ライフサイエンスコーパス: pollen tube growth

1 ith different ligands at different stages of pollen tube growth.

2 n in a signal transduction pathway mediating pollen tube growth.

3 LePRK2 might participate in signaling during pollen tube growth.

4 ze the mitochondria and contribute to arrest pollen tube growth.

5 in a common pathway with NtRac1 to regulate pollen tube growth.

6 ve been shown to be important regulators for pollen tube growth.

7 ADF1, was used to dissect the role of ADF in pollen tube growth.

8 ins to their normal locations, and inhibited pollen tube growth.

9 ect (segregation 40%:51%:9%) due to aberrant pollen tube growth.

10 lved in perceiving extracellular cues during pollen tube growth.

11 c events required for pollen germination and pollen tube growth.

12 of actin turnover by NtADF1 is critical for pollen tube growth.

13 to be essential during pollen hydration and pollen tube growth.

14 pathway that regulates pollen hydration and pollen tube growth.

15 d in the binding of a specific ligand during pollen tube growth.

16 acquire water from the female, thus enabling pollen tube growth.

17 s controlling the irreversible inhibition of pollen tube growth.

18 cium is essential for pollen germination and pollen tube growth.

19 e for SUZ1 and ZWI in pollen germination and pollen tube growth.

20 through the S phase of the cell cycle during pollen tube growth.

21 ough the male gametophyte due to a defect in pollen tube growth.

22 at the pea Rop GTPase Rop1Ps is critical for pollen tube growth.

23 len maturation which is essential for normal pollen tube growth.

24 ttracting protein needed for optimal in vivo pollen tube growth.

25 pollen, while NIP4;2 expression peaks during pollen tube growth.

26 luble inorganic pyrophosphatase required for pollen tube growth.

27 imilar pollen myosins had greater defects in pollen tube growth.

28 ect leading to more severe depolarization of pollen tube growth.

29 l-associated TGases are believed to regulate pollen tube growth.

30 reduced germination efficiency, and reduced pollen tube growth.

31 erspecific) pollen through the inhibition of pollen tube growth.

32 a dominant-active form of wild-type LTP5 in pollen tube growth.

33 ss effects on pollen hydration, adhesion and pollen tube growth.

34 rt for a redundant function of AGC1.5/1.7 in pollen tube growth.

35 viability, delayed germination, and aberrant pollen tube growth.

36 the initiation and regulation of oscillatory pollen tube growth.

37 e pollen tubes are important for controlling pollen tube growth.

38 le transmission efficiency due to defects in pollen tube growth.

39 low detailed gene expression analyses during pollen tube growth.

40 egulate PRONE function, leading to polarized pollen tube growth.

41 ng tract and stigma development and impaired pollen tube growth.

42 ly increased medium ATP levels and inhibited pollen tube growth.

43 the effect of overexpressing this isoform on pollen tube growth.

44 urrents of Ca2+, H+, and K+ are critical for pollen tube growth.

45 to previous models for Ca(2+) regulation of pollen tube growth.

46 expression of its putative target genes and pollen tube growth.

47 ckening of the apical cell wall and inhibits pollen tube growth.

48 candidates for important roles in regulating pollen tube growth.

49 ant and we used it to investigate aspects of pollen-tube growth.

50 ling network, resulting in the inhibition of pollen-tube growth.

51 In vitro, GABA stimulates pollen tube growth, although vast excesses are inhibitor

52 importance of the functional connections in pollen tube growth and can help guide future research di

53 Effects of PIP5K6 expression on pollen tube growth and cell morphology were attenuated b

54 l- fluxes are not a significant component of pollen tube growth and Cl- itself is not required for gr

55 ses (PMEs) likely play a central role in the pollen tube growth and determination of pollen tube morp

56 Furthermore, both pollen tube growth and ethylene action were needed for t

57 ses to biotic and abiotic stress, as well as pollen tube growth and fertility.

58 ght of the central role calcium maintains in pollen tube growth and fertilization.

59 llen tube growth in the stigma and style, or pollen tube growth and guidance in the ovary.

60 role for gamma-amino butyric acid (GABA) in pollen tube growth and guidance.

61 tants, implies a role for GABA in regulating pollen tube growth and guidance.

62 s indicate that Rop controls actin-dependent pollen tube growth and H(2)O(2)-dependent defense respon

63 roduction, which fuels single nucleus-driven pollen tube growth and is essential for plant reproducti

64 -P2 act in a common pathway to control polar pollen tube growth and provide direct evidence for a fun

65 ere, we show that mat3 mutants have impaired pollen tube growth and reduced seed set.

66 reeding system was determined by analysis of pollen tube growth and seed production from controlled p

67 the female organs of the flower that support pollen tube growth and sperm cell transfer along the tra

68 ndings provide insight into the mechanism of pollen tube growth and the oscillation of cellular signa

69 Earlier studies of seed-set, pollen-tube growth and progeny fitness suggested that pa

70 1) exhibited ballooned pollen tubes, delayed pollen tube growth, and decreased numbers of fertilized

71 such as pollen tube incompatibility, slower pollen tube growth, and delayed generative cell mitosis.

72 e TT slowed and then arrested N. obtusifolia pollen tube growth, and was developmentally synchronized

73 sion and guidance for pollen germination and pollen tube growth are abundantly present in the extrace

74 Pollen germination and pollen tube growth are thought to require extracellular

75 ered clearly from the metabolic state during pollen tube growth, as indicated by principal component

76 Pollen tube growth assays in vitro and in the pistil dem

77 tion half-maximally at 50 nM, yet it blocked pollen tube growth at one-tenth of that concentration.

78 sure outbreeding by interrupting the path of pollen tube growth before egg-sperm interaction.

79 Polarized exocytosis is critical for pollen tube growth, but its localization and function ar

80 Calcium is a key regulator of pollen tube growth, but little is known concerning the d

81 s thaliana Rho family GTPase, ROP1, controls pollen tube growth by regulating apical F-actin dynamics

82 Inhibition of pollen tube growth caused by mild temperature shock or c

83 and directionality not mimicked in in vitro pollen tube growth cultures.

84 ignaling network, resulting in inhibition of pollen tube growth, cytoskeletal alterations, and progra

85 Ca(2+) availability partially suppresses the pollen tube growth defects, suggesting that LRX proteins

86 tween SI and UI in the tomato clade, in that pollen tube growth differs between these two rejection s

87 ces in our understanding of the mechanism of pollen tube growth, focusing on such basic cellular proc

88 e by examining seed set, pollen fitness, and pollen tube growth for knockout mutants of five of the s

89 role in the regulation of calcium-dependent pollen tube growth, H(2)O(2)-mediated cell death, and ma

90 OP1-overexpression-induced depolarization of pollen-tube growth identified REN1 (ROP1 enhancer 1) in

91 formed pollen tubes and in the inhibition of pollen tube growth in a dose-dependent manner.

92 ulted in reduced pollen adhesion and delayed pollen tube growth in all mutants studied.

93 el that describes vesicle trafficking during pollen tube growth in Arabidopsis (Arabidopsis thaliana)

94 abacum resulted in the loss of inhibition of pollen tube growth in Nicotiana obtusifolia (synonym Nic

95 s characterized by evaluating N. obtusifolia pollen tube growth in normal and TT-ablated N. tabacum s

96 pollen development, pollen germination, and pollen tube growth in other species.

97 Furthermore, the difference of pollen tube growth in syp124/syp125 single and double mu

98 genes required for pollen grain development, pollen tube growth in the stigma and style, or pollen tu

99 nscript levels during stamen development and pollen tube growth in the transgenic trees of a stamen-s

100 Exogenous LeSTIG1 promotes pollen tube growth in vitro.

101 a tabacum (tobacco), TTS protein, stimulates pollen tube growth in vivo and in vitro and attracts pol

102 or female tissues was sufficient to support pollen tube growth in vivo.

103 The majority of pollen-tube growth in Arabidopsis occurs in specialized

104 The phases of pollen tube growth include interactions that establish p

105 s vital and in vitro germination normal, but pollen tube growth inside stylar tissues appeared less d

106 Pollen tube growth is a polarized growth process whereby

107 Pollen tube growth is an essential aspect of plant repro

108 Pollen tube growth is central to the sexual reproduction

109 Pollen tube growth is controlled by a tip-localized ROP1

110 In flowering plants, pollen tube growth is dependent on the actin cytoskeleto

111 Although pollen tube growth is essential for plant fertilization

112 dient and tip-localized Rho-family GTPase in pollen tube growth is established, the existence and fun

113 The claim of a central role for Cl- in lily pollen tube growth is further undermined by the fact tha

114 Pollen tube growth is influenced by interaction between

115 Pollen tube growth is inhibited in the style when its si

116 ycin, antimycin A, and cyanide, we find that pollen tube growth is much less sensitive to respiratory

117 Pollen tube growth is rapid, occurs exclusively at the t

118 he response is biphasic; rapid inhibition of pollen-tube growth is followed by PCD, which is involved

119 ion of the exocytotic machinery depending on pollen tube growth modes.

120 , a sugar alcohol, in flower development and pollen tube growth of apple (Malus domestica).

121 The model results adequately fit the pollen tube growth of both previously reported wild-type

122 peated pattern of faster and longer-distance pollen tube growth often within solid pathways in phylog

123 s pollen tube elongation but does not affect pollen tube growth polarity and shows Rop1-independent l

124 of catalytically modified Pi CDPK1 disrupted pollen tube growth polarity, whereas expression of Pi CD

125 later defects affecting pollen germination, pollen tube growth, polarity or guidance, or pollen tube

126 TTS mRNAs encode a pollen tube growth-promoting and -attracting protein nee

127 nsmitting tissue-specific (TTS) protein is a pollen tube growth-promoting and attracting glycoprotein

128 Comparative analyses point to accelerated pollen tube growth rate as a critical innovation that pr

129 llose-walled growth pattern with accelerated pollen tube growth rate underlies a striking repeated pa

130 etophytes, and arises in part from a reduced pollen tube growth rate.

131 In contrast, pollen tube growth rates of taxa in ancient angiosperm l

132 , and, in monocots and eudicots, much faster pollen tube growth rates.

133 tigmas, pollen development, pollination, and pollen tube growth require spatial and temporal regulati

134 Inhibition of N. obtusifolia and N. repanda pollen tube growth required accumulation of PELPIII in t

135 Pollen tube growth requires a Ca2+ gradient, with elevat

136 netic evidence presented here indicates that pollen tube growth requires cyclic nucleotide-gated chan

137 Pollen tube growth resembles that of polarized metazoan

138 als from female tissues to elicit the proper pollen tube growth response during pollination.

139 use severe defects in pollen germination and pollen tube growth, resulting in a reduced seed set.

140 e of sterility was identified as a defect in pollen tube growth, resulting in tubes that were kinky,

141 h predictions made by a mechanical model for pollen tube growth revealed the importance of pectin dee

142 n tubes and reduced its inhibitory effect on pollen tube growth significantly, suggesting that phosph

143 Pollen tube growth stops for several minutes before resu

144 nteractions and the precision of directional pollen tube growth suggest that signals are continually

145 lay a crucial role in pollen germination and pollen tube growth, the proteins that mediate their acti

146 its known role in transporting sperm during pollen tube growth, the vegetative cell also contributes

147 Pollen Receptor-Like Kinases (PRKs) control pollen tube growth through the pistil in response to ext

148 This occurs by facilitating pollen-tube growth through differentiation and then deat

149 a indicate that the increased sensitivity of pollen tube growth to LATB was not due to general destab

150 fertilization process, including guidance of pollen tube growth to the female gametophyte.

151 ing or the actin cytoskeleton, then examined pollen tube growth using fluorescent protein markers tha

152 an essential role in stamen development and pollen tube growth via MdMYB39L in apple.

153 ning of pollinated pistils demonstrated that pollen tube growth was affected only when both parents b

154 In order to address this question, pollen tube growth was measured after inter-specific cro

155 pool was necessary to half-maximally inhibit pollen tube growth, whereas a approximately 100% increas

156 rane at the tip and caused depolarization of pollen tube growth, which was less severe than that indu

157 ecreased pollen germination rate and reduced pollen tube growth, which were all closely related to lo

158 screen and select among male gametes during pollen tube growth within the female tissues of the stig