ライフサイエンスコーパス: cotton fiber

1 ineating the evolutionary basis of spinnable cotton fiber.

2 nforced the multilayered architecture of the cotton fiber.

3 ould lead to novel ways to engineer superior cotton fiber.

4 elongation, such as occurs in the developing cotton fiber.

5 ful in genetic engineering schemes to modify cotton fiber.

6 nanoparticles throughout an entire volume of cotton fiber.

7 de insights into and resources for improving cotton fiber.

8 likely due to the presence of an intraocular cotton fiber.

9 e cellulose biosynthesis stage in developing cotton fibers.

10 on species producing over 90% of the world's cotton fibers.

11 for alternative mRNA isoforms in developing cotton fibers.

12 een microtubules and actin microfilaments in cotton fibers.

13 aments, but never with axial actin cables in cotton fibers.

14 lpha-tubulin transcript levels in elongating cotton fibers.

15 ial sequencing of anonymous cDNA clones from cotton fibers.

16 ndary wall cellulose synthesis in developing cotton fibers.

17 ormal development or structural integrity of cotton fibers.

18 fabric was limited by the size of the native cotton fibers.

19 Based on work with cotton fibers, a particulate form of sucrose (Suc) synth

20 h seed, which helps explain how thousands of cotton fibers achieve their great length within a confin

21 al examination revealed retained intraocular cotton fiber along the inferotemporal quadrant over the

22 Developing cotton fibers also exhibited GFP fluorescence suggesting

23 the inherent reducing agents present in raw cotton fiber and embedded within the fiber matrix.

24 atin structures to phenotypic differences in cotton fiber and identified regulatory variations that d

25 hromatin structures of two subgenomes in the cotton fiber and offers a new insight into the regulator

26 cotton wipes through the nanoengineering of cotton fibers and investigates their mineralization beha

27 hat improved the interfacial bonding between cotton fibers and the matrix.

28 PME extracted from tomato seeds, cotton fibers, and melon fruit showed pH optima of 6, 6,

29 ic immunolocalization of sucrose synthase in cotton fibers, and phylogenetic relationships between ce

30 uality of textiles that can be produced from cotton fibers, and therefore are important consideration

31 characterization of rapid cell elongation in cotton fibers, approximately 14,000 unique genes were as

32 Cotton fibers are aerial trichoblasts that employ a high

33 Cotton fibers are single cells that develop from the epi

34 Cotton fibers are single-celled seed trichomes of major

35 Cotton fibers arise through highly anisotropic expansion

36 In this study, we developed a cotton fiber-based piezoresistive textile (CF p-textile)

37 ic plastics, films prepared from low-quality cotton fibers can easily degrade in the natural environm

38 me and metabolome during the early stages of cotton fiber cell development using a combination of spa

39 GhTCP4 plays an important role in balancing cotton fiber cell elongation and wall synthesis.

40 Cotton fiber cells are developmentally synchronous, high

41 We compared RNA and DNA from cotton fiber cells at five developmental time points fro

42 Cotton fiber cells serve as an excellent model for study

43 decreased from 3 to 8-DPA in the developing cotton fiber cells while transcript levels remained low.

44 e compartmentalized functions of proteins in cotton fiber cells, we developed a label-free liquid chr

45 nvolvement of ethylene in the development of cotton fiber cells.

46 nd specific activities on pectic material in cotton fibers compatible with their use in the scouring

47 Mature cotton fiber consists of nearly pure cellulose.

48 eld emission-scanning electron microscopy of cotton fibers developing in situ within the boll demonst

49 the potential regulatory roles of miRNAs in cotton fiber development and the importance of miRNAs in

50 Cotton fiber development entails complex genome-wide gen

51 During cotton fiber development from 10 to 21 DPA, the GhKCBP p

52 The role of microRNAs (miRNAs) during cotton fiber development remains unclear.

53 ta indicate significant roles of laccases in cotton fiber development, and presents an excellent oppo

54 ription factors are likely to play a role in cotton fiber development, the molecular evolutionary pro

55 istribution of gene networks responsible for cotton fiber development, we investigated the distributi

56 g a reference dataset for further studies on cotton fiber development.

57 s that TCP genes may play important roles in cotton fiber development.

58 pid functional analysis of genes involved in cotton fiber development.

59 se miRNAs, which are potentially involved in cotton fiber development.

60 s but little is known how microRNAs regulate cotton fiber development.

61 ndicating that BR plays an important role in cotton fiber development.

62 highly expressed in the elongation stages of cotton fiber differentiation, suggesting a role of this

63 n factor genes are specifically expressed in cotton fiber during different developmental stages, incl

64 mains uncloned and the underlying pathway of cotton fiber elongation is still unclear.

65 sA1 ZnBD is rapidly degraded when exposed to cotton fiber extracts, whereas the oxidized dimer is res

66 em indicates that the N-terminal portions of cotton fiber GhCesA1 and GhCesA2 containing these domain

67 present work, we show that the half-life of cotton fiber GhCesA1 protein is <30 min in vivo, far les

68 In cotton fibers, GhKCH1 decorated cortical microtubules in

69 d scalable strategy for direct MOF growth on cotton fibers grafted via the diazonium chemistry.

70 This observation suggests that in developing cotton fibers, increased mitochondrial sublimon replicat

71 n wildtype Xu-142, 26 miRNAs are involved in cotton fiber initiation and 48 miRNAs are related to pri

72 ng different developmental stages, including cotton fiber initiation and early development.

73 Among 54 miRNAs, 18 miRNAs were involved in cotton fiber initiation and eight miRNAs were related to

74 YB genes previously shown to be expressed in cotton fiber initiation were examined.

75 nsights into regulatory processes underlying cotton fiber initiation.

76 the crucial role of GhBEE3/Gh_A09G062900 in cotton fiber initiation.

77 Cotton fiber is a single-celled seed trichome of major b

78 Cotton fiber is an economically important seed trichome

79 Cotton fiber is the most valuable naturally available ma

80 orld's dominant renewable textile fiber, and cotton fiber is valued as a research model because of it

81 s been developed that introduces copper into cotton fibers, latex, and other polymeric materials.

82 The economic value of cotton fiber lies in its length and quality.

83 the superior yield and quality of tetraploid cotton fibers may be explained by accelerated Dt to At c

84 Cotton fiber membranes synthesize sitosterol-cellodextri

85 ast two-hybrid system to identify a putative cotton fiber metallothionein and to confirm it as a prot

86 fiber tips and consolidated by adhesion of a cotton fiber middle lamella (CFML).

87 turonans and xyloglucans in the formation of cotton fiber middle lamella and contributing to fiber pl

88 sms that govern developmental programming of cotton fiber morphogenesis in these two cultivated speci

89 cell, using as a model the seed trichomes ("cotton fiber") of allopolyploid (containing "A" and "D"

90 Further, analysis of cotton fiber phenolic compounds showed an overall decrea

91 The single-celled cotton fibers, produced from seed coat epidermal cells a

92 iosynthesis in developing fiber might affect cotton fiber properties.

93 rove coverage and functional analyses of the cotton fiber proteome as a function of developmental tim

94 and distinct supramolecular structure of the cotton fiber provided a favorable environment for the co

95 nisms of cell polarized growth and improving cotton fiber quality.

96 ion in plants and could play crucial role in cotton fiber quality.

97 g of allopolyploidy, which will help improve cotton fiber quality.

98 D) genome architecture of the allotetraploid cotton fiber, representing a typical single cell undergo

99 ton KCBP homolog GhKCBP were isolated from a cotton fiber-specific cDNA library.

100 New data are included on phosphorylation of cotton fiber sucrose synthase, possible regulation by Ca

101 This cotton-fiber system provides a high sensitivity of 17.73

102 be encouraged to 'self-fumigate' nests with cotton fibers that have been treated with permethrin.

103 The films were prepared from low-quality cotton fibers through dissolution in DMAc/LiCl, casting,

104 Overall, the results reveal diverse cotton fiber tip morphologies and support primary wall s

105 nd impacts on the ongoing efforts to improve cotton fiber traits.

106 are responsible for cellulose production in cotton fiber, very limited numbers of GhCesA genes have

107 ivity and biochemical analysis of developing cotton fibers was performed using G. arboreum species.

108 The modified cotton fibers were incorporated into nonwoven wipes usin

109 Cotton fibers, which deposit almost pure cellulose into

110 Results showed that cotton fibers with a slight prefibrillation and hydropho