ライフサイエンスコーパス: mammosphere

1 le, motile protrusions on the surface of the mammosphere.

2 to proliferate in suspension, as nonadherent mammospheres.

3 xpression was directly controlled by NRF2 in mammospheres.

4 D8's effects on antioxidant genes and ROS in mammospheres.

5 idant genes to enhance gene transcription in mammospheres.

6 ards three-dimensionally cultured breast CSC mammospheres.

7 egation and increase the formation of clonal mammospheres.

8 of single tumor cells as they divide to form mammospheres.

9 way is aberrantly activated in breast cancer mammospheres.

10 increased the ability of these cells to form mammospheres.

11 growth of human breast cancer stem cells as mammospheres.

12 tectable in stem-like cells when expanded as mammospheres.

13 tly compromised the ability of cells to form mammospheres.

14 KP-1) and dephosphorylation of ERK1/2 in the mammospheres.

15 hose cells have an increased ability to form mammospheres, a property associated with mammary epithel

16 (BCSCs), including CD44(+)CD24(-) fractions, mammospheres, ALDH1(+) populations and side population c

17 s of hypoxia on CSC activity, using in vitro mammosphere and holoclone assays as well as in vivo limi

18 drogenase 1 (ALDH1) expression, and decrease mammosphere and progenitor colony formation.

19 CD133NPs effectively decreased the number of mammospheres and colonies formed.

20 he number, size, and replating efficiency of mammospheres and downregulated the stem cell markers ALD

21 cells exhibited an increased ability to form mammospheres and elevated expression of pluripotency-fac

22 -like cells isolated from HMLE cultures form mammospheres and express markers similar to those of HML

23 patient samples that are capable of forming mammospheres and initiating tumors with as few as 10 GD2

24 ER2(+)/PIK3CA tumors more efficiently formed mammospheres and lung metastases.

25 significant decrease in the overall size of mammospheres and reduced tumor volume in nude mice.

26 iferation and self-renewal potential of MCF7 mammospheres and resulted in cell death after <4 weeks o

27 P4-treated breast cancer cells formed larger mammospheres and silencing of CK5 using small hairpin RN

28 ogical inhibition of the Akt pathway in both mammospheres and syngeneic mice bearing tumors was shown

29 an mammary stem/progenitor cells cultured as mammospheres and that these genes are down-regulated whe

30 to the recovery of the capacity to generate mammospheres and to an increase in the number of tumors.

31 of miR-181, exhibited reduced expression in mammospheres and upon TGF-beta treatment.

32 ly improves the ability of cMaSCs to grow as mammospheres and, importantly, that this effect is aboli

33 tion blocks the formation and maintenance of mammospheres, and in combination with chemotherapy suppr

34 ercentage of cancer stem cells and number of mammospheres, and its influence upon several glycosphing

35 Importantly, mammospheres are enriched for cells that regenerate an e

36 We demonstrate that nonadherent mammospheres are enriched in early progenitor/stem cells

37 Here, we used progenitor-containing mammospheres as an in vitro exposure model to study this

38 as compared to non-TICs and in TIC-enriched mammospheres as compared to primary tumor cells depleted

39 howed that McTNs persist in breast stem cell mammospheres as flexible, motile protrusions on the surf

40 or (VDR) was significantly down-regulated in mammospheres, as well as in ALDH(+) breast cancer cells.

41 endent inhibition of bCSC, as evidenced by a mammosphere assay and flow cytometric analysis of aldehy

42 d ALDH1, with further characterisation using mammosphere assay and transplantation into immunodeficie

43 splayed enhanced self-renewal as measured by mammosphere assay compared with CD44(+)/CD24(-)/ANTXR1(-

44 However, the traditional mammosphere assay inevitably introduces cell aggregation

45 miting dilution transplantation and in vitro mammosphere assay, a Lin(-)CD29(H)CD24(H) subpopulation

46 as able to control cancer cell stemness in a mammosphere assay, anchorage-independent growth in vitro

47 drogenase 1, side population and by in vitro mammosphere assay.

48 progenitor cells as demonstrated by in vitro mammosphere assays and the expression of stem cell marke

49 alpha3, increased stem cell self-renewal in mammosphere assays and Wnt signaling including the expre

50 Mammosphere assays are widely used in vitro to identify

51 mesenchymal transition and generate >100-mum mammospheres bearing markers of cancer-initiating cells.

52 nase (ALDH(+)) had increased ability to form mammospheres compared to ALDH(-) cells.

53 Mammospheres, containing enriched breast progenitors, we

54 TPH was induced by PRL in mammosphere cultures and by milk stasis in nursing dams,

55 ible model of cellular transformation and in mammosphere-derived breast CSCs.

56 NA methylation of its promoter CpG island in mammosphere-derived epithelial cells on diethylstilbestr

57 tive complexes 2 and 3 readily penetrate CSC mammospheres, enter CSC nuclei, induce genomic DNA damag

58 e altered in epithelial progeny derived from mammospheres exposed to a synthetic estrogen, diethylsti

59 These mammospheres expressed MCSC-specific markers and generat

60 st cancer cells by reducing the formation of mammosphere, expression of pluripotency-factors and alde

61 s expands the stem cell population, augments mammosphere formation and accelerates EMT.

62 stem-like properties as indicated by reduced mammosphere formation and aldehyde dehydrogenase activit

63 ties, involving Snail and Slug upregulation, mammosphere formation and aldehyde dehydrogenase activit

64 to a non-CSC, which was detected by reduced mammosphere formation and cell motility.

65 ssion and enriched for CSCs, as indicated by mammosphere formation and CSC markers.

66 with stem cells assessed by gene expression, mammosphere formation and lineage markers.

67 and mammosphere formation in SUM225, whereas mammosphere formation and Notch1 activity were increased

68 g cell (TIC) fraction was investigated using mammosphere formation and soft-agar colony formation ass

69 ARTN also enhanced mammosphere formation and the ALDH1+ population in estro

70 DUSP4 loss increased mammosphere formation and the expression of the CSC-prom

71 Loss of miR-141 enhanced both mammosphere formation and tumor initiation.

72 es the increase in cancer cell viability and mammosphere formation by equol, and results in a signifi

73 PL also inhibited mammosphere formation by tumor cells from patient-derive

74 se aldehyde dehydrogenase-positive BCSCs and mammosphere formation capacity in SUM149.

75 Relative viability and mammosphere formation differed between samples but were

76 SFX-01 reduced mammosphere formation efficiency (MFE) of ER+ primary an

77 er cell motility and metastasis, and greater mammosphere formation efficiency.

78 Mammosphere formation in cell lines and human primary DC

79 demonstrate that DAPT reduced acini size and mammosphere formation in MCF10DCIS.com whereas there was

80 hanced migration and invasion, and increased mammosphere formation in methylcellulose.

81 Lapatinb reduced acini size and mammosphere formation in SUM225, whereas mammosphere for

82 uPAR overexpression increased mammosphere formation in vitro and tumor formation in an

83 se reduced cellular migration, invasion, and mammosphere formation of ErbB2-induced mammary tumors.

84 l-to-mesenchymal transition and CCN2-induced mammosphere formation of MCF-7 adenocarcinoma cells.

85 lial cells results in significantly enhanced mammosphere formation that is accelerated in the presenc

86 Inhibition of ALDH1 activity and/or mammosphere formation upon DATS treatment was significan

87 addition, inhibition of progranulin-induced mammosphere formation was examined and found to be most

88 Both drug resistance and enhanced mammosphere formation were reversed by treatment with a

89 increased whilst the inhibitor DKK1 reduced mammosphere formation with the greatest inhibitory effec

90 TMCC3 silencing suppressed mammosphere formation, ALDH activity and cell migration

91 ed cells show mitigated migration, invasion, mammosphere formation, and CD44(+)/CD24(-) population.

92 ed higher levels of migration, invasion, and mammosphere formation, and had a greater proportion of c

93 otch1 abrogated the increase in CSC markers, mammosphere formation, and in vivo tumor-initiating capa

94 mary mammary cells are dependent on Tcf3 for mammosphere formation, and its overexpression in the dev

95 in serial transplantations in vivo, reduced mammosphere formation, and reduced the proportion of CD4

96 s the CD44(hi)/CD24(lo) population, enhances mammosphere formation, and upregulates aldehyde dehydrog

97 tion, and increased stem cell generation and mammosphere formation, dependent upon autocrine TGF-beta

98 d anchorage-independent colony formation and mammosphere formation, indicating compromised self-renew

99 cell lines and abrogates NFkappaB-dependent mammosphere formation, indicating that DMF has anti-canc

100 and CD44(+)/CD24(-) CSC subpopulations, and mammosphere formation, indicating that JNK promotes CSC

101 Mammosphere formation, inhibited by EZH2 depletion, was

102 ession in HER2+ BC cells increased secondary mammosphere formation, soft agar colony formation, and %

103 ER+ve and ER-ve breast cancer but not normal mammosphere formation, suggesting that the Wnt pathway i

104 tosis, reversing EMT-signaling and impairing mammosphere formation, thereby blocking the tumor-formin

105 (CIP1) attenuated oncogene-induced BT-IC and mammosphere formation.

106 tes RORalpha function in suppressing EMT and mammosphere formation.

107 reases sensitivity to triptonide and reduces mammosphere formation.

108 ed by enhanced cell invasion, migration, and mammosphere formation.

109 in parallel with decreased CD44(hi)/CD24(lo) mammosphere formation.

110 increased the expression of CSC markers and mammosphere formation.

111 cyclin D1 expression, cell proliferation or mammosphere formation.

112 ke cells and promoted cell growth as well as mammosphere formation.

113 important for cellular growth, invasion and mammosphere formation.

114 ectively, and a reduction by 2.6-fold of the mammospheres formation.

115 null cells abrogated invasion, migration and mammosphere-formation.

116 d increase the probability that the observed mammospheres formed are clonal in origin.

117 Mammospheres formed following DEAR1 loss are enriched fo

118 owth, altered morphogenesis in Matrigel, and mammosphere forming ability, when overexpressed in immor

119 8600 treatment suppresses growth, colony and mammosphere forming capacity of BCSCs and induces G2M ar

120 that interferes with the measurement of true mammosphere forming efficiency.

121 stem cell properties, which included reduced mammosphere-forming ability and tumor initiation.

122 ATRA reduced mammosphere-forming ability of a subset of breast cancer

123 24(-/low) phenotype, concomitantly enhancing mammosphere-forming ability.

124 /CD24(-) stem cells, and a 3.2-fold enhanced mammosphere-forming capacity.

125 We also undertook cytogenetic analyses of mammosphere-forming cells after prolonged culture, which

126 tes or cytokines increased the proportion of mammosphere-forming cells and of cells expressing stem-l

127 SMO activation also increased the mammosphere-forming efficiency of primary mammary epithe

128 m relative to wild type, suggesting enhanced mammosphere-forming efficiency was due to increased surv

129 l reporter to enrich for cells with enhanced mammosphere-forming potential.

130 enhanced anoikis sensitivity, and suppressed mammosphere generation in mammary epithelial cells.

131 the miR-181 family members were elevated in mammospheres grown in undifferentiating conditions, comp

132 ults indicate that using lipid tethering for mammosphere growth assays can reduce the confounding fac

133 ng proteins important for breast cancer cell mammosphere growth.

134 MMTV-neu;Nedd9(-/-) mammospheres had striking defects in morphology and cell

135 ated that isolated PI-MECs were able to form mammospheres in culture, and upon transplantation, these

136 d MCF7-mCherry cells were seeded, 65% of the mammospheres in lipid-coated wells demonstrated single c

137 pe and form well-organized prostaspheres and mammospheres in Matrigel.

138 feration and a decreased ability to generate mammospheres in normal mammary glands.

139 ibroblasts, and were also capable of forming mammospheres in suspension culture and subsequent format

140 on of breast cancer (BC) cells that can form mammospheres in suspension, a feature endowed by stem ce

141 The ability of MCF-10A(arom) cells to form mammospheres in the absence of serum was increased.

142 samples were cultured in 3D matrigel and as mammospheres in the presence, absence or combination of

143 -like properties such as the ability to form mammospheres in vitro and tumor self-renewal in vivo.

144 oRNA mixture inhibited their ability to form mammospheres in vitro.

145 ary gland cells that are capable of forming "mammospheres" in vitro.

146 Activation of hedgehog signaling increases mammosphere-initiating cell number and mammosphere size,

147 lasia, and modulation of Bmi-1 expression in mammosphere-initiating cells alters mammary development

148 Overexpression of Gli2 in mammosphere-initiating cells results in the production o

149 on of new cell surface markers for enriching mammosphere-initiating cells, including endoglin and pri

150 Snail was up-regulated in mammospheres isolated from breast cancer cells.

151 Down-regulation of p63 in ErbB2 mammospheres markedly restricts self-renewal and expansi

152 Our findings that PHLDA1 is upregulated in mammospheres (MS) of ER+ breast cancer cells and that PH

153 , breast cancer cells propagated in vitro as mammospheres (MSs) have also been shown to be enriched f

154 The breast CSC mammosphere potency of 1-3 is dependent on the Group 10

155 SCF rescued the c-Jun-deficient mammosphere production.

156 stem-like cells, offsetting the formation of mammospheres relative to nontransduced T cells.

157 analysis of cells isolated from nonadherent mammospheres revealed overlapping genetic programs with

158 eases mammosphere-initiating cell number and mammosphere size, whereas inhibition of the pathway resu

159 CK5+ cells and prevented the P4 increase in mammosphere size.

160 RNA abolished this P4-dependent increase in mammosphere size.

161 helial cells that have undergone an EMT form mammospheres, soft agar colonies, and tumors more effici

162 53 in stem/progenitor cell-containing murine mammospheres, suggesting a potential role for the ER-p53

163 ly transformed line that forms self-renewing mammospheres that contain cancer stem cells.

164 hibits the formation, size, and viability of mammospheres to a better extent than salinomycin, an est

165 Notably, 3 reduces the formation and size of mammospheres to a greater extent than salinomycin, an es

166 ikingly, 1 reduces the formation and size of mammospheres to a greater extent than salinomycin, an es

167 ibly inhibits the formation of free-floating mammospheres to an extent similar to that of salinomycin

168 educes the formation, size, and viability of mammospheres, to a greater extent than salinomycin, a po

169 ency in vitro and decreases 3D-breast cancer mammosphere viability.

170 nt of cancer stem cells and number of formed mammospheres was significantly lower.

171 Mammospheres were relatively insensitive to treatment wi

172 metastatic breast cancer samples, only ER-ve mammospheres were responsive to the ligand Wnt3a.

173 is study, we examined vitamin D signaling in mammospheres which are enriched in MCSCs from establishe

174 Notably, in MCF-7 cell mammospheres, which display a well-defined acinus-like s

175 ficient epithelial cells were unable to form mammospheres, which were considered to be derived from m