecular genetics approach to restrict the assimilation

94 Using a molecular genetics approach, we investigated the mechani

95 The utilization of molecular genetics approaches in examination of panic di

96 Molecular genetics approaches in zebrafish research are

97 Improved understanding of the molecular genetics associated with these lesions will li

98 Taking advantage of the robust molecular genetics available in S. cerevisiae, we identi

99 The aim of this study was to use a mouse molecular genetics-based approach to test whether the le

100 Recently, the use of a molecular genetics-based approach using messenger RNA (m

101 Examining 20 730 individuals, we report a molecular genetics-based heritability estimate (h(2)SNP)

102 There are significant differences in molecular genetics between pancreatic and extrapancreati

103 Since the utility of classical molecular genetics beyond model species is limited, the

104 We use molecular genetics, biochemical analyses, and experiment

105 We utilized molecular genetics, biochemistry, and cryo-electron micr

106 Painstaking molecular genetics, biochemistry, and electron microscop

107 truction (cryo-reconstruction) combined with molecular genetics, biochemistry, and in vivo approaches

108 owever, little is known about the underlying molecular genetics, biochemistry, or physiology of L. he

109 s, which has many of the advantages of yeast molecular genetics but uses long-range microtubule-based

110 y through the ongoing extinction crisis, and molecular genetics can assist in park design by helping

111 Advances in molecular genetics challenge the hepatology community to

112 , clinical trials, psychiatric epidemiology, molecular genetics, children, and other cultures are dis

113 re research for the neuroscience and broader molecular genetics communities.

114 otyping that should prove useful in clinical molecular genetics diagnostics and pharmacogenetic resea

115 rrent classification system, histopathology, molecular genetics, electrophysiology, and transcriptome

116 rther companion paper was published in Human Molecular Genetics (Ellis et al, 2005 [3]) showing that

117 stry, molecular biology, molecular virology, molecular genetics, epigenetics, genomics, proteomics, a

118 stry, molecular biology, molecular virology, molecular genetics, epigenetics, genomics, proteomics, a

119 el player in Plasmodium motility and provide molecular genetics evidence for a critical role of a sma

120 poson vector for chromosomal engineering and molecular genetics experiments in zebrafish.

121 le-stranded components is necessary for many molecular genetics experiments.

122 Advances in molecular genetics extend our ability to recognize and t

123 netheless, there is increasing evidence that molecular genetics, focused -omic (proteomic, metabolomi

124 Here we take advantage of newly available molecular genetics for Cryptosporidium parvum to investi

125 in nitrate research, spanning biochemistry, molecular genetics, genomics, and systems biology.

126 ocusing on clinical and laboratory features, molecular genetics, genotype-phenotype correlation, and

127 Cell type-specific molecular genetics has allowed a new level of examinatio

128 Molecular genetics has been key in allowing developmenta

129 Molecular genetics has clearly differentiated the genus

130 combination of neurobehavioural studies and molecular genetics has determined behavioural difference

131 As the scope of assays used in molecular genetics has expanded to capture systems-level

132 The development of molecular genetics has greatly enhanced the study of the

133 Molecular genetics has had a major influence on our unde

134 In recent years, the advent of molecular genetics has heightened awareness of familial

135 Molecular genetics has identified dozens of genes that r

136 nt research using methodological advances in molecular genetics has improved our understanding of the

137 The advent of molecular genetics has in the past several years aided c

138 The field of molecular genetics has many roles in biodiversity assess

139 The technology of molecular genetics has profoundly altered the conduct of

140 Molecular genetics has revealed a precise stereotypy in

141 Molecular genetics has revealed the identities of severa

142 transposon, the workhorse of D. melanogaster molecular genetics, has a pronounced nonrandom insertion

143 Advances in immunology and molecular genetics have accelerated our understanding of

144 Here we review how molecular genetics have advanced our understanding of th

145 contributions to insights in population and molecular genetics have been fueled by advances in compu

146 Second, dramatic advances in molecular genetics have created new possibilities for in

147 Although recent advances in molecular genetics have enabled improved risk classifica

148 s in neuroimaging, developmental biology and molecular genetics have increased the understanding of d

149 ology, physiology, and biochemistry, but its molecular genetics have not been explored.

150 Advances in cell type-specific molecular genetics have now helped to elucidate several

151 The last 50 years of molecular genetics have produced an abundance of new dis

152 Recent advances in molecular genetics have produced many novel strategies f

153 actorial and complex, but recent advances in molecular genetics have provided additional information

154 Advancements in molecular genetics have revealed that hybridization may

155 Major advances and developments in corneal molecular genetics have revolutionized our fundamental u

156 More recently, advances in molecular genetics have suggested important mechanistic

157 Advances in molecular genetics have vastly improved our understandin

158 Recent advances in bacterial molecular genetics, immunology, and human genetics have

159 To evaluate the role of molecular genetics in the routine clinic, we investigate

160 ggesting these cells' utility to dissect T2D molecular genetics in these regions.

161 Molecular genetics, in vitro assays, and expression data

162 as opportunities presented by incorporating molecular genetics into these efforts.

163 , the involvement of experts from outside of molecular genetics is hampered by the specialist literat

164 Molecular genetics is playing an increasing role in the

165 PURPOSE OF REVIEW: Molecular genetics is revolutionizing the diagnosis and

166 cts from 256 sibships (243 markers, the Utah Molecular Genetics Laboratory).

167 By analyzing tumors at a molecular genetics level rather than traditional histolo

168 The potential of molecular genetics, like all technology, must be evaluat

169 ration and sperm storage as well as powerful molecular genetics make it an excellent model organism f

170 aches such as this enhance the resolution of molecular genetics, make genome editing easier, and may

171 able data on the epidemiology, risk factors, molecular genetics, management options, and outcomes of

172 rs in regulating CYP3A4 expression, and used molecular genetics methods (siRNA/shRNA gene knockdown a

173 titioners for the changes likely to occur as molecular genetics moves from the laboratory to clinic.

174 Recent findings from molecular genetics now make it possible to test directly

175 nces in our understanding of the biology and molecular genetics of acute leukemia that are clinically

176 we provide a state-of-the-art review of the molecular genetics of ADHD incorporating evidence from c

177 Recent advances in our knowledge of the molecular genetics of AML have significantly improved ou

178 Several advances in the molecular genetics of aortic valve formation and calcifi

179 investigations into the pathophysiology and molecular genetics of ARH.

180 resulted in a detailed understanding of the molecular genetics of benign and malignant tumors affect

181 An understanding of the molecular genetics of carcinoma of the pancreas is impor

182 We focus on the molecular genetics of cardiac hypertrophy in various con

183 tly, data has become available regarding the molecular genetics of children affected with juvenile de

184 These advancements in the molecular genetics of CLL have important implications fo

185 Investigators conducting studies of the molecular genetics of complex traits in humans often nee

186 chanisms controlling DUOX expression and the molecular genetics of congenital hypothyroidism.

187 owerful resource for those investigating the molecular genetics of facial development and facial clef

188 ariants, and they may give insights into the molecular genetics of facial development.

189 these data provide key new insights into the molecular genetics of form and function in the mammalian

190 The important interplay between the molecular genetics of gastrontestinal stromal tumour and

191 A more complete understanding of the molecular genetics of head and neck cancer is providing

192 ess has been made in the past two decades in molecular genetics of heritable skin diseases, and patho

193 Extraordinary progress accomplished in molecular genetics of inherited cardiomyopathies allowed

194 Studies of the molecular genetics of inherited disorders have also prov

195 een a revolution in our understanding of the molecular genetics of insecticide resistance.

196 Here, we review published studies of the molecular genetics of lung cancer in never smokers and i

197 n and translation in Escherichia coli to the molecular genetics of mammalian cells.

198 Here, I review the molecular genetics of meiotic silencing and consider the

199 associated with cardiac arrhythmias, and the molecular genetics of monogenic disorders of heart rhyth

200 a major advance in our understanding of the molecular genetics of NCMD and provide insights into the

201 Recent advances in understanding the molecular genetics of nematode moulting should stimulate

202 odel has made it possible to investigate the molecular genetics of neural crest contributions to outf

203 An improved understanding of the molecular genetics of OS may yield new approaches to imp

204 Research into the molecular genetics of osteoarthritis (OA) has been subst

205 ovide a valuable platform for addressing the molecular genetics of osteosarcoma and for developing no

206 ology in increasing our understanding of the molecular genetics of PAD.

207 stantially advanced our understanding of the molecular genetics of PAH.

208 Therefore, understanding the molecular genetics of palate development is important fr

209 we believe that an improved knowledge of the molecular genetics of pancreatic cancer will lead to the

210 The molecular genetics of panic disorder (PD) with and witho

211 adic parathyroid tumors to better define the molecular genetics of parathyroid tumors.

212 In this review we describe the molecular genetics of PD as currently understood to help

213 ntly contributed to our understanding of the molecular genetics of photosynthesis, photoheterotrophy,

214 view summarizes current understanding of the molecular genetics of polycythemia vera and essential th

215 important recently published findings on the molecular genetics of primary gliomas.

216 stigations into the biochemical pathways and molecular genetics of reduced P metabolism in bacteria a

217 Here, we review the current knowledge of the molecular genetics of replisome dysfunction disorders an

218 This study provides insight into the molecular genetics of SAM initiation and function in mai

219 Elucidation of the molecular genetics of sarcomeric hypertrophic cardiomyop

220 wide association study of common SNPs in the Molecular Genetics of Schizophrenia (MGS) case-control s

221 ciation study (GWAS) data set available, the Molecular Genetics of Schizophrenia (MGS) data set.

222 case subjects of European ancestry from the Molecular Genetics of Schizophrenia (MGS) sample, three

223 The Molecular Genetics of Schizophrenia (MGS2) project recru

224 Here, we review the molecular genetics of SHANK mutations in human ASD and d

225 ollowing the successful determination of the molecular genetics of single-gene disorders, attention h

226 This review first describes the molecular genetics of SMA and then focuses on newborn sc

227 Recent work on the molecular genetics of speciation has raised an altogethe

228 Recent advances in the molecular genetics of sporadic and familial GEP NET are

229 recent advances in our understanding of the molecular genetics of T-ALL.

230 ome editing] will be critical to dissect the molecular genetics of T2DM pathogenesis, to build next-g

231 The molecular genetics of the assembly pathway and high-reso

232 The present report reviews the clinical and molecular genetics of the cAMP-dependent protein kinase

233 we discuss the clinical characteristics and molecular genetics of the more common autosomal recessiv

234 er, much remains to be done to elucidate the molecular genetics of the risk of developing ALD and in

235 The molecular genetics of these diseases explains the differ

236 garding the etiology, molecular biology, and molecular genetics of these diseases.

237 lines recent developments in the biology and molecular genetics of these disorders, current diagnosti

238 nderpinnings, little else is known about the molecular genetics of this frequently fatal cancer.

239 in this area, as well as interesting data on molecular genetics of thyroid cancer will be discussed.

240 The molecular genetics of trichome distortion in Arabidopsis

241 Recent advances in the molecular genetics of uveal melanoma are revolutionizing

242 ing data, our findings shed new light on the molecular genetics of uveal melanoma, delineating it as

243 his issue, we took advantage of the power of molecular genetics of yeast.

244 esence of VEGF stimulation was combined with molecular genetics, optical imaging, and biochemistry to

245 Combined with technologies for single-cell molecular genetics or cell biology, it may significantly

246 The quest for therapies based on molecular genetics (pharmacogenomics, DNA microarrays, e

247 Using molecular genetics, plant physiology, hormone analysis a

248 ical cross-linking mass spectrometry (CXMS), molecular genetics, protein biochemistry, and structural

249 Here we applied molecular genetics, proteomics, and whole-genome sequenc

250 Recent advances in human and molecular genetics provide an unparalleled opportunity t

251 identified from NGS databases at three large molecular genetics reference laboratories.

252 The results inform molecular genetics research and transdiagnostic treatmen

253 rily based on our laboratory-based and human molecular genetics research of addictive diseases, will

254 tics, adoption of the Caenorhabditis elegans-molecular genetics resource for general nematological re

255 Recent advancements in molecular genetics resulted in the identification of gli

256 ccount the most current information on virus molecular genetics, serology, and host reactivity.

257 Molecular genetics should help match the types and/or in

258 g of actin gene transcription, combined with molecular genetics, stochastic simulation and probabilis

259 hat encompasses the latest advances in viral molecular genetics, structural biology, and immunology.

260 Recent molecular genetics studies implicate neuregulin 1 (NRG1)

261 Extension of molecular genetics studies in Borrelia burgdorferi has b

262 Molecular genetics studies of three common autoaggregati

263 d individuals is widely used in clinical and molecular genetics studies.

264 large part due to a paucity of resources for molecular genetics, such as a reference genome.

265 this approach complements the current mouse molecular genetics systems and provides a powerful means

266 Molecular genetics techniques are an essential diagnosti

267 ements in brain imaging, neuropathology, and molecular genetics that have led to different approaches

268 Amassing greater knowledge on the molecular genetics that underlie tree form can benefit t

269 Here we investigated, using molecular genetics, the conservation and diversification

270 fference-makers for psychiatric illness from molecular genetics through culture and review their dist

271 of gene expression mechanisms has propelled molecular genetics to a state of rapid development, a st

272 examples of pharmacogenetics, spanning from molecular genetics to clinical diagnostics for individua

273 cently, researchers have applied advances in molecular genetics to conduct candidate gene and genome-

274 We exploited Arabidopsis molecular genetics to define the mechanism and regulatio

275 Here we used molecular genetics to dissect the neuronal circuits by w

276 Here, we employed bioinformatics and molecular genetics to identify and characterize MATE tra

277 genomics, bioinformatics, metabolomics, and molecular genetics to identify and validate molecular ne

278 We used molecular genetics to probe the required functions of th

279 bine structure-based protein engineering and molecular genetics to restrict the activity of the poten

280 Here, we use molecular genetics to show that the moss Physcomitrella

281 h, integrating the tools of quantitative and molecular genetics to study developmental processes, and

282 In order to apply the tools of molecular genetics to this question, we have adapted a b

283 Around 1972, I began to use molecular genetics to understand the developmental biolo

284 ed evolutionary theory, genome sequences and molecular genetics to understand the selection response

285 MPRAs are powerful molecular genetics tools that can be used to screen thou

286 brief historical perspective of the field of molecular genetics, touching on seminal research that pa

287 stituents of ripe blueberries are known, the molecular genetics underlying their biosynthesis, locali

288 The molecular genetics underlying this abnormality are not k

289 of cancer-related deaths worldwide, yet the molecular genetics underlying this malignancy are still

290 The molecular genetics underlying thyroid carcinogenesis is

291 By using a combination of molecular genetics, vital dye fate mapping, organ cultur

292 archaeal atomic structure as a guide, yeast molecular genetics was used to query the function of the

293 By combining computational modeling with molecular genetics, we show that boundary formation is d

294 Using molecular genetics, we show that the functional gene for

295 Using molecular genetics, we then mapped at which point in the

296 Using molecular genetics, we unexpectedly found that genetic d

297 in this series of reports as advancements in molecular genetics, whole-genome sequencing, and studies

298 sorders, and will ultimately link defects in molecular genetics with specific neuropathological targe

299 Combining molecular genetics with target-based approaches, we esta

300 Using a combination of astrocyte-specific molecular genetics, with in vivo electrophysiology and p