ライフサイエンスコーパス: reproductive organ

1 fertilization growth and development of this reproductive organ.

2 portance as they specify the male and female reproductive organs.

3 e radiotracer ligands in tumor, adrenal, and reproductive organs.

4 e how NPHP4 functions in the retina and male reproductive organs.

5 l different roles in roots, vasculature, and reproductive organs.

6 ts including virilization and hypertrophy of reproductive organs.

7 to atrophy and inflammation in the accessory reproductive organs.

8 PSC) requires exclusion of a source in other reproductive organs.

9 hws), was identified that failed to shed its reproductive organs.

10 tems, young primordia, vascular tissues, and reproductive organs.

11 a and kappa that are highly expressed in the reproductive organs.

12 ue to unwanted side effects, particularly in reproductive organs.

13 s on bone while avoiding unwanted effects on reproductive organs.

14 mice, all the while inducing hypertrophy of reproductive organs.

15 in this category, 87% were expressed in the reproductive organs.

16 for the development of both bone and female reproductive organs.

17 , AG is expressed in distinct regions of the reproductive organs.

18 t activating untoward effects of estrogen in reproductive organs.

19 ht, or if the radiation directly affects the reproductive organs.

20 ly post-germination stages and in leaves and reproductive organs.

21 ects, but indispensable for their effects on reproductive organs.

22 cartilage surfaces and connective tissues in reproductive organs.

23 bone loss without associated side effects on reproductive organs.

24 r of developmental defects in vegetative and reproductive organs.

25 notoxic damage in many organs, including the reproductive organs.

26 finity Pi transporters in mobilizing Pi into reproductive organs.

27 in orchidectomized males, without affecting reproductive organs.

28 nly in the brain but also in male and female reproductive organs.

29 at used to preserve the mass and function of reproductive organs.

30 ivate expression in male and female pairs of reproductive organs.

31 estine, along with tissue destruction of the reproductive organs.

32 ans, typically infecting lymphoid as well as reproductive organs.

33 de resistance in both vegetative tissues and reproductive organs.

34 velopmental anomalies in both vegetative and reproductive organs.

35 o the macroevolution of plant vegetative and reproductive organs.

36 ing in a proliferation of petals in place of reproductive organs.

37 enic animals that overexpress MAT in several reproductive organs.

38 h male worms to fuel the maturation of their reproductive organs.

39 f a physiological role for oestrogen in male reproductive organs.

40 new blood vessels, occurs normally in female reproductive organs.

41 br is also expressed at high levels in adult reproductive organs.

42 been described, especially in the context of reproductive organs.

43 or oophorectomy, breast cancer, or cancer in reproductive organs.

44 treatment adversely affects the function of reproductive organs.

45 gans is 6-7 times higher than the number for reproductive organs.

46 .5 times higher than the number published on reproductive organs.

47 ontributes to thermotolerance in cotton male reproductive organs.

48 uctures that give rise to most of the female reproductive organs.

49 es, including the central nervous system and reproductive organs.

50 uscle tissues but little characterization in reproductive organs.

51 f the genetic basis for HT tolerance in male reproductive organs.

52 2 and performed gene expression profiling of reproductive organs.

53 to characterize the activities of the UPS in reproductive organs.

54 n the pairing-dependent maturation of female reproductive organs.

55 duced microbial loads in both the midgut and reproductive organs.

56 failure of sperm cells to target the female reproductive organs.

57 s to regulate gibberellic acid perception in reproductive organs.

58 h nodes, spleen, gastrointestinal tract, and reproductive organs.

59 tle is known about its effects on developing reproductive organs.

60 e of boron in the formation of fully fertile reproductive organs.

61 daptations in their locomotory apparatus and reproductive organs.

62 ng that auxin mediates PpSHI function in the reproductive organs.

63 d genes are highly expressed in sex-specific reproductive organs.

64 egeneration of the testes and male accessory reproductive organs.

65 iogenesis in the eye, ear, brain, and female reproductive organs.

66 to control the development of meristems and reproductive organs.

67 cences, thus conferring vegetative traits to reproductive organs.

68 induction of AP3 and AG and formation of the reproductive organs.

69 stablished evidence that bacteria persist in reproductive organs.

70 in the innermost whorl of the flower, is the reproductive organ and one of the most complex structure

71 distributed in macrophage-like cells of the reproductive organs and affected udders.

72 ta and pol kappa are highly expressed in the reproductive organs and are associated with translesion

73 rkable because worker honeybees have reduced reproductive organs and are normally sterile; however, t

74 , 2, 6, 12, or 24 h before collecting blood, reproductive organs and brains for immunocytochemical an

75 y their unwanted side effects, especially in reproductive organs and breast.

76 ew of malignant neoplasms' metastases to the reproductive organs and breast.

77 n of morphologically distinct vegetative and reproductive organs and by different growth patterns.

78 ogic analysis of the retina, brain, and male reproductive organs and by electroretinogram (ERG)-based

79 lso play an essential role in development of reproductive organs and generation of the gamete cells.

80 all, foregut, anterior and posterior midgut, reproductive organs and in a subset of ganglionic neuron

81 sive protein, has been detected in tumors of reproductive organs and is found in high levels in the p

82 hat nhr-1 mRNA is expressed in the accessory reproductive organs and is required for their developmen

83 resent in all phases of the estrous cycle in reproductive organs and mammary glands but was highest d

84 potential regulators of sexual dimorphism in reproductive organs and pinpoint previously unknown gene

85 egulate the development and function of male reproductive organs and play a crucial role in the onset

86 Flowers are reproductive organs and precursors to fruits and seeds.

87 how the HOX code is established in distinct reproductive organs and reveal that the expression of th

88 muscle mass while having reduced effects on reproductive organs and sebaceous glands.

89 es the effects of ZIKV infection on the male reproductive organs and semen and the immune response of

90 systemic infection, with LASV documented in reproductive organs and sperm for 21-42 days.

91 and to an unknown reason in males, as their reproductive organs and spermatozoid motility appeared n

92 , but how they work together in establishing reproductive organs and terminating FM remains to be det

93 Inhibiting nrps led to loss of female reproductive organs and testis hyperplasia.

94 sed in all cell types in the male and female reproductive organs and that the OsIDD6 protein directly

95 lt animals, with the highest levels found in reproductive organs and the lowest in muscle.

96 are the functional unit of the female insect reproductive organs and the number of ovarioles per ovar

97 its extent differs significantly between the reproductive organs and the organs of the perianth.

98 The unique expression patterns in reproductive organs and the sequence divergence of the A

99 explore this phenomenon and report that the reproductive organs and the vaginal introitus can underg

100 , diaspore mass, mass allocation to stem and reproductive organs and total number and proportion of m

101 Na+ and Cl- are accumulated in the reproductive organs and within assimilating branches, wh

102 rphism by obligatorily removing an undamaged reproductive organ, and thus dramatically enhancing its

103 igh levels of TIMP-2 mRNA in the lung, skin, reproductive organs, and brain.

104 Immune privilege is used by the eye, brain, reproductive organs, and gut to preserve structural and

105 s expressed in many organs, including female reproductive organs, and is a stem cell marker in the st

106 ine tissues examined, particularly in brain, reproductive organs, and late developmental stages of mu

107 through adaptive immunity against accessory reproductive organs, and the manifestation of SMG inflam

108 nd progesterone (2.23-9.78 ng/g), and in the reproductive organ are dexamethasone (<2.54-37.23 ng/g)

109 pment and disease, such organoids from fetal reproductive organs are not available.

110 Female reproductive organs are rich in elastic fibers that turn

111 In Arabidopsis, the identity of perianth and reproductive organs are specified by antagonistic action

112 BGD3 is expressed, the keel and the enclosed reproductive organs, are cyanogenic.

113 thod by showing that TRV-VIGS can operate in reproductive organs as well.

114 d the axial growth of various vegetative and reproductive organs, as the loss of At KINESIN-4C greatl

115 , hemolymph, salivary gland, coxal gland, or reproductive organs at 15 weeks postinfection.

116 ities, including variable male runting, male reproductive organ atrophy, reduced male fertility, and

117 0B are expressed both in the female and male reproductive organs, AtRPL10C expression is restricted t

118 imorphism, with distinct size differences of reproductive organs between fertile queens and the more

119 sex determination and suppression of female reproductive organ biogenesis.

120 fertile because the presence of their female reproductive organs blocks sperm transfer into females.

121 esponsive gene highly expressed in brain and reproductive organs (BRE) is down-regulated after UV irr

122 Moreover, for the two most-researched reproductive organs (breast and prostate), the focus is

123 Telomerase activity is abundant in reproductive organs but low or undetectable in vegetativ

124 high virus titers in lungs, brain, eye, and reproductive organs but no virus in the typical target o

125 EA5 is constitutively expressed in roots and reproductive organs but not in seeds.

126 tially masculinized females (m/m), with male reproductive organs but retained female antennae.

127 haracteristics of response to stimulation of reproductive organs, but not the colon, correlate with c

128 So far, the focus has been on reproductive organs, but sex steroids have far more wide

129 in life results in organizational changes in reproductive organs, but the effect of BPA on conducting

130 ated, abundant in rapidly dividing cells and reproductive organs, but undetectable in most other diff

131 l deletion of Lgr5 (Lgr5(d/d)) in the female reproductive organs by progesterone receptor-Cre (Pgr(Cr

132 rapy, radiotherapy, or surgery that involves reproductive organs can cause impaired spermatogenesis,

133 nterventions, and appropriate monitoring for reproductive organ cancer risk.

134 me, paradigms in the treatment of women with reproductive organ cancers have shifted lately.

135 induced parthenocarpy and auxin signaling in reproductive organs demonstrate breeding utility to safe

136 sperm ratios within both the male and female reproductive organs demonstrates that C(2)EN-bearing spe

137 In the other, reproductive organs develop on very short lateral branch

138 We show enhanced impairment of male reproductive organ development and exacerbation of the C

139 gene AGAMOUS is required for male and female reproductive organ development and for floral determinac

140 rturbations in pathways critical to C/C male reproductive organ development and function, including s

141 or the cell specification maintenance during reproductive organ development and, ultimately, for the

142 mone-like function of volatile terpenoids in reproductive organ development as a system with a visual

143 gland protein content, arginine content, and reproductive organ development in males, resulting in si

144 ference also auxin, play important roles for reproductive organ development in moss.

145 intensively studied, the molecular basis of reproductive organ development in orchids remains largel

146 ages of organ morphogenesis and to show that reproductive organ development in P. patens is highly or

147 A switch from apical to lateral reproductive organ development is proposed to have prime

148 enomic analyses reveal key genes involved in reproductive organ development, cell wall biosynthesis a

149 expression affects meristematic tissues and reproductive organ development, including the gynoecium,

150 the floral identity gene essential to plant reproductive organ development.

151 cting to epithelial openings, and organizing reproductive organ development.

152 to auxin to effect perianth organ number and reproductive organ differentiation.

153 -deficient males developed defects in select reproductive organs (e.g. penile hypospadias and prostat

154 Herein, we have identified a somatic reproductive organ enhancer complex (SREC) containing mu

155 The three somatic reproductive organ enhancers each activate expression in

156 age protein and oil bodies in vegetative and reproductive organs, events that normally occur during t

157 Zeus acquired male reproductive organ expression patterns and phenotypes.

158 -benzyl) reduced the total number of soybean reproductive organs (flowers and pods) by 31% and 27%, r

159 ng its possible habit of visiting gymnosperm reproductive organs for pollen feeding and/or pollinatio

160 In one, reproductive organs form apically, terminating growth of

161 pathway has been investigated extensively in reproductive organ function and their diseases.

162 rtility if their treatment adversely affects reproductive organ function.

163 que synergistic manner of JAG and DL in rice reproductive organ generation, providing insights into t

164 We assessed reproductive organs, gestation outcome, birth weight, an

165 velopment of the Arabidopsis thaliana female reproductive organ (gynoecium) is a crucial biological p

166 Unlike SERMs, the estrens induced reproductive organ hypertrophy in both male and female m

167 or instance, genes specifically expressed in reproductive organs (i.e., stamen) evolve more quickly t

168 ey player in floral morphogenesis, specifies reproductive organ identities and regulates the timely t

169 the C function gene AGAMOUS, acts to specify reproductive organ identities and to repress A function.

170 bidopsis MADS box gene AGAMOUS (AG) controls reproductive organ identity and floral meristem determin

171 gene AGAMOUS (AG) has a dual role specifying reproductive organ identity and floral meristem determin

172 Reproductive organ identity in Arabidopsis is controlled

173 background, which is partially defective in reproductive organ identity specification.

174 D-class genes, respectively, in determining reproductive organ identity, but also play hitherto unkn

175 that both genes are essential for specifying reproductive organ identity, yet they, exert different r

176 sts of an anther and a filament, is the male reproductive organ in a flower.

177 ed by the close proximity of male and female reproductive organs in a bisexual flower.

178 The development of reproductive organs in Antirrhinum depends on the expres

179 x genes appear to control the development of reproductive organs in both gymnosperms and angiosperms.

180 itant with the association of nectaries with reproductive organs in derived lineages.

181 e that inhibits both the formation of female reproductive organs in male embryos and the proliferatio

182 rear part of the body due to fully developed reproductive organs including eggs and follicles.

183 70J genes not only in vegetative but also in reproductive organs including mature tissues, where expr

184 1 is expressed throughout the vasculature of reproductive organs, including in the chalazal seed coat

185 ificantly higher level than neutral genes in reproductive organs, including kernels.

186 ates the development and homeostasis of male reproductive organs, including the prostate.

187 NICOL is expressed in male reproductive organs, including the testis, and forms a c

188 d mutations also cause the transformation of reproductive organs into perianth organs in the hua1-1 h

189 doublesex (dsx) mutants display size-reduced reproductive organs irrespective of the sexual morpholog

190 number of research articles published on non-reproductive organs is 4.5 times higher than the number

191 hat the number of grants for research on non-reproductive organs is 6-7 times higher than the number

192 We show that specification of reproductive organs is associated with distinct binding

193 In plants, correct formation of reproductive organs is critical for successful seedset a

194 Regulation of Gld in the reproductive organs is particularly complex, involving i

195 How sex hormones affect non-reproductive organs is poorly understood, yet highly rel

196 riptional networks coordinate Cu delivery to reproductive organs is poorly understood.

197 ntil the end of silking, expansive growth of reproductive organs is the primary event leading to abor

198 molecular mechanism of development in female reproductive organs is vital for understanding the princ

199 DOAG1 and DOAG2 are highly expressed in the reproductive organ, known as the column, compared to per

200 ne and instruct cells to become meiocytes in reproductive organs late in development.

201 Cancer therapy can often affect reproductive organs, leading to impaired pubertal develo

202 defects or premature spore abortion in male reproductive organs, leading to male sterility.

203 r less educated women) and those with intact reproductive organs (lower odds for less educated women)

204 ferent tissues within the pistil, the female reproductive organ of a flower.

205 The carpel is the female reproductive organ of flowering plants.

206 Flowers are the core reproductive organ of plants, and flowering is essential

207 Beyond their primary function as the reproductive organs of angiosperms, flowers constitute r

208 specific expression is also observed in the reproductive organs of both the male and female, includi

209 All constructs showed expression in the reproductive organs of developing flowers but no express

210 med that Tag1 expression predominates in the reproductive organs of flower buds.

211 of the accumulation of these bacteria in the reproductive organs of flowering plants.

212 he specification of stamens and carpels, the reproductive organs of flowers.

213 Reproductive organs of monocots produce abundant phased,

214 daptive roles in both vegetative tissues and reproductive organs of plants.

215 ute inflammation aberrantly infiltrated into reproductive organs of pregnant Dgcr8(d/d) mice.

216 A PN_LNC_N13 shows contrasting expression in reproductive organs of sexual and apomictic Paspalum not

217 The reproductive organs of some plants self-heat, release sc

218 hronologically altered expression pattern in reproductive organs of the apomictic genotype with respe

219 ved enriched Amt (AeAmt1) mRNA levels within reproductive organs of the arboviral vector mosquito, Ae

220 y, T1-weighted and T2-weighted images of the reproductive organs of three mice in their in vivo envir

221 and respiratory tract, lymphoid tissues and reproductive organs of viremic monkeys.

222 tract (kidneys and ureters) or lower tract (reproductive organs) of the genitourinary (GU) system ar

223 n rates of species with both male and female reproductive organs on the same individual (monoicy), an

224 diation, and chemotherapy can all damage the reproductive organs or the hypothalamic pituitary axis t

225 s, spleen, muscle, bone, and male and female reproductive organs (penis, testes, uterus, ovaries).

226 estational day 14 until parturition affected reproductive organ physiology and reduced circulating te

227 sub-groups are circumscribed by alternative reproductive organ placements.

228 of the pancreas, liver, lung, bowel, brain, reproductive organs, placenta, and thymus.

229 While soybean reproductive organs, pollen grains, and yield were reduc

230 al changes in the module repetition pattern, reproductive organ position, branching pattern and the n

231 anther sterility, confounding estimation of reproductive organ QTLs.

232 Furthermore, surgical removal of reproductive organs reduced the severity of mycoplasma d

233 The development of floral reproductive organs requires the activity of plant MADS-

234 (AG) specify the identities of perianth and reproductive organs, respectively, in flower development

235 After delivery, the reproductive organs return to their non-pregnant state.

236 Investigation of the reproductive organs revealed significantly fewer germ ce

237 In the absence of pollination, female reproductive organs senesce, leading to an irrevocable l

238 and ABCG18 are expressed in leaves, and the reproductive organs septum, and valves but not in the de

239 Histopathology of the reproductive organs showed atrophy of both testis and ov

240 ow that DELLA proteins are key regulators of reproductive organ size and important for ensuring optim

241 S (AG) is necessary for the specification of reproductive organs (stamens and carpels) during the ear

242 l) eta and kappa are highly expressed in the reproductive organs, such as testis, ovary, and uterus,

243 Reproductive organ surgeries may alter ovarian hormone l

244 procedure that may be associated with other reproductive organ surgeries, which in turn may be assoc

245 hormone therapy, how usage varied by type of reproductive organ surgery, and the bivariate and net as

246 rm lineages, but in general, male and female reproductive organs surrounded by a sterile perianth of

247 Our results also reveal how the reproductive organs temporally shift in concert within t

248 cer incidence by organ weight and found that reproductive organs tend to have a higher mass-normalize

249 monstrated that APGWamide was present in the reproductive organs that participate in the storage or t

250 Florets of cereal crops are the basic reproductive organs that produce grains for food or feed

251 innovation of flowering plants is the female reproductive organ, the carpel.

252 shape acquisition at the apex of the female reproductive organ, the gynoecium, remain poorly underst

253 s important for the patterning of the female reproductive organ, the gynoecium, the flow as well as t

254 elf-incompatibility, which allows the female reproductive organ, the pistil, to distinguish between s

255 In many flowering plant species, male reproductive organs, the anthers, produce abundant phase

256 s are required for the apical opening of the reproductive organs, the final differentiation of the eg

257 ribed isolated soft body preserving the male reproductive organs, the new specimen for the first time

258 issues but undergo massive remodeling in the reproductive organs through pregnancy and birth.

259 ZIKV can replicate in female and male reproductive organs, thus facilitating the human-human t

260 erial transfer, which occur mainly in female reproductive organs; thus, the molecular mechanism of de

261 ipts were found in kidney, liver, and female reproductive organ tissues.

262 s (estren-alpha and estren-beta) on bone and reproductive organs to determine whether estrens are saf

263 eir hosts through manipulation of the hosts' reproductive organs to facilitate disease transmission.

264 The thinning of competing reproductive organs to improve source-to-sink ratios in

265 e mutants, which show homeotic conversion of reproductive organs to perianth organs and a loss of flo

266 quires gradual yet extreme remodeling of the reproductive organs to support the growth of the embryos

267 ed to relay ejaculation-related signals from reproductive organs to the brain, and they express neuro

268 e alterations observed in the shoot apex and reproductive organs under salinity conditions.

269 e, while accumulating GB in their leaves and reproductive organs up to 0.3 and 1.2 micromol g(-1) fre

270 level glyphosate tolerance in vegetative and reproductive organs using transplastomic technology prov

271 g has differential impact on male and female reproductive organ viability leading to yield losses in

272 ion relies on yolk cell-generating accessory reproductive organs (vitellaria) supporting development

273 e sex steroid bioactivity on male and female reproductive organs was attenuated.

274 ptor mRNA in tissues such as bone and female reproductive organs was evident, and significant phenoty

275 d a loss of determinacy, but the identity of reproductive organs was largely unaffected.

276 Radiation dosimetry to adult reproductive organs was less favorable for radiographic

277 he worker nutrition-driven size reduction of reproductive organs was restricted to the female sex, su

278 No changes were found in reproductive organ weights, systolic blood pressure, ope

279 teroid concentrations and the weights of the reproductive organs were greatly reduced in all groups t

280 ugh growth and development of vegetative and reproductive organs were not affected.

281 The diaphragm encloses the reproductive organs where pollination by carrion flies o

282 crease in cutin production in vegetative and reproductive organs, while its downregulation has the op