ライフサイエンスコーパス: whorl

1 hospholipid-containing membrane structures ('whorls').

2 autonomous inhibitor of DEF activity in this whorl.

3 ional stamen primordia interior to the third whorl.

4 sia, the diaphragm is derived from the petal whorl.

5 to AGAMOUS (AG) misexpression in the second whorl.

6 undaries of homeotic gene expression between whorls.

7 phenotypes observed in the first and second whorls.

8 incisures, disordered ROS tips, and membrane whorls.

9 d at the boundaries between different floral whorls.

10 pecially in the 2nd (petal) and 3rd (stamen) whorls.

11 mber and several defects in each of the four whorls.

12 wer number of internal vesicles and membrane whorls.

13 r stamens) but decreased allocation to other whorls.

14 B and C gene expression in the reproductive whorls.

15 sformation of floral organs in the outer two whorls.

16 oncentric regions of floral meristems called whorls.

17 plays a role in repression of plena in outer whorls.

18 control organ separation within and between whorls.

19 rtitioned into four developmentally distinct whorls.

20 e and the production of small electron-dense whorls.

21 promoter early and globally in newly forming whorls.

22 andom reduction of organs in the outer three whorls.

23 anomalous concentric SR structures known as whorls.

24 te staminate and pistillate unisexual flower whorls.

25 ntagonize the C-function in the outer floral whorls.

26 eads to formation of unusual, large membrane whorls.

27 k into multiple, micrometer-sized concentric whorls.

28 misaligned outer segment discs and membrane whorls.

29 (AP2) promotes sepal and petal identities in whorls 1 and 2 and restricts the expression of the C-cla

30 ession of the C-class gene AGAMOUS (AG) from whorls 1 and 2.

31 sual B class mutant that exhibits defects in whorl 2 where sepals develop in place of petals, but thi

32 makes a major contribution to morphology in whorl 2, irrespective of the allele.

33 ults in homeotic conversions of floral organ whorls 2 and 3 into sepals and carpelloid structures, re

34 xhibit equivalent phenotypic defects in both whorls 2 and 3.

35 n all three layers of the floral meristem in whorls 2 and 3.

36 ification of the boundary between stamens in whorl 3 and carpels in whorl 4, as superman mutants exhi

37 /carpel whorl boundary (the boundary between whorl 3 and whorl 4) in Arabidopsis.

38 al and spatial patterns of SUP expression in whorl 3 floral meristems.

39 st L1 expression is largely unable to rescue whorl 3, possibly because of a non-autonomous inhibitor

40 hange in whorl 4 or the overproliferation of whorl 3.

41 uit that creates the correct position of the whorl 3/whorl 4 boundary.

42 creates the correct position of the whorl 3/whorl 4 boundary.

43 s originate from an organ identity change in whorl 4 or the overproliferation of whorl 3.

44 l boundary (the boundary between whorl 3 and whorl 4) in Arabidopsis.

45 ry between stamens in whorl 3 and carpels in whorl 4, as superman mutants exhibit supernumerary stame

46 mens in superman mutants arise from cells in whorl 4, which change their fate from female to male, wh

47 ailed to accumulate miR172 in the developing whorls, although accumulation was detected at the base o

48 boundaries between organ primordia within a whorl and boundaries of homeotic gene expression between

49 tion become restricted to the equator of the whorl and then to patches which define where secondary t

50 ed species in that the flowers have only two whorls and are truly unisexual.

51 ration of stamenoid perianth organs in inner whorls and complete loss of carpels.

52 tant 'Pukekohe dwarf' with multiple perianth whorls and extended petaloid features.

53 s were found to be non-random around the two whorls and four generalizations relating the marked and

54 elops independently from the orthodox floral whorls and is best interpreted as a late elaboration of

55 ng the mutant channels accumulate membranous whorls and multicompartment vacuoles, hallmarks of degen

56 display remarkable floral phenotypes: floral whorls and organ numbers are reduced and the floral orga

57 Hair whorls and other macroscopic hair patterns are found in

58 ort diverse phyllotaxis in leaves, including whorls and spirals.

59 nes can cause swirling patterns indicated by whorls and tufts of hairs in the wings and the abdomen o

60 tereotyped whorls on the hind feet, variable whorls and tufts on the head, and misorientation of hair

61 ese proteins induced formation of karmellae, whorls, and crystalloid OSER structures.

62 ransference of petal function between floral whorls, and recurrent petal evolution.

63 ir follicles is disrupted, leading to waves, whorls, and tufts, each comprising many hundreds of hair

64 all traits studied (shell height, number of whorls, and two variables obtained from geometric morpho

65 These inclusions were composed of membrane whorls, apparently derived from the ER.

66 hat the radial symmetries that emerge in the whorl are established by a system of positional coordina

67 al replacement, while their symphyseal tooth whorls are comparable to chondrichthyan and osteichthyan

68 late in development, after the other floral whorls are fully developed.

69 s interesting that adjacent petal and stamen whorls are most strongly affected.

70 d snails, the shells are open-coiled and the whorls are unattached.

71 the microtubules form loose bundles that are whorled around the nucleus.

72 s in which leaf primordia are initiated in a whorled arrangement.

73 s and organs, supernumerary organs in floral whorls, arrested development of axillary meristems, late

74 differentiation of a distinct second floral whorl as opposed to specifying petal identity per se.

75 al part of the TCA pathway, and form a dense whorl at the border between dorsal and ventral thalamus.

76 The detection of LEUNIG mRNA in all floral whorls at the time of their inception suggests that the

77 nts display skin defects including linear or whorled atrophic and pigmentary lesions, striated hyperk

78 involved in maintenance of the stamen/carpel whorl boundary (the boundary between whorl 3 and whorl 4

79 the number of floral organs in the inner two whorls, but also in the second whorl of the flower.

80 ess the transcription of AG in the inner two whorls, but instead counteracts AG activity.

81 on of a membrane structure, identified as ER whorls by electron microscopy.

82 delay, skeletal abnormalities, multiple hair whorls, cardiac, and neurological issues, symptoms that

83 made and found to be a ridge with the fourth whorl carpels at the summit and the first whorl transver

84 The loss of petal identity in these second whorl cells does not result from ectopic AG expression,

85 cluding repression of AGAMOUS (AG) in second whorl cells, promotion of petal epidermal cell identity,

86 redundantly with AP2 to repress AG in second whorl cells.

87 nded lysosome population containing membrane whorls characteristic of lysosomal storage diseases.

88 Posterior embryotoxon appeared as nubs of whorled collagen extending from the corneal stroma, line

89 The first (outermost) whorl consists of four sepals and the fourth (innermost)

90 ry of AG expression, rbe enhanced the second-whorl defects present in ap2-1, lug-1 and clf-2 mutants.

91 eins was localized to the centres of the RNA whorls, demonstrating significant partitioning of viral

92 acts non-cell-autonomously to inhibit second whorl development in ufo mutants.

93 ver another role for UFO in promoting second whorl development.

94 nd maintenance of this patterning throughout whorl development.

95 A. J. S. Klar between counterclockwise hair whorl direction and homosexuality in men, using more obj

96 Hair whorl direction is a somatic feature that is organized e

97 ween heterosexual and homosexual men in hair whorl direction, but the authors did replicate the frate

98 dentity gene but is restricted to the 'third whorl' domain in the flower.

99 sepals and reduced organ numbers in all four whorls, especially in the 2nd (petal) and 3rd (stamen) w

100 ur floral organ types arranged in concentric whorls exists across all flowering plant (angiosperm) sp

101 notably in the pattern of lines, swirls, and whorls first noted by the dermatologist Alfred Blaschko.

102 B class function specifies second and third whorl floral organ identity as described in the classic

103 leaf/stem separation and in first- and third-whorl floral organ separation, with FFO3 likely acting t

104 whorl floral organs), paleas (putative first whorl floral organs), and floral meristems.

105 s are expressed in ovules, lodicules (second whorl floral organs), paleas (putative first whorl flora

106 s to control the number of third- and fourth-whorl floral organs.

107 re, perennial life cycle, and dioecious, two-whorled flowers.

108 , cytoplasmic vacuoles and larger membranous whorls form, and the cell swells.

109 Membrane stacking and whorl formation coincided with a marked slowing of coat

110 Furthermore, whorl formation driven by exogenous expression of an ER

111 digital photographs of parietal surface hair whorls from 100 heterosexual men and 100 homosexual men

112 Silurian gnathostome based on isolated tooth whorls from Guizhou province, China.

113 duction of multiple flowers within one sepal whorl, fusion of sepals and petals, and conversion of se

114 that FAW inflicted the most damage in early whorl growth stage of maize, regardless of whether chemi

115 y laminar floral organs in the second floral whorl, have been shown to be under similar genetic contr

116 more specific role for FUL2 in outer floral whorl identity.

117 33-kD cysteine proteinase accumulates in the whorl in response to larval feeding.

118 elineates the boundaries of the third floral whorl in S. latifolia flowers.

119 expression of AGAMOUS (AG) to the inner two whorls in Arabidopsis thaliana.

120 l abnormalities and accumulation of membrane whorls in both vacuoles and the sarco- (endo-) plasmic r

121 The presence of additional floral whorls in flowers ectopically expressing APETALA3 and PI

122 tively correlated with counterclockwise hair whorls in heterosexual men.

123 e, a natural variant with posterior-specific whorls in its fur, to understand how epidermal polarity

124 sphorus, and biomass allocation among floral whorls in recombinant inbred lines of Brassica rapa in m

125 /eosin staining of rd7 tissue shows that the whorls in the outer nuclear layer of the retina do not a

126 y retinal dysplasia manifesting as folds and whorls in the photoreceptor layer.

127 be regionally decoupled to produce posterior whorls in the rosette fancy mouse.

128 ing phenotypes had longer branches but fewer whorls in their stems compared to those from the slow-gr

129 lcholine mass and the appearance of membrane whorls in these cells.

130 d the differentially expressed genes between whorls in wild and cultivated Camellia.

131 s the C-function to the inner petunia floral whorls, in parallel with the microRNA BLINDBEN belongs t

132 into a genetic model explaining early second whorl initiation/proliferation, in which UFO functions t

133 lly over-elongate and form large membranous "whorls" instead of disc stacks.

134 ts of four sepals and the fourth (innermost) whorl is made up of two carpels.

135 0.81 vs. 22.77 +/- 0.83, P = 0.01), inferior whorl length (18.03 +/- 1.46 vs. 25.1 +/- 1.95, P = 0.00

136 ed malformed outer segments characterized by whorl-like continuous membranes instead of stacked disks

137 Findings leading to the diagnosis included whorl-like epitheliopathy, corneal conjunctivalization,

138 ings included loss of limbal architecture, a whorl-like epitheliopathy, or an opaque epithelium arisi

139 ep135 resulted in the accumulation of unique whorl-like particles in both the centrosome and the cyto

140 he remodeling of the SR and the formation of whorls may represent a novel mechanism of the unfolded p

141 organization into stacked and concentrically whorled membranes, but the underlying mechanisms and fun

142 h strict boundaries at the second and fourth whorls, Men-9 gene expression therefore delineates the b

143 was initially expressed throughout the inner whorl meristem in female and male flowers, its spatial e

144 ion resembles separate shark-like oral tooth whorls more than modified dermal denticles.

145 Here we show that a major event in whorl morphogenesis is the activation of a prestalk-spec

146 d activity of LEUNIG in the outer two floral whorls must depend on interactions with other spatially

147 d third whorl of sepals surrounding a fourth whorl of carpels, or three whorls of sepals surrounding

148 WCM are tiny pests that feed within the whorl of developing leaves, and their feeding causes lea

149 target genes to specify the identity of each whorl of floral organs.

150 ses sepals and petals to merge into a single whorl of mixed identity.

151 e apical meristem, the floral meristem, each whorl of organ primordia, and in ovule primordia during

152 The organs in the second whorl of pAP3::AG flowers either fail to develop or deve

153 two whorls of sepals with a diminished third whorl of sepals surrounding a fourth whorl of carpels, o

154 t downregulation of AqAP3-2 in the innermost whorl of stamens was a critical step in the evolution of

155 MIP1 is expressed in the fourth whorl of the flower, in an overlapping temporal and spat

156 fertilised gynoecium formed in the innermost whorl of the flower, is the reproductive organ and one o

157 motor, AGAMOUS is misexpressed in the second whorl of the flower.

158 the inner two whorls, but also in the second whorl of the flower.

159 pic AGAMOUS mRNA expression in the outer two whorls of a flower, leading to homeotic transformations

160 ssors repress miR172 expression in the outer whorls of A. thaliana flowers.

161 organ number in the third and fourth floral whorls of Arabidopsis thaliana.

162 ristem development in a system with numerous whorls of floral organs, as well as an apocarpous gynoec

163 ound to control the development of the inner whorls of flowers.

164 topic expression of AG and SEP3 in the outer whorls of flowers.

165 Fall armyworm larvae feed in enclosed whorls of maize plants, where frass accumulates over ext

166 ntained increased numbers of neurofilaments, whorls of membrane, and accumulations of debris resembli

167 S) disc shedding, accumulation of debris and whorls of membranes at the RPE-OS interface, transient s

168 the lens, they had a flattened profile with whorls of membranous material and nucleic acid accumulat

169 used on model systems that only produce four whorls of organs in a flower, while little is known abou

170 abidopsis flower consists of four concentric whorls of organs.

171 e that includes two morphologically distinct whorls of petaloid organs and a clearly differentiated f

172 auliflower mosaic virus consist of two outer whorls of petals and inner whorls of stamens.

173 normal morphological development of the four whorls of primary floral organs.

174 Whorls of rhabdomeral membrane break into vesicles and f

175 rounding a fourth whorl of carpels, or three whorls of sepals surrounding abnormal carpels.

176 l variability, with flowers containing three whorls of sepals surrounding fertile carpels, two whorls

177 s of sepals surrounding fertile carpels, two whorls of sepals with a diminished third whorl of sepals

178 Flowers are organized into concentric whorls of sepals, petals, stamens and carpels, with each

179 They produce extra whorls of stamens, and an indefinite number of carpels.

180 sist of two outer whorls of petals and inner whorls of stamens.

181 re not required for repression of C in outer whorls of the flower.

182 tic organ identity phenotype in all the four whorls of the flowers, the endosperm development is seve

183 l and radially symmetric, with more than two whorls of three separate perianth organs each (undiffere

184 ach (undifferentiated tepals), more than two whorls of three separate stamens each, and more than fiv

185 on, organs present in the outer three floral whorls often have abnormal morphology.

186 eletion of the Fz6 gene produces stereotyped whorls on the hind feet, variable whorls and tufts on th

187 aws of the gnathostome crown-ancestor; tooth whorls or tooth rows evolved independently in placoderms

188 Enhanced first-whorl organ fusion in ap2-2 rbe-3, ant-4 rbe-3 and cuc2-

189 that of the wild type: after the outer three-whorl organ primordia have initiated, the remaining cent

190 pathway is required regardless of the second whorl organ to be formed, arguing that it affects a basi

191 that causes filamentous, mispositioned outer whorl organs and reduced numbers of malformed stamens in

192 In pi-5 flowers, second whorl organs develop as sepals rather than petals, but t

193 in the angiosperms and expression in second whorl organs in monocots.

194 In the development of second-whorl organs, RBE acts in the same pathway and downstrea

195 ap3 bnq3 double mutant displays pale second-whorl organs, supporting the hypothesis that BNQ3 is dow

196 ant pinoid, producing flowers with few outer whorl organs.

197 llele "random-recessive model" for both hair-whorl orientation and handedness trait inheritance is de

198 a person's preferred hand and the scalp hair-whorl orientation developed on the head.

199 (1) that a single gene controls handedness, whorl orientation, and twin concordance and discordance

200 y dense in 3 aniridia cases, and a prominent whorl pattern of nerves and epithelial cells was observe

201 oduce organs in defined spiral, opposite, or whorl patterns.

202 a sarcomatoid morphology of spindle cells in whorled patterns and metastasized to the lungs.

203 We find that second-whorl petals in rbe mutants can be replaced with stamino

204 d meristem, in which leaves are initiated in whorled phyllotaxis and without axillary meristems, both

205 s, carbon, and nitrogen allocation to female whorls (pistils and sepals) decreased under high density

206 ornroschen-like-2 (drnl-2), results in third whorl positions developing as filamentous organs.

207 The whorls possess non-shedding teeth arranged in a pair of

208 epal, stamen, and carpel at each of the four whorls, respectively, thus unveiling a role of SlDELLA i

209 y right-handers (RH), shows counterclockwise whorl rotation infrequently in 8.4% of individuals.

210 ion to the biologically specified scalp hair-whorl rotation is determined here.

211 ch currency were positively correlated among whorls, selection to improve fitness through female (or

212 AG1 and TAGL1 act together to repress fourth whorl sepal development, most likely through the MACROCA

213 f third whorl sepal-petal-stamens and fourth whorl sepal-carpels.

214 1 and HUA2, leads to the production of third whorl sepal-petal-stamens and fourth whorl sepal-carpels

215 ode trans-acting factors required for second-whorl-specific APETALA3 expression.

216 ever, what controls this predominantly inner whorl-specific expression of miR172 is not known.

217 served phenotype is not due to disruption of whorl-specific homeotic genes, AP3 or PISTILLATA, respon

218 the production of intercellular signals in a whorl-specific manner.

219 ion canalization of key functions; the faded whorl specification mechanism was fundamental under the

220 Despite the key principle of ABCE model in whorl specification, the underlying mechanism of fine-tu

221 wild-type flowers at stage 6, when the third-whorl stamen primordia have formed.

222 sepals develop in place of petals, but third whorl stamens are most often normal.

223 elop as sepals rather than petals, but third whorl stamens are normal.

224 erial organized as exaggerated multilamellar whorls, striated belts and 'fingerprint bodies'.

225 ce of a radially symmetric prepattern on the whorl surface.

226 inking the evolution of lodicules and second whorl tepal/petals of monocots.

227 etala flowers contain more floral organs and whorls than wild-type plants, phenotypes that correlate

228 nels reshape the ER membrane into concentric whorls that are released into the cytoplasm.

229 he formation of numerous abnormal membranous whorls that disrupted the integrity of photoreceptor out

230 In the sepal and carpel whorls the smallest sectors of marked and unmarked tissu

231 abundant in the yellow-green portion of the whorl-the normal site of larval feeding and the tissue t

232 monstrates that AG is required in the fourth whorl to make a flower determinate.

233 (but not the C-function) in the first floral whorl, together with BEN We propose a combinatorial mode

234 as B-function repressors in the first floral whorl, together with BEN/ROB genes.

235 of a 1927 study on the genetics of the hair-whorl trait, support for a recent single gene, two-allel

236 th whorl carpels at the summit and the first whorl transverse sepal pair at the base.

237 reas APETALA3 is expressed at high levels in whorls two and three.

238 These whorls undergo a morphogenetic transformation from spher

239 he 33-kDa cysteine protease in the maize mid-whorl was correlated with a significant reduction in cat

240 ise direction (for which no more than 1 hair whorl was present) by 2 raters unaware of sexual orienta

241 Cell fate in the first and fourth whorls was studied using X-ray-induced yellow ch-42 sect

242 ng to the level of protein expression, these whorls were composed of parallel dense lines arranged in

243 a greater extent of organ loss in all floral whorls were observed in the seuss leunig double mutants.

244 These whorls were prevalent in alphadbn-deficient mice but wer

245 ana, miR172 is expressed in the inner floral whorls where it downregulates the class A gene APETALA 2

246 own for its function in the outer two floral whorls, where it specifies the identities of sepals and

247 is expressed in the third and fourth floral whorls, whereas APETALA3 is expressed at high levels in

248 located between the perianth and the stamen whorl, which, although developed to varying degrees amon

249 ns show vacuoles, membranous infoldings, and whorls with associated amorphous tau accumulations and a

250 the PVX RNA was concentrated in distinctive 'whorls' within the VRC.

251 anscripts predominantly in the inner, sexual whorl, within developing ovules of female flowers and an