ライフサイエンスコーパス: plant breeding

1 ractions can ultimately be incorporated into plant breeding.

2 uctural and molecular biology, genetics, and plant breeding.

3 hybridization events associated with recent plant breeding.

4 from only one parent can greatly accelerate plant breeding.

5 romise to greatly increase the efficiency of plant breeding.

6 cientists in the areas of bioinformatics and plant breeding.

7 concepts and have important implications for plant breeding.

8 ic-assisted selection paradigm in animal and plant breeding.

9 dely used in functional genomic analysis and plant breeding.

10 tudy of maize genetics and evolution and for plant breeding.

11 is in the development of tools for molecular plant breeding.

12 diversity and are useful for accelerated tea plant breeding.

13 t role in higher plant evolution and applied plant breeding.

14 plants and may have a significant impact on plant breeding.

15 relatives for use in comparative studies and plant breeding.

16 and additive variance, need to be retired in plant breeding.

17 nizing numerous scientific domains including plant breeding.

18 trait subject to both natural selection and plant breeding.

19 ributing to more informed decision-making in plant breeding.

20 reases crop yields is a primary objective in plant breeding.

21 rop productivity is a pivotal goal in modern plant breeding.

22 omosome recombination works is essential for plant breeding.

23 orming the pace of agricultural research and plant breeding.

24 is one of the most powerful -omics to assist plant breeding.

25 to advance data-driven, phytochemical-based plant breeding.

26 ompatible climate-adapted wild varieties for plant breeding.

27 al processes and have direct applications in plant breeding.

28 a species is necessary for conservation and plant breeding.

29 nes, from personal medicine and nutrition to plant breeding.

30 ide a significant tool for genomics-assisted plant breeding.

31 hod to predict breeding values in animal and plant breeding.

32 om wild relatives has often been adaptive in plant breeding.

33 erful ML for prediction enabled prescriptive plant breeding.

34 cted mechanisms for genome engineering-based plant breeding.

35 CRISPR-Cas9 technology is fully realized in plant breeding.

36 real grains, wheat, rice, and maize, through plant breeding.

37 technology with a potential to revolutionize plant breeding.

38 ailability of crop wild relatives for use in plant breeding.

39 has the potential to dramatically transform plant breeding.

40 of evolutionary biology, human genetics and plant breeding.

41 cal importance for seed set and for targeted plant breeding.

42 section of complex traits and support modern plant breeding.

43 s poised to revolutionise basic research and plant breeding.

44 rmance and increase the efficiency of modern plant breeding.

45 the potential of epigenome manipulations for plant breeding.

46 racteristic for the fixation of heterosis in plant breeding.

47 its the exploitation of genetic variation by plant breeding.

48 method as a promising alternative for GS in plant breeding.

49 omatin, a feature potentially exploitable in plant breeding.

50 udy offer valuable insights into AI-mediated plant breeding, addressing challenges faced by tradition

51 Plant breeding aims to improve current germplasm that ca

52 Plant breeding alone, however, cannot drive adoption of

53 d composition improvement is a major goal of plant breeding and biotechnology.

54 nary biology and in the fields of animal and plant breeding and conservation.

55 Polyploidization has played a key role in plant breeding and crop improvement.

56 effective transfer of current knowledge into plant breeding and crop management strategies that will

57 ait coordination is essential for successful plant breeding and crop modeling.

58 gy as a plant genome editing tool to enhance plant breeding and crop research needed to meet growing

59 Plant breeding and crop research rely on experimental ph

60 ations for fungal development, epidemiology, plant breeding and disease control.

61 olyploid species is central to understanding plant breeding and evolution.

62 gricultural scientists have carried out both plant breeding and genetic engineering research.

63 e grain yield has been a major focus of both plant breeding and genetic engineering to meet the globa

64 lation and evolutionary genetics, animal and plant breeding and human genetics.

65 Male sterility is a valuable trait for plant breeding and hybrid seed production.

66 Male sterility is an important tool for plant breeding and hybrid seed production.

67 aluated in targeted selection strategies for plant breeding and improvement.

68 e a potential role of transgressive sRNAs in plant breeding and in natural evolution with wild plants

69 ecoming increasingly important in animal and plant breeding and is also receiving attention in human

70 as received enormous attention in animal and plant breeding and is making inroads into human and even

71 Both plant breeding and molecular technologies have been used

72 The analogy between plant breeding and natural selection indicates that the

73 ity of gametes, which should prove useful in plant breeding and other applications.

74 Plant breeding and propagation widely use haploid embryo

75 s can be modified genetically, which may aid plant breeding and selection efforts.

76 ify the value of candidate traits for use in plant breeding and to project the impact of climate chan

77 c prediction being widely used in animal and plant breeding, and increasingly in human genetics.

78 ecting for quantitative traits in animal and plant breeding, and offers a potentially superior altern

79 t resources for legume comparative genomics, plant breeding, and plastid genetic engineering, while s

80 translated into a potential future tool for plant breeding, and share the story of researcher Simon

81 breeding applications, we present the public plant Breeding Application Programming Interface (BrAPI)

82 to predict compatibility of pair-crosses in plant breeding applications, to analyze segregation dist

83 New plant breeding approaches are needed to meet this challe

84 ed selection (MAS) combined with traditional plant breeding approaches is considered best to improve

85 Here we compare and contrast some animal and plant breeding approaches to make a case for bringing th

86 Through strategic plant breeding approaches, it is possible to increase th

87 The implications of research on QR for plant breeding are discussed.

88 e role of sRNAs and their potential value to plant breeding are limited by an incomplete picture of s

89 Domestication and plant breeding are ongoing 10,000-year-old evolutionary

90 This positions plant breeding as a major technological contributor in t

91 iofortified maize is being developed through plant breeding as a sustainable agronomic approach to al

92 Apomixis has a revolutionary potential in plant breeding, as it could allow the instant fixation a

93 te this diversity, exploit its potential for plant breeding, as well as understand its biological sig

94 volution and also plays an essential role in plant breeding, because a successful breeding program de

95 of phenotypic diversity and serve to advance plant breeding by exploring genetic variation across div

96 on of genome editing introduced a new era of plant breeding by giving researchers efficient tools for

97 uable resource within the wheat research and plant breeding communities.

98 lations are currently being developed in the plant-breeding community because linkage associations pr

99 of academic plant scientists teaming up with plant breeding companies and straw processing companies

100 site-specific level, enviromics could inform plant breeding decisions across varying conditions and a

101 Agricultural yield and plant breeding depend on understanding and consequently

102 tic resource collections can greatly enhance plant breeding/domestication efforts and support plant g

103 cluding considering existing alternatives to plant breeding (e.g. management strategies), minimising

104 ity of manipulating recombination to enhance plant breeding efficiency.

105 oubled haploid plants can greatly accelerate plant breeding efficiency; however, despite successful e

106 We estimate that future plant breeding efforts aimed at HI improvement to the th

107 While plant breeding efforts have greatly benefited from advan

108 is orphan crop, and will be vital for future plant breeding efforts.

109 is important for general genetic studies and plant-breeding efforts.

110 For any plant breeding endeavor to be effective, a variety of ge

111 nt defenses for plant ecology as well as for plant breeding/engineering are explored, and the need fo

112 Phenotyping is the current bottleneck in plant breeding, especially because next-generation seque

113 To maximize the potential of genomics for plant breeding, experiments must be further miniaturized

114 f prime importance in human nutrition and in plant breeding for cultivar identification and improveme

115 thout fertilization, also can be valuable in plant breeding for doubled haploid production.

116 ution power of these algorithms in practical plant breeding for heterotic grouping identification.

117 gn in the future, especially with respect to plant breeding for infertile soils.

118 to be an effective strategy in accelerating plant breeding for many plant species.

119 imitations by enabling advanced genetics and plant breeding for new cultivars with improved yield and

120 Conventional plant breeding for resistance has an important role to p

121 Factors and mechanisms that can aid in plant breeding for salt stress tolerance are therefore o

122 tolerance in barley is a critical aspect of plant breeding for stress resilience. Therefore, a folia

123 rol programs including homestead production, plant breeding, fortification, and supplementation are i

124 reproduction, providing insights critical to plant breeding, genetics and agriculture.

125 Over the years, quantitative genetics in plant breeding has become increasingly empirical and com

126 diction was efficient and its application in plant breeding has been justified.

127 As with other agricultural sciences, plant breeding has primarily been conducted in the conte

128 of hybridization, selection, adaptation and plant breeding has shaped the genetic makeup of modern b

129 Since the dawn of agriculture, plant breeding has targeted the harvest index as a main

130 Plant breeding has traditionally relied on combining the

131 thetic fertilisers, pesticides, and improved plant breeding, has greatly increased food production.

132 n nutrition but for plant nutrition as well, plant breeding holds great promise for making a signific

133 of machine learning approaches in practical plant breeding; however, more accurate and robust cluste

134 x trait, but may not be directly relevant to plant breeding if they are not detected from the breedin

135 Since the advent of modern plant breeding in the 1930s, North American maize has un

136 hus, siR109944 provides a genetic target for plant breeding in the future.

137 a significant resource for biotechnology and plant breeding initiatives.

138 ity impacts to identify concrete targets for plant breeding innovation as a food systems solution.

139 Application of machine learning in plant breeding is a recent concept, that has to be optim

140 However, plant breeding is currently limited by incremental impro

141 ing approach for increasing genetic gains in plant breeding is genomic selection.

142 While plant breeding is important, institutional innovations i

143 asis for genomic selection in the context of plant breeding is still being debated.

144 Long-accepted plant breeding methods for incorporating new diversity i

145 Conventional plant-breeding methods can improve both agronomic and me

146 We used methods that combine plant breeding, molecular biology, and genomics to ident

147 cs including studies in evolution, genetics, plant breeding, molecular biology, biochemistry and syst

148 can further prompt novel protocols to assist plant breeding of sugar beet in the pursuit of improved

149 e context of experimental biology and animal/plant breeding of the period and review both the well-kn

150 ds, there are limited studies on the role of plant breeding on this sustainability metric.

151 ut it is possible to enhance this content by plant breeding or by inserting the gene for ferritin int

152 of specific carotenoids in plastids through plant breeding or genetic engineering requires an unders

153 Plant breeding plays a pivotal role in the development o

154 However, with realistic plant breeding population sizes, diversity depletion in

155 cting the breeding value of individuals in a plant breeding population.

156 h as colchicine, has been widely employed in plant breeding precisely to this end.

157 nheritance of traits emerged from an applied plant breeding program.

158 because it is a percentile commonly used in plant breeding programmes (for example, at CIMMYT).

159 agronomic traits as targets for selection in plant breeding programmes is increasingly common.

160 The food industry and plant breeding programmes require fast, clean and low-co

161 interactions, creating new opportunities for plant breeding programmes towards management of RKNs.

162 racteristics suitable to be taken forward in plant breeding programmes.

163 d function of immune-related RBPs can inform plant-breeding programmes to generate crops with increas

164 ance of flavor for consumer preference, most plant breeding programs have neglected it, mainly becaus

165 Testers are important in many plant breeding programs to enhance efficiency of RRS, an

166 Genomic selection has become a reality in plant breeding programs with the reduction in genotyping

167 n facilitate genomic selection in animal and plant breeding programs, and can aid in the development

168 for disease resistance is a central focus of plant breeding programs, as any successful variety must

169 rence of foods and is an increasing focus of plant breeding programs.

170 useful alleles or genes absent in commercial plant breeding programs.

171 cycles and advanced generation selections in plant breeding programs.

172 shelf life to aid in implementing effective plant breeding programs.

173 urces of genetic and phenotypic diversity in plant breeding programs.

174 mbers of muskmelon and watermelon samples in plant breeding programs.

175 ental-regulatory genes that are important in plant breeding programs.

176 les typical of production quality systems or plant breeding programs.

177 se for increasing recombination frequency in plant-breeding programs.

178 The aim of many plant breeding projects is to improve the consumers' fla

179 line Mp708, which was developed by classical plant breeding, provides enhanced resistance to CLA.

180 Plant breeding relies on crossing-over to create novel c

181 This article describes ongoing plant breeding research that could increase the intake o

182 an essential tool in population genetics and plant breeding research, yet user-friendly online tools

183 of genomic selection to reshape traditional plant breeding schemes.

184 itigation from rice agriculture, alternative plant breeding strategies may be needed, along with alte

185 The 3 most promising plant breeding strategies toward this goal are as follow

186 tionary dynamics of gynodioecy, a widespread plant breeding system.

187 * The diversity of plant breeding systems provides the opportunity to study

188 e assembled a dataset of island and mainland plant breeding systems, focusing on the presence or abse

189 Amongst gynodioecious plant breeding systems, there can exist intermediate mor

190 ability towards transformation and other new plant breeding techniques.

191 ongly influenced by host genetic factors and plant breeding than bacterial communities, a finding tha

192 In plant breeding, the main focus of quantitative genetics

193 The results have implications for plant breeding: the existence of a mutant that is both A

194 ances in plant genomics are being applied to plant breeding, thereby enabling rapid development of ne

195 generation time, which prolongs research and plant breeding timelines.

196 backcrossing are commonly used in animal and plant breeding to induce heritable variation including e

197 engineering have paved the way to accelerate plant breeding to meet this increasing demand.

198 ed 80 years ago for the study of large-scale plant breeding trials.

199 election holds a great promise to accelerate plant breeding via early selection before phenotypes are

200 in plants, and the use of such mutations in plant breeding was a major factor in the success of the

201 the genetic bottlenecks of introduction and plant breeding was mostly due to the small number of Asi

202 tion rate, which is an interesting trait for plant breeding, were identified by QTL analyses using th

203 otential crosses plays a significant role in plant breeding, which aims to produce new crop varieties

204 that the application of NGS technologies to plant breeding will help us to meet the challenge of fee

205 been freely available to use for farming and plant breeding without restriction.

206 Plant breeding would benefit from borrowing approaches f