ライフサイエンスコーパス: marker-assisted

1 Marker-assisted analysis of six BMP signaling components

2 cts in soybean SDS resistance breeding using marker-assisted and genomic selection approaches.

3 Overall, our findings suggest that marker-assisted and genomic selection could be used to i

4 We report results of marker assisted backcross breeding of the GR2E trait int

5 Marker assisted breeding (MAB) supports breeding by iden

6 Conventional breeding, molecular marker assisted breeding and genetic engineering have al

7 density genetic linkage maps are needed for marker assisted breeding but are not available for cowpe

8 , association mapping population studies and marker assisted breeding.

9 ovides valuable information for facilitating marker-assisted breeding and apple improvement.Apple is

10 ple translational genomic analysis including marker-assisted breeding and gene editing in order to de

11 rovides a basis for crop improvement through marker-assisted breeding and genomic selection.

12 approaches have now shifted emphasis towards marker-assisted breeding and the construction of vectors

13 lationships between traits and trait groups, marker-assisted breeding can be used more efficiently to

14 y of the Cr1 region are resources for future marker-assisted breeding efforts as well as for investig

15 that comprise them are potential targets for marker-assisted breeding for broad-spectrum, durable dis

16 th fine mapping and gene cloning, as well as marker-assisted breeding for multiple abiotic stress tol

17 associated markers will play a vital role in marker-assisted breeding for winter-hardy pea cultivar.

18 sting that these may be valuable targets for marker-assisted breeding in cowpea.

19 ication of trait-specific markers for use in marker-assisted breeding in Louisiana and elsewhere.

20 wo valuable SNP markers for high-throughput, marker-assisted breeding of seed toxicity in J. curcas.

21 ith decreased fire blight susceptibility via marker-assisted breeding or biotechnological approaches.

22 to identify and track genes of interest in a marker-assisted breeding program.

23 ideration of optimal mapping methodology and marker-assisted breeding strategies for improvement of c

24 n this region hold significant potential for marker-assisted breeding strategies to breed resistance

25 fine-tuning starch structure in rice through marker-assisted breeding that can be used to alter the d

26 We have employed marker-assisted breeding to construct two sets of overla

27 ance under stresses is expected by combining marker-assisted breeding with metabolite markers.

28 These can be used in marker-assisted breeding, genomic selection and genome e

29 ic DNA markers is an invaluable tool for DNA marker-assisted breeding, positional cloning, and a wide

30 "chromonomics," germplasm introgression, and marker-assisted breeding.

31 gies for improving pregnancy maintenance via marker-assisted breeding.

32 t tolerance, providing potential targets for marker-assisted breeding.

33 vement of Striga resistance breeding through marker-assisted breeding.

34 ctional gene mapping, map-based cloning, and marker-assisted breeding.

35 ssociated markers that could be exploited by marker-assisted breeding.

36 tall fescue persistence in dry areas through marker-assisted breeding.

37 ts in perennial species can inform molecular marker-assisted breeding.

38 re fine mapping and developing SNP chips for marker-assisted breeding.

39 int objectives such as map-based cloning and marker-assisted breeding.

40 We present a theoretical evaluation of marker-assisted congenic production and provide the empi

41 truction of genome-wide physical maps, rapid marker-assisted construction of congenic strains, and ev

42 Personalized medicine, the use of marker-assisted diagnosis and targeted therapies derived

43 rees, and constitutes the first step towards marker-assisted disease resistance breeding in white pin

44 -B1 and Snn1-B2 genes and will be useful for marker-assisted elimination of these genes for better ho

45 in relation to TE polymorphism and applying marker-assisted estimations of CO frequencies to isogeni

46 eloped in this study will aid in cloning and marker assisted gene pyramiding of LrAp.

47 In conclusion, we performed marker-assisted gene identification of aesthetic traits

48 s (QTL) for tissue-specific function using a marker-assisted genetic approach.

49 -wide integrated approach have potential for marker-assisted genetic improvement and unravelling the

50 populations and detection systems useful for marker-assisted improvement of the world's leading fiber

51 The efficiency of marker-assisted introgression in backcross populations d

52 ties are now routinely calculated in genetic marker-assisted parentage analyses to indicate the stati

53 A fine mapping experiment, followed by marker-assisted progeny testing for selected recombinant

54 study presents the initial step for further marker-assisted research on Colias butterflies, includin

55 lleles, and has the potential application in marker assisted rice breeding programmes to develop cult

56 The data reported here is expected to aid in marker-assisted seedling selection (MASS) targeted towar

57 tification of major salt tolerance genes and marker assisted selection (MAS) can accelerate wheat bre

58 In order to employ marker assisted selection (MAS) to select a high oleic d

59 The identified QTL can be used for marker assisted selection in breeding wheat for improved

60 QTL can be used for further fine mapping and marker assisted selection in peanut breeding programs.

61 ers identified in this study can be used for marker assisted selection using haplotype blocks as a wh

62 gronomic and medicinal traits, and molecular marker assisted selection will be used increasingly.

63 making it a useful technology for performing marker assisted selection.

64 ic background of another inbred strain using marker assisted selection.

65 a single chromosome, which can be useful for marker assisted selection.

66 lect the most appropriate markers for use in marker assisted selection.

67 uced a valuable resource that can be used in marker assisted selection.

68 s to select the most appropriate markers for marker assisted selection.

69 in genetic mapping, germplasm evaluation and marker assisted selection.

70 Marker-assisted selection (MAS) combined with traditiona

71 The publicly reported limited application of marker-assisted selection (MAS) in wheat breeding progra

72 loci (QTL) and subsequent implementation of marker-assisted selection (MAS) mating schemes.

73 Marker-assisted selection (MAS) methods to increase N(e)

74 These QTL could be used in marker-assisted selection (MAS) programs for MDV resista

75 candidate gene markers will be valuable for marker-assisted selection (MAS) programs to rapidly intr

76 ey provide a solid foundation for developing marker-assisted selection (MAS) strategies and functiona

77 The application of marker-assisted selection (MAS) to breeding programmes d

78 kers identified will be useful for potential marker-assisted selection (MAS) to control sex-ratio in

79 loci (QRLs) controlling QDR can be used for marker-assisted selection (MAS) to incorporate these val

80 uding quantitative trait loci (QTL) mapping, marker-assisted selection (MAS), and cutting-edge CRISPR

81 These markers provide valuable tools for marker-assisted selection (MAS), facilitating the breedi

82 or Phytophthora crown rot resistance through marker-assisted selection (MAS).

83 bread wheat to tolerate low P stress through marker-assisted selection (MAS).

84 d the subsequent use of this information for marker-assisted selection (MAS).

85 mated QTL allelic values, a technique called marker-assisted selection (MAS).

86 ially tagging the Sr38 gene could be used in marker-assisted selection after validating them in addit

87 Implementation of marker-assisted selection and breeding programs is sever

88 rovides a solid basis for self-compatibility marker-assisted selection and for positional cloning of

89 e genetic improvement of tomato through both marker-assisted selection and genomic selection.

90 ing the nutritional content of crops through marker-assisted selection and metabolic engineering.

91 eful for map-dependent applications, such as marker-assisted selection and positional cloning of gene

92 us use of these markers in non-linkage based marker-assisted selection approaches, such as paternity

93 s in this study supports the hypothesis that marker-assisted selection can be used to decrease the ra

94 ccess in genome-wide association studies and marker-assisted selection depends on good phenotypic and

95 Marker-assisted selection for FHB resistance QTL on 3BS

96 easured, and it offers major advantages over marker-assisted selection for highly polygenic traits.

97 conditions and provide a starting point for marker-assisted selection for plasticity.

98 es, in which the allele was not present, and marker-assisted selection for the beneficial allele in l

99 ber related traits, comparative genomics and marker-assisted selection for the breeding of TK.

100 ues such as SNP genotyping, QTL mapping, and marker-assisted selection for the development of FW resi

101 ping, isolation of resistance genes, and for marker-assisted selection for the LR resistance in barle

102 ible marker has been developed, facilitating marker-assisted selection for TuMV resistance in B. junc

103 Marker-assisted selection has proven to be an effective

104 is, screening of large insert libraries, and marker-assisted selection in breeding.

105 oybean breeders who increasingly depend upon marker-assisted selection in cultivar improvement.

106 s for genetic improvement, fine mapping, and marker-assisted selection in future studies.

107 ower lines, providing a very useful tool for marker-assisted selection in sunflower breeding programs

108 ing these QTLs is immediately applicable for marker-assisted selection in white lupin breeding.

109 ation offer significant potential for use in marker-assisted selection in yellow lupin.

110 The potential usefulness of the 4443 SNP in marker-assisted selection is currently being evaluated i

111 The efficiency of the marker-assisted selection method increases with increasi

112 This strain was produced by using a marker-assisted selection method to eliminate unlinked A

113 Marker-assisted selection minimises these drawbacks, but

114 This information may be used in molecular marker-assisted selection of cattle breeding in the futu

115 QTL mapping also provides a framework for marker-assisted selection of complex disease resistance

116 ies in non-model tree species and may enable marker-assisted selection of Norway spruce adapted to se

117 ZQ response showed recessive inheritance and marker-assisted selection of parasites at a single Sm.TR

118 powdery mildew resistance will be useful for marker-assisted selection of Pm5e in wheat breeding prog

119 nd demonstrated its potential application in marker-assisted selection of PRSV resistance in bottle g

120 the cloning, functional characterization and marker-assisted selection of Sbwm1.

121 igh-resolution map to facilitate cloning and marker-assisted selection of the major dormancy gene.

122 such information could be used to implement marker-assisted selection of young bulls tested in the p

123 pecies into elite chickpea varieties through marker-assisted selection or gene-editing.

124 fy molecular markers to enhance N uptake via marker-assisted selection or genomic selection in spinac

125 inor additive BVs suggests performing either marker-assisted selection or genomic selection or both.

126 ify quantitative trait loci (QTL), implement marker-assisted selection or introgression and YAC conti

127 ment of breeding lines for the trait through marker-assisted selection or through forward breeding ap

128 if the mating ratio is large so that a high marker-assisted selection pressure on the rarer sex can

129 digree tracking information, will accelerate marker-assisted selection programs to enhance the develo

130 ked to these QTL could be used in genomic or marker-assisted selection programs to improve biomass qu

131 The identified QTL can be applied in marker-assisted selection programs to improve the resist

132 , therefore these QTL could be utilised in a marker-assisted selection scheme to increase host resist

133 association mapping, and applied breeding in marker-assisted selection schemes.

134 hese findings provide a basis for developing marker-assisted selection strategies in sugarcane breedi

135 etic resources, hindering the application of marker-assisted selection strategies.

136 across the entire genome are used to conduct marker-assisted selection such that each quantitative tr

137 roach for molecular breeding will shift from marker-assisted selection to genomic selection.

138 arkers from the QTL region have potential in marker-assisted selection to improve host resistance, pr

139 d be beneficial to be able to use genomic or marker-assisted selection to improve these traits.

140 rs closely linked to the QTLs can be used in marker-assisted selection to improve wheat PM resistance

141 ng technologies can be used as a new type of marker-assisted selection to select for desirable traits

142 Marker-assisted selection was used to backcross selected

143 loitation of these genes in breeding through marker-assisted selection, and may lead to the discovery

144 olecular techniques, such as CRISPR/Cas9 and marker-assisted selection, can be employed to transition

145 Technologies such as genotyping, marker-assisted selection, high-throughput phenotyping,

146 To facilitate marker-assisted selection, QTLs must be detected from th

147 to mitigate their impacts through the use of marker-assisted selection, RNA interference and potentia

148 e resistance, conventional breeding methods, marker-assisted selection, somaclonal variation, pathoge

149 n safflower and highlight candidate loci for marker-assisted selection, supporting the development of

150 With marker-assisted selection, there has been success in bre

151 into cultivated spinach (S. oleracea) using marker-assisted selection, thereby enhancing breeding pr

152 rates the process of animal breeding through marker-assisted selection, which leads to increased resp

153 sociated with the use of Bayesian models for marker-assisted selection, with a focus on the role of t

154 role to play that can now be facilitated by marker-assisted selection.

155 t QTL mapping results and improve success of marker-assisted selection.

156 ical linkage maps for positional cloning and marker-assisted selection.

157 s encouraging for restricted applications of marker-assisted selection.

158 tion for the prediction of genetic values in marker-assisted selection.

159 ed targeting of peanut idiotypes by indirect marker-assisted selection.

160 been constructed and suggested as a tool for marker-assisted selection.

161 identification of genetic markers for use in marker-assisted selection.

162 portunities for improving bull fertility via marker-assisted selection.

163 ple linear regression as would be applied in marker-assisted selection.

164 l trait introgression using backcrossing and marker-assisted selection.

165 used to transfer TaPHS1 in breeding through marker-assisted selection.

166 and potential functional markers for use in marker-assisted selection.

167 of complex traits and predict phenotypes for marker-assisted selection.

168 (-/-)) using a congenic strain developed via marker-assisted selection.

169 nto a widely grown Asian rice cultivar using marker-assisted selection.

170 ent and enhance previous QTL information for marker-assisted selection.

171 he identification of informative markers for marker-assisted trait selection and map-based gene isola

172 p-based cloning, comparative mapping, and in marker-assisted wheat breeding endeavors.