ライフサイエンスコーパス: cone cell

1 arlier and was more significant than that in cone cells.

2 which leads to reduction or complete loss of cone cells.

3 varicosity formation and synthesis of SV2 in cone cells.

4 uces neighboring cells to become nonneuronal cone cells.

5 on tonic synaptic release of glutamate from cone cells.

6 lectroretinogram (ERG) responses and loss of cone cells.

7 ells and a second affected the production of cone cells.

8 No expression of the gene was detected in cone cells.

9 lls is early onset, followed by the death of cone cells.

10 and delayed differentiation of non-neuronal cone cells.

11 cells, as well as the outer segments (OS) of cone cells.

12 they displayed a significant preservation of cone cells.

13 ction in photopic ERG amplitudes and loss of cone cells.

14 egeneration that first involved rod and then cone cells.

15 s used to measure ZBED4 mRNA levels in these cone cells.

16 of late-born RGC, amacrine, horizontal, and cone cells.

17 cribed specifically in R7 photoreceptors and cone cells.

18 of generating RGC, amacrine, horizontal, and cone cells.

19 he structural plasticity observed in rod and cone cells.

20 spatiotemporal expression of Delta in pupal cone cells.

21 roughout the subcellular compartments of the cone cells.

22 the organization and survival of pigment and cone cells.

23 translocation of cone arrestin in transduced cone cells.

24 show an early loss of rod cells followed by cone cells.

25 etinal analogue requires delineation also in cone cells.

26 ight-driven protein translocation in rod and cone cells.

27 in neuritic growth of isolated rod, but not cone, cells.

28 Connecting with these cone cells, a multilayer neuro-network in the retina pro

29 ation-induced optical phase changes occur in cone cells and carry substantial information about spect

30 nal bifurcation of uncommitted ectoplacental cone cells and chorion progenitors.

31 gene is initially expressed in ectoplacental cone cells and chorionic plate, and later in the labyrin

32 age analysis approach to identify individual cone cells and evaluate their opsin expression from immu

33 differentiation of uncommitted ectoplacental cone cells and later for their specification towards tro

34 morphological and functional preservation of cone cells and maintenance of the retinal pigment epithe

35 proximal extensions of the four crystalline cone cells and of distal extensions of retinular cells R

36 resulting in abnormal patterns of bristles, cone cells and photoreceptors.

37 Cone cells and primary pigment cells oppose this signal

38 primary disease-causing molecular defect in cone cells and suggest that RDS-associated disease in pa

39 lts in the overproduction of photoreceptors, cone cells, and pigment cells and a corresponding reduct

40 The number of cone cells appeared normal throughout the superior and i

41 By 2 years, almost all rod and cone cells are gone, and the residual neural retina is i

42 Retinal rod and cone cells are not required for photoentrainment.

43 Although cone cells are resistant to cell damage induced by acute

44 nels in rod cells and cGMP-gated channels in cone cells are the primary calcium channels required for

45 olocalization of NSE with SV2 indicated that cone cells began to make synaptic contacts with horizont

46 mical (glycinergic) synapses to modulate OFF cone cell bipolar terminals; these ON and OFF cone bipol

47 loped with a full complement of SDOCT bands; cone cell bodies >10 deep have thin, elongated, and tigh

48 , and synaptic pedicles and heavily staining cone cell bodies and pedicles.

49 By 13 months, foveal cone cell bodies stack >6 deep, Henle fiber layer (HFL)

50 up Ca(2+) when it accumulates either in the cone cell body or outer segment.

51 iption repressor Tramtrack (TTK) is found in cone cells but not photoreceptor cells of the Drosophila

52 adherin within a sub-group of retinal cells (cone cells) causes them to form an overall shape that mi

53 that rd7 retinas have an increased number of cone cells compared to wild-type retinas.

54 l cells and a failure to consistently switch cone cell contacts from an anterior-posterior to an equa

55 e photooxidative stress, progressive loss of cone cells continued for up to 3 months after light expo

56 In addition, rod PDE6 expressed in cone cells couples to the light signaling pathway to pro

57 ese data support the hypothesis that gradual cone cell death after rod cell death in RP is due to oxi

58 Intravitreal 7m8-RdCVF slowed the rate of cone cell death and increased the amplitude of the photo

59 a remarkable effect both on the reduction of cone cell death and the maintenance of the overall struc

60 e and white light selectively induce rod and cone cell death in an in vitro model.

61 chanisms involving RIP kinase are crucial in cone cell death in inherited retinal degeneration, sugge

62 cting protein (RIP) kinase mediates necrotic cone cell death in rd10 mice, a mouse model of retinitis

63 The mechanism of cone cell death is uncertain.

64 In retinitis pigmentosa (RP), cone cell death precedes rod cell death.

65 sms and features of subsequent nonautonomous cone cell death remain largely unknown.

66 Cone cell death was analyzed by double labeling with TdT

67 models of retinitis pigmentosa is linked to cone cell death, which can be delayed by systemic admini

68 but later declined, consistent with delayed cone cell death.

69 loped a quantitative, probabilistic model of cone cell decisions in the retinal tissue based on thyro

70 how that loss of Dicer1 leads to early-onset cone cell degeneration and suggest that Dicer1 is essent

71 With time this causes cone cell degeneration.

72 Immunohistochemical staining of cone cells demonstrates that rd7 retinas have an increas

73 this was accompanied by a 2-fold increase in cone cell density and a 50% increase in medium-wavelengt

74 pography of residual cone function parallels cone cell density.

75 hich may be relevant to their function or to cone cell development, and that differences in this post

76 pe due to a disorganized retina and aberrant cone cell differentiation, which leads to reduction or c

77 g that was required for R7 specification and cone cell differentiation.

78 In cone cells, either GRK1, GRK7, or both, depending on the

79 s this issue, we used the fly eye, where the cone cells exchange neighbors over ~10 h to shape the le

80 cone spectral sensitivities and activating M cone cells exclusively.

81 d cone, as revealed by expression of the red cone cell fate determinants thyroid hormone receptor bet

82 r sensitivity in ESCS may be due to abnormal cone cell fate determination during retinal development.

83 ptional regulators in determining rod versus cone cell fate in photoreceptor precursors during the de

84 Notch, which is important in determining the cone cell fate in the Drosophila eye.

85 les but is not required for induction of the cone cell fate.

86 ombinatorial, manner in the specification of cone-cell fate.

87 sed them to adopt R7 fates or, occasionally, cone cell fates.

88 The types of cues used by maturing cone cells for their eventual sclerad location remain to

89 hat GC1-GCAP1 interactions are essential for cone cell function in mice and that GC2 and GCAP2 activi

90 psin coding sequence, suggesting the loss of cone cell function, but maintenance of non-photosensitiv

91 The shaping of the cone cell group and packing of its components precisely

92 eptor, Notch, and intact primary pigment and cone cells have been implicated in survival or death sig

93 aining protein 1 (GTF2IRD1) in maintaining M cone cell identity and function as well as rod function.

94 ceptor cells, and TTK does not accumulate in cone cells if both PHYL and SINA are present.

95 In this study we use the developing cone cell in the Drosophila visual system to elucidate t

96 ated expression of GC1 in a subpopulation of cone cells in postnatal GC1 knockout retina restores lig

97 ctors required for terminal determination of cone cells in the eye.

98 the first demonstration of a requirement for cone cells in the ommatidial rotation aspect of PCP.

99 of mid-wavelength opsin and the presence of cone cells in the ONL and the choroidal circulation were

100 Cone cells in the periphery had remnants of inner segmen

101 of cone arrestin is one of the phenotypes of cone cells in this retina: the cone arrestin in these ce

102 maging methods permit visualization of human cone cells in vivo but have only recently achieved suffi

103 ncreased the number of varicosities, whereas cone cells increased process growth.

104 irless and the Enhancer of split-Complex for cone cell induction.

105 ions of P21 mouse retina were used to assess cone cell integrity by visualizing opsin localization.

106 Second, we found that cone cell intercalation is regulated by the Notch pathwa

107 EGF receptor, Notch, and primary pigment and cone cells into a single pathway that affected caspase a

108 The rod PDE6 enzyme expressed in cone cells is active and contributes to the hydrolysis o

109 In cone cells, L-type channel antagonists caused only modes

110 d how the absorption of a photon in a rod or cone cell leads to the generation of the amplified neura

111 a demonstrated that loss of Tmem30a in mouse cone cells leads to mislocalization of cone opsin, loss

112 ism for supporting cone function in the 661W cone cell line.

113 tinoblastoma cells to differentiate toward a cone cell lineage while selectively leading other cells

114 inner and outer segments of remaining cones; cone cell loss also was dramatic in young mice lacking R

115 results of this study show that the rate of cone cell loss in the GC1 KO mouse is comparable to that

116 Cone cell loss was exacerbated in the inferior retinal r

117 rm cone outer segment shortening rather than cone cell loss.

118 Light damage resulted in rod, but not cone, cell loss.

119 delayed, so that, at P12, positioning of the cone cell nuclei within the ONL was still quite irregula

120 the outer border of the ONL, the location of cone cell nuclei, at 1 and 2 days after injection of FeS

121 er and inner segment length was reduced, and cone cell numbers were reduced, as were scotopic and pho

122 calization in the photoreceptors and reduced cone cell numbers, and led to progressive loss of vision

123 restores cone arrestin translocation in the cone cells of postnatal GC1 knockout mouse retina.

124 ed enhancer that activates the dPax2 gene in cone cells of the developing Drosophila eye.

125 ys directly regulate D-Pax2 transcription in cone cells of the Drosophila eye disc.

126 The rod and cone cells of the mammalian retina are the principal pho

127 one cell survival was determined by counting cone cells on flat-mounted retinas.

128 whereas mouse Ubap1l is highly expressed in cone cells only.

129 The cone cell phenotype is sensitive to the level of rugose

130 appears to be distinct from that of rod and cone cell photopigments for vision.

131 How rod and cone cells prevent the accumulation of 11-cis-retinal in

132 or pigment granules in the extensions of the cone cell projections are present above the BM in T. eva

133 may function by regulating genes involved in cone cell proliferation, and mutations in this gene lead

134 In cone cells, quantitative analysis showed that NO or cGMP

135 Delayed loss of cone cells, remaining rod cells, and choroidal circulati

136 ization of gene editing in the macula and of cone cell replacement in general.

137 vector and to localize cone arrestin within cone cells, respectively.

138 idermis, but only a moderate effect on petal cone cell ridges.

139 We show that cone cell shapes depend little on adhesion bonds and mos

140 Finally, whole retinas and isolated cone cells show increased photosensitivity following exp

141 sparkling, a Notch- and EGFR/MAPK-regulated, cone cell-specific enhancer of the Drosophila Pax2 gene,

142 ifferentiation but also promotes nonneuronal cone cell specification in early Drosophila eye developm

143 Detailed analysis of R7 and cone cell specification reveals that extramacrochaetae a

144 l. exploit two different pathways to promote cone cell survival and preserve vision in murine retinal

145 fic for cone transducin were used to examine cone cell survival in the GC1 KO retina at 4, 5, 9, 16,

146 Cone cell survival was determined by counting cone cells

147 Cone cell survival was determined by counting cone opsin

148 6 months of age; however, 40% to 70% of the cone cells survived in the superior region at this age.

149 Cone cell terminals, however, are relatively inactive.

150 ted channels, known to be present on rod and cone cell terminals, respectively, were used to block ca

151 se findings, which show that fully developed cone cells that have developed in the absence of GC1 can

152 The Notch signal from the cone cells then functions in the direct specification of

153 MP causes neuritic sprouting in rod, but not cone, cells through the AC-PKA-CREB pathway known to be

154 al lens with normal refractive power, and in cone cells to enable complete extension of the photorece

155 es coexpress both S and M opsins in a common cone cell type throughout the retina.

156 w progression, differentiation of R4, R7 and cone cell types, and rotation of ommatidial clusters.

157 ng natural noise stimuli and preservation of cone cells upon spectral domain optical coherence tomogr

158 yramids) was found in layer II/III; another (cone cells) was found in clusters spanning layer VI thro

159 kout mouse (Dicer CKO) to delete Dicer1 from cone cells, we show that cone photoreceptor cells degene

160 or cone arrestin in transduced and wild-type cone cells were indistinguishable after dark and light a

161 Single rod and cone cells were isolated by micromanipulation, and the a

162 Individual rod and cone cells were lysed for RT-PCR and Southern blot analy

163 Axonal extensions of NSE-labeled cone cells were shown to interact with those of differen

164 A total of 5400 and 7252 margin cones cells were found in each of two monkeys.

165 d LS neurons (stellates, small pyramids, and cone cells) were encountered in layers II/III and VI of

166 s individual cone dysfunction by stimulating cone cells with flashes of light and measuring nanometer

167 th CRX predominantly in the inner segment of cone cells, with additional costaining in the outer nucl

168 Analysis of rod and cone cells within the photoreceptor layer showed a distu