ライフサイエンスコーパス: germplasm

1 5 897 polymorphic markers within A. hypogaea germplasm.

2 ucing agronomically desirable WSMV-resistant germplasm.

3 infoin and their characterization in diverse germplasm.

4 s of environmental adaptation in the sampled germplasm.

5 of novel allelic variation using wild barley germplasm.

6 solidation of control and ownership of plant germplasm.

7 complex multi-NLR loci from uncharacterized germplasm.

8 nes for other marked trait intervals in this germplasm.

9 ic salinity-induced growth responses in rice germplasm.

10 gree, to some extent, with the origin of the germplasm.

11 for a mutual improvement between the sets of germplasm.

12 ld mandarins were part of the early breeding germplasm.

13 raits that can be improved with S. pennellii germplasm.

14 ortant to the development of resistant maize germplasm.

15 p molecular markers to select phenolics-rich germplasm.

16 and for the maintenance of accurately named germplasm.

17 shape varies significantly in the cultivated germplasm.

18 the existence of suppressors of OVATE in the germplasm.

19 lation of favorable alleles in today's elite germplasm.

20 ndosperm as a potential source of RH mapping germplasm.

21 n cultivars, embodying the majority of Greek germplasm.

22 olic mutants, human disease studies and crop germplasm.

23 terminant of awn suppression in global wheat germplasm.

24 athogens that must be excluded from valuable germplasm.

25 conserved haplotype in the yellow endosperm germplasm.

26 has not yet resulted in commercially viable germplasm.

27 ance resources have been discovered in wheat germplasm.

28 ations of marker alleles across very diverse germplasm.

29 and callus growth rate of high type II maize germplasm.

30 analyses revealed that Rf8 is rare in maize germplasm.

31 the way geneticists utilize wild and exotic germplasm.

32 tion allowing direct transformation of elite germplasm.

33 lerated integration of resistance into elite germplasm.

34 d, due to a large performance gap with elite germplasm.

35 been investigated due to the absence of such germplasm.

36 us making this variety a potential source of germplasm.

37 est for introgression in susceptible sorghum germplasm.

38 he accessions and cultivars in rice breeding germplasm.

39 h, and Mexican teosintes as well as in maize germplasm.

40 erlies seed mass variation in global sorghum germplasm.

41 SG profiles that are observed across Stevia germplasm.

42 hed genic SSRs (eSSRs) generated on the same germplasm.

43 artificial selection and be retained in crop germplasm.

44 mazzard), landrace and bred sweet cherry germplasm.

45 C, but not with catechin content, in diverse germplasm.

46 lines in a new diversity panel of 159 wheat germplasm.

47 ngo, representing Indian and Southeast Asian germplasm.

48 te metabolic engineering of chemically elite germplasm.

49 d availability of genetic variation in wheat germplasm.

50 genetic differences between local and exotic germplasms.

51 conducted in four distinct groups of soybean germplasm: 26 accessions of the wild ancestor of soybean

52 m provides an immortal collection of diverse germplasm, a high-density single-nucleotide polymorphism

53 ies were performed using a population of 214 germplasm accessions and 31,914 SNPs from the SoySNP50K

54 chiaria (Trin.) Griseb. and P. maximum Jacq. germplasm accessions and cultivars.

55 promoter and transcripts from various citrus germplasm accessions established a tight correlation bet

56 of total) taxa associated with 63 crops, no germplasm accessions exist, and a further 257 (23.9%) ar

57 biotic variables are partitioned across rice germplasm accessions may be key to identifying potential

58 Germplasm accessions were evaluated in field trials at I

59 focus on central metabolism in nine selected germplasm accessions.

60 The development of germplasm adapted to changing climate is required to ens

61 strategies that breeders used for developing germplasm adapted to local climates.

62 The new germplasm also was genotyped for 12 microsatellite loci.

63 , ex-situ conservation and sharing of unique germplasm among plant breeders and geneticists.

64 yphyletic distribution of the kabuli form in germplasm, an absence of nested variation within the bHL

65 s and tools to support maize trait analysis, germplasm analysis, genetic studies, and breeding.

66 onstructed in crop species, and their inbred germplasm and associated phenotypic and genotypic data s

67 r cost effective and efficient management of germplasm and better stewarding of these valuable resour

68 We also resequence 146 lines of diverse germplasm and build a variation map consisting of 16 mil

69 ion of the fruit shape alleles in the tomato germplasm and evaluated their contribution to morphology

70 from a very small base of temperate japonica germplasm and having a relatively brief breeding history

71 f the genetic diversity in cultivated coffee germplasm and in wild populations growing in the center

72 ed trait architecture consistency in African germplasm and investigated further evidence for the dome

73 study focused on South American and African germplasm and investigated the genetic architecture of h

74 iting the allelic diversity within available germplasm and leveraging the knowledge of the mechanisms

75 ruit ionome indicated the major influence of germplasm and other locational factors on the acquisitio

76 results suggest that admixture shaped olive germplasm and perhaps also local domestication events.

77 ok policy, (5) keeping track of ownership of germplasm and plant genetic resources, and (6) promoting

78 undation for large-scale characterization of germplasm and population genomics, and a resource for tr

79 alleles at a single locus in cultivated rice germplasm and provide evidence that amplification in wil

80 th commercial varieties clustered with India germplasms and demonstrating allelic admixture, and indi

81 These winter-hardy germplasms and frost tolerance associated markers will p

82 de sequence polymorphisms including alleles, germplasms and phenotypes, Gene Ontology annotations, ge

83 rth's surface, a potential source of ancient germplasm, and a laboratory for the study of rates of mi

84 ximately 800 Mbp), diploid genetics, diverse germplasm, and colinearity with other C4 grass genomes.

85 identified for qP-FF4.1 in the sweet cherry germplasm, and the "soft" alleles were dominant over the

86 d after domestication and spread among maize germplasm, and the ZmWAK kinase domain underwent functio

87 me some of the most well-characterized maize germplasm, and their de novo assemblies were recently ma

88 p) relative to most other grasses, a diverse germplasm, and utility for comparative genomics with ric

89 signed to assess the vast amount of valuable germplasm archived in 1,750 gene banks.

90 f genetic variation between local and exotic germplasms as revealed by missing and unique alleles.

91 The study showed that the germplasm assessed is a good source of micronutrients an

92 Because the entirety of germplasm available in a breeding program is not in Hard

93 istent across years, environments, and elite germplasm backgrounds.

94 ollection of genomic DNA (gDNA) samples from germplasm bank, and two gDNA samples from historical her

95 3 triploids and 7 tetraploids, in the Active Germplasm Bank, at Embrapa Cassava & Fruits, to evaluate

96 e provide a brief introduction to macroalgal germplasm banking and its application to conservation, i

97 ine preservation of marine algal species via germplasm banking with an overview of the technical adva

98 Germplasm banks-living seed collections that serve as re

99 es critical challenges arising from a narrow germplasm base and supply limitations.

100 worldwide necessitating a broadening of the germplasm base required to source and incorporate novel

101 further sampling of seedling RNA within this germplasm base will result in minimal discovery.

102 d the discrimination of different jack fruit germplasm based on their geographical origin in India.

103 p in the clonal multiplication of elite tree germplasm, because the ability to form roots declines ra

104 asymmetrically localizing the protein to the germplasm before cleavage and subsequently degrading res

105 asm pool, while PH207 is a founder of Iodent germplasm, both of which have contributed substantially

106 olyploidization, not only for the cultivated germplasm but also for the entire species.

107 ated with early flowering in global chickpea germplasm but was not widely distributed, indicating tha

108 between processing, fresh-market and vintage germplasm by using an F(st)-outlier method based on the

109 available diversity due to lack of efficient germplasm characterization and structure.

110 ering we demonstrated that shape categories, germplasm classes, and the shape genes were nonrandomly

111 geographical and ecological information for germplasm-collecting missions, as well as for the preser

112 he structure of genetic diversity in a plant germplasm collection is significantly influenced by its

113 ation by providing a framework for efficient germplasm collection management and guidance for future

114 rtain the magnitude of variability in a core germplasm collection of diverse origin and predict pearl

115 e bioaccessibility of phenolics in a diverse germplasm collection representing cultivated highbush bl

116 Comparisons against the US germplasm collection show placement of the sequenced acc

117 orphological traits in a diverse C. baccatum germplasm collection spanning the species distribution.

118 was carried out on the USDA-ARS C. baccatum germplasm collection using data from GIS, morphological

119 A maize germplasm collection was used for statistical testing of

120 total of 265 tomato accessions from the USDA germplasm collection were evaluated at the seedling stag

121 ity panel derived from the Ecofibre Cannabis germplasm collection, an extreme-phenotype genome-wide a

122 ybrids shows a narrow genetic base in the US germplasm collection, and points to the importance of co

123 genome, high-quality reference genome, large germplasm collection, and selfing nature make it an exce

124 ts adaptation to harsh environments, diverse germplasm collection, and value for comparing the genome

125 cultivars and rootstocks, originating from a germplasm collection, has been developed and validated.

126 genetic and biochemical diversity of a large germplasm collection, representing 80% of maize genetic

127 an lines were selected from the USDA-Soybean Germplasm Collection, were grown in Stoneville, MS for b

128 from the US Department of Agriculture grape germplasm collection.

129 represented by the k individuals of a given germplasm collection.

130 This study shows that evaluation of large germplasm collections across north-south geographic clin

131 screening the extensive genetic diversity in germplasm collections and enabling maximal recombination

132 date the genetic and phenotypic diversity of germplasm collections and populations and, yet, biochemi

133 ic diversity of HIPM and DIPM genes in Malus germplasm collections and used a candidate gene-based as

134 etic diversity within the local and regional germplasm collections can enhance the overall effectiven

135 d genebank management and the utilization of germplasm collections for linking natural variation to h

136 The ability to access alleles from unadapted germplasm collections is a long-standing problem for gen

137 the most informative genotypes in sequenced germplasm collections to facilitate experiments for quan

138 ity, all traits available in most major crop germplasm collections, increases in productivity (7%) ar

139 ers to assess and enhance diversity in their germplasm collections, to introgress valuable traits fro

140 enetic diversity of both Chilean and Spanish germplasm collections.

141 Iranian locations and 26 accessions from two germplasm collections.

142 ith extreme phenotypes in large sequences of germplasm collections.

143 is of large structural variations in soybean germplasm collections.

144 This has implications for the scales of germplasm conservation and exploitation of sources of re

145 c gene or chromosome regions and identifying germplasm conserving allelic diversity missing in curren

146 diversity of the apricot (Prunus armeniaca) germplasm containing resistance to PPV, next-generation

147 RNPs and also for sorting certain mRNPs into germplasm-containing structures.

148 accessions were chosen as a reference set by germplasm curators.

149 ces and their application to the analysis of germplasm currently in use in West African breeding prog

150 Potato germplasm derived from S. bulbocastanum has shown durabl

151 genetic diversity in Portuguese common bean germplasm, details on its metabolomics profiles are stil

152 noid content, advantage was taken of a maize germplasm diversity collection that exhibits genetic and

153 cassava varieties that are representative of germplasm diversity within the crop, and in 212 individu

154 dissection of complex genetic traits require germplasm diversity.

155 nse flavor, SP has been used as an important germplasm donor in modern tomato breeding.

156 the efficiency of stevia evaluation through germplasm enhancement and agronomic improvement programs

157 and SNPs are widely used in genetic mapping, germplasm evaluation and marker assisted selection.

158 to integrate genomic prediction into a broad germplasm evaluation process.

159 We present a new strategy for germplasm evaluation under genotype x environment intera

160 genetic resources for salt tolerance in rice germplasm exist but are underutilized due to the difficu

161 reases our understanding of the domesticated germplasm, facilitating translation of acquired knowledg

162 nt varieties conserved in a national ex situ germplasm field collection in Finland, North Europe.

163 t improvement is proposed to provide a novel germplasm for blackgram production on marginal lands.

164 ntitative trait loci to a means of providing germplasm for breeding programmes.

165 propriate approach for the identification of germplasm for breeding varieties with increased proporti

166 ess of moving trait genes into high-yielding germplasm for commercialization.

167 ledge to create a protected commons of plant germplasm for future generations.

168 c switchgrass lines can be used as potential germplasm for improvement of lignocellulosic feedstocks

169 ction (MASS) targeted towards widening peach germplasm for maturity, particularly early maturity.

170 planting materials, and efforts to evaluate germplasm for resistance to witches' broom are described

171 r use as parents to improve existing cassava germplasm for root mealiness.

172 Abundant natural variability exists in rice germplasm for salt tolerance traits.

173 This will diversify the germplasm for sunflower breeding and facilitate understa

174 sual morphology, it is an important donor of germplasm for the cultivated tomato Solanum lycopersicum

175 function in the development of climate smart germplasm for the future.

176 al materials to improve existing common bean germplasm for these important traits.

177 f information prevents exploitation of these germplasms for genetic improvement of new cultivars and

178 e inbred lines representing multiple eras of germplasm from both China and the United States.

179 was no evidence that it is introgressed with germplasm from two other alien Ligustrum species present

180 tensified crop management involving improved germplasm, greater inputs of fertilizer, production of t

181 Lastly, molecular analysis of soybean germplasms harboring the qSw17-1 QTL for the big-seeded

182 ng for the combination of beneficial loci in germplasm has improved yields in diverse environments th

183 re of FCR resistance within cultivated wheat germplasm has significantly limited breeding efforts to

184 sult of widespread adoption of improved crop germplasm have saved natural ecosystems from being conve

185 ioning of sequence variation in modern elite germplasm, highlighting regions vulnerable to genetic er

186 Genetic studies using diverse sour cherry germplasm identified non-functional S-haplotypes for whi

187 Screening of tomato germplasm identified two additional l2 mutant alleles.

188 es with 68 representative japonica or indica germplasms identified rice Lysine-Histidine-type Transpo

189 New breeding technologies accelerate germplasm improvement and reduce the cost of goods in se

190 New estimates of the impacts of germplasm improvement in the major staple crops between

191 biotics, ZmTps21 exists as a useful gene for germplasm improvement programs targeting optimized bioti

192 in a world that had not benefited from crop germplasm improvement since 1965.

193 (and subsequent advances in yields from crop germplasm improvement) on land-cover change.

194 ages secured a tripling of rice output, with germplasm improvements providing benefits beyond US$4.3

195 ker data, and phenotypic data for the actual germplasm in a breeding program.

196 a tool for dissemination and regeneration of germplasm in all mammalian species.

197 ow possible to sequence large collections of germplasm in crops for detecting genome-scale genetic va

198 ight responses among a diverse collection of germplasm, including a phytochrome-deficient mutant elm1

199 tegrates quantitative trait loci, traits and germplasm information along with genomic variation data,

200 such as quantitative trait loci, traits and germplasm information.

201 ipal Component Analysis (PCA) stratified the germplasm into five clusters (Mississippi-River, West No

202 process that selectively integrates nonlocal germplasm into local seed stocks.

203 Division of the domesticated germplasm into two major regional groups (Western and Ea

204 zation, development of plant "chromonomics," germplasm introgression, and marker-assisted breeding.

205 c descriptors in order to characterise onion germplasm is also discussed.

206 able research to be done before O3 -tolerant germplasm is available to growers for most crops.

207 on of flowering time variation in global pea germplasm is controlled by HR, with a single, widespread

208 genetic relationships among and within crop germplasm is invaluable for genetic improvement.

209 ide, and the development of drought-tolerant germplasm is needed to improve crop productivity.

210 inbreds and indicate that tropical highland germplasm is poorly represented in maize inbreds.

211 t to show genetic variations among different germplasms; large-scale genome comparisons among Oryza s

212 ib trait and lignin reduction in the sorghum germplasm line PI 595743.

213 multiple disease resistant (MDR) watermelon germplasm lines have been developed by the USDA in Charl

214 resequencing projects adding to 500+ soybean germplasm lines in total have been integrated.

215 athways, genetic diversity, genes, proteins, germplasm, literature, ontologies and a fully-structured

216 in most cultivated tomatoes, arose in tomato germplasm long before domestication; (4) extant accessio

217 and their genetic variability within extant germplasm must be understood.

218 in challenging environments exist within the germplasm of crops, their wild relatives and species tha

219 exported mango cultivar among the vast mango germplasm of India.

220 he sharing and inconsistent documentation of germplasm often results in unintentionally duplicated co

221 are frequently found in current elite barley germplasm; one is probably the product of mutation breed

222 k for quantifying the contribution of exotic germplasm or older improved varieties to the genetic bac

223 o propose an ideal genotypic, phenotypic and germplasm 'package' that multi-parent populations should

224 gene cloning in any crop that has a diverse germplasm panel.

225 ome-wide association approach on two diverse germplasm panels followed by quantitative trait loci (QT

226 to represent the genetic diversity of maize germplasm, partial or nearly complete loss of the tandem

227 B73 is a founder of the Stiff Stalk germplasm pool, while PH207 is a founder of Iodent germp

228 rt to characterize the primary and secondary germplasm pools for quinoa, we report the complete mitoc

229 novel SHELL alleles in noncommercial African germplasm populations from the Malaysian Palm Oil Board.

230 can further facilitate B. napus breeding and germplasm preservation.

231 ic diversity captured by the National Animal Germplasm Program and explores genetic structure and dif

232 hagy mediated by the SEPA-1 protein depletes germplasm proteins from somatic cells during early devel

233 antitative trait locus discovered in Chinese germplasm, provides the most stable and the largest effe

234 , trait loci, genetic maps, genes, taxonomy, germplasm, publications and communication resources for

235 for markers, quantitative trait loci (QTLs), germplasm, publications and trait evaluation data.

236 el) and 89 from the USDA-ARS National Clonal Germplasm Repository (NCGR panel) in the USA.

237 a-grown pomegranate from the National Clonal Germplasm Repository.

238 The extensive germplasm resource collections that are now available fo

239 servation and exploitation of European peach germplasm resources and, ultimately, as a true heritage

240 Diverse wheat germplasm resources are available for industrial product

241 s challenging due to the limited genomic and germplasm resources available for comprehensive analysis

242 genetic potential of our wild and cultivated germplasm resources for the benefit of society.

243 e cycle, small (440-Mb) genome, and advanced germplasm resources make birch an attractive model for f

244 ion in genes and metabolic pathways with the germplasm resources needed to accelerate varietal develo

245 Extensive germplasm resources, largely a byproduct of their econom

246 ate genetic information contained in diverse germplasm resources.

247 Testing across crop germplasm revealed sufficient variation to maintain nutr

248 est for purposes related to quality control, germplasm screening, and bioactivity evaluation.

249 A germplasm set of twenty-five grapevine accessions, formi

250 airwise comparisons between local and exotic germplasms showed that the temperate and some IITA lines

251 r with unique alleles identified within each germplasm, shows the potential for a mutual improvement

252 ing-by-sequencing was used to generate maize germplasm SNP data for GWAS.

253 gume of Indo-African continents with diverse germplasm sources demonstrating alternating mechanisms d

254 will be necessary to develop improved plant germplasm specifically tailored to serve as energy crops

255 erved in cold-stored tubers from wild potato germplasm stocks that are resistant to cold-induced swee

256 and retrieving basic breeding data including germplasm, study, observation, and marker data.

257 l genetic variation for CCS in diverse maize germplasm, suggest that CCS merits attention as a potent

258 he large genetic variation for CCFN in maize germplasm suggests that CCFN merits attention as a breed

259 dynamics may prevent farmers from accessing germplasm suitable to a rapidly changing climate.

260 y robust markers that can be safely used for germplasm surveys in apple.

261 ) was higher in tea products from the Kenyan germplasm than in those from the Japanese cultivars.

262 Plant breeding aims to improve current germplasm that can tolerate a wide range of biotic and a

263 identified in early flowering grain sorghum germplasm that contain unique loss-of-function mutations

264 Among germplasm, the kabuli form is polyphyletic.

265 n of 2742 modern cassava landraces and elite germplasm, the legacy of a 1930s era breeding to combat

266 sistance genes have been identified in plant germplasm, there is no easy way to predict the quality o

267 Improvement of local germplasm through artificial selection is regarded as th

268 enetic diversity and possible acquisition of germplasm through hybridisation is fundamental to unders

269 Nonlocal germplasm thus might play a critical role in maintaining

270 estrictions on the movement of livestock and germplasm to bluetongue-free countries.

271 findings provide new genes, SSR markers, and germplasm to enhance the breeding of commercially cultiv

272 nities to develop genomic resources for wild germplasm to facilitate crop improvement.

273 e temperate-tropical division of early maize germplasms to different agricultural environments was ar

274 c frequency differences observed between the germplasms, together with unique alleles identified with

275 Very low polymorphism in the germplasm typically used by breeding programs poses a si

276 fold) and across a range of commercial apple germplasm (up to 6-fold).

277 t is imperative to characterize the breeding germplasms using standard phenomic and genomic character

278 underlying phenotypic variation from diverse germplasm, using a mutant phenotype as a "reporter." In

279 their genetic diversity for improvement and germplasm utilization.

280 understanding of genomic controls underlying germplasm variations for this trait in Indian mustard.

281 As predicted, 100-seed mass in global germplasm varies significantly among botanical races and

282 A diverse sample set of wheat germplasm was chemically profiled.

283 ivars that make up the pedigree of US runner germplasm were genotyped and used to identify genomic re

284 ncipal component and cluster analysis, sumac germplasms were categorized into three groups: i.e., gro

285 ng region were not observed in diverse wheat germplasm whereas a nearby polymorphism was highly predi

286 erm cells would provide a reserve of monarch germplasm, which could be utilized in the event of popul

287 erate maize depends upon the use of tropical germplasm, which harbors a rich source of natural alleli

288 g programs require exhaustive phenotyping of germplasms, which is time-demanding and expensive.

289 lly and temporally independent selections of germplasm with a non-brittle rachis were made during the

290 s, understanding genetics and characterizing germplasm with efficient manner.

291 The germplasm with immunity to PM are good sources of resist

292 gh development and delivery of novel cassava germplasm with increased nutrient levels.

293 ing programs for the development of improved germplasm with low bolting tendency.

294 nowledge can be used to develop agricultural germplasm with more predictable vernalization responses

295 ngle genes demonstrates the need for finding germplasm with multigenic resistance to the aphid.

296 goal was to evaluate overall differences in germplasm with quality traits classified as sweet, sweet

297 e, there is potential application of the new germplasm with reduced detrimental glucosinolates and in

298 d 7 were identified in both RILs and diverse germplasm with resolutions of 3.2 cM or less for each of

299 limitation, a resistance phenotype in tomato germplasm with the Ty-1 gene, and functional properties

300 ening the genetic base of commercial alfalfa germplasm with these valuable genetic variations can be