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1 The soft agar assay was used as a measure of anchorage independent growth.
2 ivity and for suppressing cell migration and anchorage-independent growth.
3 lticellular spheroids that were generated by anchorage-independent growth.
4 oncogenic MET-induced cell migration but not anchorage-independent growth.
5 ll death and reducing metabolic activity and anchorage-independent growth.
6 esults in preventing migration, invasion and anchorage-independent growth.
7 suppressed HCC cell migration, invasion, and anchorage-independent growth.
8 ploidy cells, and attenuation of cancer cell anchorage-independent growth.
9 T352A) attenuated the induction of PDAC cell anchorage-independent growth.
10 xpressed in TNBCs and 10 proved critical for anchorage-independent growth.
11 l lines reduced cell migration, invasion and anchorage-independent growth.
12 increased the proliferation rate and induced anchorage-independent growth.
13 t expression reduced anchorage-dependent and anchorage-independent growth.
14 of epithelial characteristics and decreased anchorage-independent growth.
15 l lines and decreased cell proliferation and anchorage-independent growth.
16 l lines caused ATP reduction and compromised anchorage-independent growth.
17 and suppresses PDAC anchorage-dependent and anchorage-independent growth.
18 ression of aromatase significantly increased anchorage-independent growth.
19 liation and increased both proliferation and anchorage-independent growth.
20 lected in their relative abilities to confer anchorage-independent growth.
21 also find that reduction of NOS1AP enhances anchorage-independent growth.
22 s of ROCK substrates, migration, invasion or anchorage-independent growth.
23 is associated with reduced proliferation and anchorage-independent growth.
24 ration and invasion, anoikis resistance, and anchorage-independent growth.
25 ion of these activities inhibits PAK1-driven anchorage-independent growth.
26 on displayed higher activation of ERK1/2 and anchorage-independent growth.
27 l transition (EMT), increased migration, and anchorage-independent growth.
28 affected E1A-mediated cell proliferation and anchorage-independent growth.
29 s, activation of death programs, and loss of anchorage-independent growth.
30 increased proliferation, clonogenicity, and anchorage-independent growth.
31 ared with WT, especially under conditions of anchorage-independent growth.
32 ut not Exo84 was necessary for inhibition of anchorage-independent growth.
33 atment with an inhibitor of ERRalpha impeded anchorage-independent growth.
34 enic RAS but also conferred the capacity for anchorage-independent growth.
35 found no inhibition of KRAS mutant CRC cell anchorage-independent growth.
36 -RasV12 was sufficient to reduce Ras-induced anchorage-independent growth.
37 B56gamma3 to inhibit cell proliferation and anchorage-independent growth.
38 rRNA transcription and repressed EGF-induced anchorage-independent growth.
39 ncy on ETV1 expression for proliferation and anchorage-independent growth.
40 ing, and are dependent on FGFR signaling for anchorage-independent growth.
41 cked the ability of EGFR mutations to induce anchorage-independent growth.
42 inotransferase is essential for Kras-induced anchorage-independent growth.
43 t wild-type doubling times, cytokinesis, and anchorage-independent growth.
44 well as for Ewing sarcoma proliferation and anchorage-independent growth.
45 ncer-like gene expression but do not exhibit anchorage-independent growth.
46 h Cat-1, the cells are again able to undergo anchorage-independent growth.
47 ogate its actions as a negative regulator of anchorage-independent growth.
48 cell proliferation, migration, invasion, and anchorage-independent growth.
49 ion forces, cell migration and invasion, and anchorage-independent growth.
50 r (CTGF) and Cyr61 target genes, and exhibit anchorage-independent growth.
51 7b overexpression on migration, invasion and anchorage-independent growth.
52 vPK also augments cellular proliferation and anchorage-independent growth.
53 ain prostate cancer migration, invasion, and anchorage-independent growth.
54 ed cell growth, clonogenicity, mobility, and anchorage-independent growth.
55 er proliferation, cell cycle progression and anchorage-independent growth.
56 cy, including cell migration, metastasis and anchorage-independent growth.
57 4C-E) resulted in a significant increase in anchorage-independent growth.
58 towards ULK1 and require ULK1 for sustained anchorage-independent growth.
59 ndrial function, cellular proliferation, and anchorage-independent growth.
60 with CK2alpha had enhanced proliferation and anchorage-independent growth.
61 uired to support replicative immortality and anchorage independent growth, a predictor of tumorigenes
62 pha silencing in ras-transformed IEC reduced anchorage-independent growth, a criterion for malignant
63 ere we report that p100 inhibits cancer cell anchorage-independent growth, a hallmark of cellular mal
64 cer cells inhibits cell proliferation and an anchorage-independent growth, a hallmark of tumorigenic
66 ction to ECM-induced signals is required for anchorage-independent growth, a property of most maligna
68 of apico-basal polarity in 3D cultures, and anchorage-independent growth, accompanied by expression
69 osis, epithelial-mesenchymal transition, and anchorage-independent growth activities in vitro and on
71 ns for CAP1 in cancer cell proliferation and anchorage-independent growth, again in a cell context-de
72 d strikingly, cooperated with OSM to promote anchorage-independent growth (AIG), a property associate
73 ired and sufficient to control PKD1-mediated anchorage-independent growth and anchorage-dependent pro
74 n a subset of these cell lines inhibits both anchorage-independent growth and cell invasion in a GAP-
75 investigation revealed that miR-185 impedes anchorage-independent growth and cell migration, in addi
77 lpha expression was required for Myc-induced anchorage-independent growth and cell proliferation.
78 I in H460 cells also impaired cell adhesion, anchorage-independent growth and cell seeding to the lun
79 ons, ectopic expression of Myc-nick promotes anchorage-independent growth and cell survival at least
80 tment; second, in a separate assay measuring anchorage-independent growth and colony formation by imm
81 mary epithelial cells evidenced by decreased anchorage-independent growth and decreased cell migratio
82 ive melanoma and lung cancer cells increased anchorage-independent growth and elevated the expression
83 embrane localization and activation, impeded anchorage-independent growth and enhanced stress-induced
84 ormed characteristics of cancer cells (e.g., anchorage-independent growth and enhanced survival capab
85 al features of human cancer cells, including anchorage-independent growth and escape from contact inh
86 n immortalized cells, although essential for anchorage-independent growth and evasion of apoptosis, d
87 ependency of tumor cells on HR signaling for anchorage-independent growth and highlights how the meta
88 pression was sufficient to suppress in vitro anchorage-independent growth and in vivo tumor formation
89 hat LARP1 promotes cell migration, invasion, anchorage-independent growth and in vivo tumorigenesis.
90 colorectal cancer cell lines increased their anchorage-independent growth and inhibited TGFB signalin
91 ermore, depletion of K-Ras and RalB inhibits anchorage-independent growth and invasion and interferes
92 ing ATAD3A also results in loss of both cell anchorage-independent growth and invasion and suppressio
93 ransfectants of truncated FasL showed strong anchorage-independent growth and lung metastasis potenti
94 -dependent growth was ROCK-independent, both anchorage-independent growth and Matrigel invasion were
95 example is the importance of active RalA in anchorage-independent growth and membrane raft trafficki
96 lower cell cycle progression and compromised anchorage-independent growth and migration ability in vi
99 ivation of MEK and NF-kappaB, migration, and anchorage-independent growth and reduce its mitochondria
100 nt-derived colon cancer cell line suppressed anchorage-independent growth and reduced tumor growth in
101 operties of MCF10-2A cells with induction of anchorage-independent growth and self-renewal in 3D-sphe
102 bset of lung cancer cell lines reduces their anchorage-independent growth and significantly decreases
103 abrogated the ability of hypoxia to increase anchorage-independent growth and significantly reduced t
104 pensates for AMPK activation and facilitates anchorage-independent growth and solid tumour formation
105 ess conditions, such as glucose limitations, anchorage-independent growth and solid tumour formation
106 (KO) in LN-229 glioblastoma cells suppresses anchorage-independent growth and spheroid invasion in vi
107 ts expression in NIH-3T3 fibroblasts induces anchorage-independent growth and stimulates cell invasio
110 egulated kinase pathway activation, promoted anchorage-independent growth and tumor formation in mice
111 gulation of the miR-200 family, and enhanced anchorage-independent growth and tumor formation in nude
112 cells harboring wild-type PPP2R1A increased anchorage-independent growth and tumor formation, and tr
113 in signaling, cell migration, proliferation, anchorage-independent growth and tumor growth in a mouse
114 Phosphorylation of WASp at Y102 enhances anchorage-independent growth and tumor growth in an in v
115 significant increases in cell proliferation, anchorage-independent growth and tumor growth in vivo.
116 ation of PEAK1 levels in cancer cells alters anchorage-independent growth and tumor progression in mi
117 ies associated with tumorigenesis, including anchorage-independent growth and tumor progression.
118 nally important in alveolar rhabdomyosarcoma anchorage-independent growth and tumor-cell proliferatio
122 We showed that depletion of FoxM1 inhibits anchorage-independent growth and tumorigenicity in mouse
124 rmation of the HA cable structure, increased anchorage-independent growth, and cell-cell adhesion.
125 ing FGFR3 and kdFGFR3 reduced clonogenicity, anchorage-independent growth, and disintegration of the
126 gnificantly decreased cell proliferation and anchorage-independent growth, and impaired migration and
127 ediated signaling, inhibiting cell invasion, anchorage-independent growth, and in vivo dissemination
128 imensional culture, increased proliferation, anchorage-independent growth, and increased migration an
129 creased proliferation and survival, promoted anchorage-independent growth, and induced migration and
130 phosphorylation increased autophagy, reduced anchorage-independent growth, and inhibited Akt-driven t
131 cluded rates of proliferation and apoptosis, anchorage-independent growth, and invasiveness, were ass
132 transforming prostate epithelial cells into anchorage-independent growth, and MAPK4 knockdown inhibi
133 orrelated with increased cell proliferation, anchorage-independent growth, and migration and invasion
134 as, suppresses SW-480 cell proliferation and anchorage-independent growth, and promotes caspase- and
135 KSRP decreased cell proliferation, reversed anchorage-independent growth, and reduced migration/inva
136 duced apoptosis, inhibited proliferation and anchorage-independent growth, and rendered glioma cells
137 n to reduce cellular motility, invasiveness, anchorage-independent growth, and responsiveness to TGFb
138 asTF promotes oncogenic gene expression, anchorage-independent growth, and strongly up-regulates
139 ogic transformation by H-RasV12 or K-RasV12, anchorage-independent growth, and survival of anoikis of
140 , KAP1, CHD1, and EIF3L collectively support anchorage-independent growth, and the SUMOylation of KAP
141 JNK2alpha had decreased cellular growth and anchorage-independent growth, and the tumors were four-f
142 n, elevated clonogenic activity, accelerated anchorage-independent growth, and transformation and wer
143 changes, an increase in cell proliferation, anchorage-independent growth, and tumor growth in vivo.
144 ll lines compromised cell cycle progression, anchorage-independent growth, and tumorigenesis in nude
145 s exhibit epithelial-to-mesenchymal changes, anchorage-independent growth, and upregulated RAS/MAPK s
146 ockdown inhibited cancer cell proliferation, anchorage-independent growth, and xenograft growth.
147 by shRNA suppressed PCa cell proliferation, anchorage-independent growth, and xenograft tumor format
148 of cancer, loss of cell-to-cell adhesion and anchorage-independent growth, are both dependent on cell
149 increased invadopodia-dependent invasion and anchorage-independent growth, as well as by inhibition o
151 ting contact inhibition and oncogene-induced anchorage-independent growth, because of a failure to pr
152 n of KLF5 expression significantly decreased anchorage-independent growth, but did not affect prolife
153 on of RalA expression reduced CRC tumor cell anchorage-independent growth, but surprisingly, stable s
154 tive CCND1/CDK2 activity effectively confers anchorage independent growth by inhibiting p53 or replac
155 cell (HCEC) model to identify suppressors of anchorage-independent growth by conducting a soft agar-b
156 mors inhibited their anchorage-dependent and anchorage-independent growth by inducing senescence and/
157 melanocytes and in melanoma cells increased anchorage-independent growth by providing GAB2-expressin
158 antly, Orai3 knockdown selectively decreased anchorage-independent growth (by approximately 58%) and
159 1)/S transition of the cell cycle as well as anchorage-independent growth capability of breast cancer
160 y active forms of Akt1 and Akt2 restores the anchorage-independent growth capability of HeLa cells de
161 tive-tissue growth factor (CTGF), as well as anchorage-independent growth, capacity to invade Matrige
162 each variant on NB cell adhesion, migration, anchorage-independent growth, co-precipitation with alph
164 nder magnesium-deprived situations and under anchorage-independent growth conditions, demonstrating a
165 PC re-expression exerted profound effects in anchorage-independent growth conditions, however, includ
166 icted by Helios found ten conferred enhanced anchorage-independent growth, demonstrating Helios's exq
167 cy on Nrf2 could be recapitulated in certain anchorage-independent growth environments and was not pr
168 y and cellular transformation as assessed by anchorage-independent growth, focus formation, invasion,
169 ificantly reduced cellular proliferation and anchorage-independent growth from control melanomas, whe
170 ased proliferation, migration, invasion, and anchorage-independent growth; impaired growth of an orth
171 oduction and the capacity of MCF-7 cells for anchorage independent growth in soft agar were dependent
172 bypass the requirement for oncogenic Ras in anchorage independent growth in vitro and tumor formatio
173 transcripts identified in this tumor induced anchorage-independent growth in 3T3 cells and tumor form
174 of human kinases for their ability to induce anchorage-independent growth in a derivative of immortal
175 whereas independently of PI3K, Rac1 mediated anchorage-independent growth in a GTPase-independent man
176 cancer cell growth, migration, invasion and anchorage-independent growth in both MCF7 and MCF7-Cd ce
177 tivity in maintaining metabolic activity and anchorage-independent growth in breast cancer cells.
179 ound that FATE1 is required for survival and anchorage-independent growth in Ewing sarcoma cells via
181 together with FGFR2 isoform IIIb, increases anchorage-independent growth in immortalized Barrett's e
182 d that its depletion inhibits clonogenic and anchorage-independent growth in multiple patient-derived
183 duces the ability of Ran(K152A) to stimulate anchorage-independent growth in NIH-3T3 cells and in SKB
184 ated Akt phosphorylation, proliferation, and anchorage-independent growth in parental cells, but had
186 , morphological transformation and increased anchorage-independent growth in response to FGF2 ligand
188 by growth factor-independent proliferation, anchorage-independent growth in soft agar, and enhanced
189 ormation between GRIN1 and GRIN2A, increased anchorage-independent growth in soft agar, and increased
190 o-mesenchymal transition phenotype, acquired anchorage-independent growth in soft agar, and led to en
191 reased cell proliferation, colony formation, anchorage-independent growth in soft agar, cell migratio
194 functionally relevant; through induction of anchorage-independent growth in TGF-beta1-dependent norm
195 ERRalpha expression, metabolic capacity, and anchorage-independent growth in the absence of KSR1.
196 icient to enhance metabolic capacity but not anchorage-independent growth in the absence of KSR1.
200 esses prostate cancer cell proliferation and anchorage-independent growth in vitro and inhibits tumor
201 colon cancer cells reduces cell survival and anchorage-independent growth in vitro and inhibits tumor
202 negatively regulates anchorage-dependent and anchorage-independent growth in vitro and restrains tumo
203 ific expression of CD24 (NLS-CD24) increased anchorage-independent growth in vitro and tumor formatio
204 encing inhibits NSCLC cell proliferation and anchorage-independent growth in vitro and tumor formatio
205 tion of ETS1 in breast cancer cells promotes anchorage-independent growth in vitro and tumor growth i
206 ispensable for breast cell proliferation and anchorage-independent growth in vitro and tumor growth i
207 sufficient to promote cell proliferation and anchorage-independent growth in vitro and tumorigenesis
208 MEM16A overexpression significantly promoted anchorage-independent growth in vitro, and loss of TMEM1
209 cancer cell stemness in a mammosphere assay, anchorage-independent growth in vitro, and lung cancer c
210 P2 overexpression suppressed foci formation, anchorage-independent growth in vitro, and tumorigenicit
214 ited an increased capacity for AKT-dependent anchorage-independent growth, in support of a tumor supp
215 roliferation in vitro and in vivo, decreases anchorage-independent growth, induces apoptosis, and dra
217 ilization, G2/M growth arrest induction, and anchorage-independent growth inhibition of cancer cells.
218 RNA Rad9 cells restores migration, invasion, anchorage-independent growth, integrin beta1 expression,
219 ts in vitro and in vivo including changes to anchorage-independent growth, interaction with activated
220 In contrast, PKCdelta attenuation enhanced anchorage-independent growth, invasion, and migration in
221 like phenotype with increased proliferation, anchorage-independent growth, invasion, and migration.
222 e-mediated attenuation of PKCdelta inhibited anchorage-independent growth, invasion, migration, and t
223 cells, miR-22 decreased cell proliferation, anchorage-independent growth, invasiveness, and promoted
225 major source of ROS generation required for anchorage-independent growth is the Q(o) site of mitocho
226 the loss of KSR2 in metabolic signaling and anchorage-independent growth, KSR2 RNAi, MEK inhibition,
227 5 and -1976 suppress CRC cell proliferation, anchorage independent growth, metastatic potential, and
228 s treated with bisphosphonates inhibited the anchorage-independent growth, migration and invasion of
229 oviocytes, and cell proliferation, survival, anchorage-independent growth, migration, and invasion we
230 gnant properties such as cell proliferation, anchorage-independent growth, migration, invasion, and a
232 Silencing ITSN1 significantly inhibits the anchorage independent growth of tumor cells in vitro and
233 PAK4 substrate GEF-H1 (IC(50) = 1.3 nM) and anchorage-independent growth of a panel of tumor cell li
234 l migration, invasion, colony formation, and anchorage-independent growth of aggressive lung cancer c
235 gulation of survivin, which in turn supports anchorage-independent growth of alphavbeta6-expressing c
236 has also acquired the property to facilitate anchorage-independent growth of breast cancer cells.
237 we found that Nrf2 activation inhibited the anchorage-independent growth of breast cancer cells.
238 -binding motif of Claudin-2 is necessary for anchorage-independent growth of cancer cells and is requ
239 entiation and impaired the proliferation and anchorage-independent growth of cells with protective al
241 firmed by finding that DeltaNp73 facilitates anchorage-independent growth of gastric epithelial cells
243 f focal complexes, is also essential for the anchorage-independent growth of HeLa cervical carcinoma
245 antiandrogens induced anoikis by abrogating anchorage-independent growth of HR(+) cancer cells but e
246 not RKI-11 inhibits migration, invasion and anchorage-independent growth of human breast cancer cell
247 preading of murine embryonic fibroblasts and anchorage-independent growth of human cancer cell lines.
248 tion, CDK2 inhibition drastically diminishes anchorage-independent growth of human cancer cells and c
250 lture, the knockdown of which diminished the anchorage-independent growth of ILC cell lines through c
251 ounds disrupt NR0B1 complexes and impair the anchorage-independent growth of KEAP1-mutant cancer cell
253 Depletion of AR suppressed Sema4D-induced anchorage-independent growth of LNCaP and LNCaP-LN3 cell
259 Igammai2 and Src synergistically induced the anchorage-independent growth of nonmalignant cells.
260 INPP4B increases proliferation and triggers anchorage-independent growth of normal colon epithelial
261 nd in cells and suppressed proliferation and anchorage-independent growth of pancreatic cancer by inh
262 enzymatic product of LTA(4)H, and suppressed anchorage-independent growth of pancreatic cancer cells.
263 depletion of srGAP3 promotes Rac dependent, anchorage-independent growth of partially transformed hu
267 ncing LITAF by shRNA enhances proliferation, anchorage-independent growth of these cancer cells and t
268 hosphatases significantly reduced growth and anchorage-independent growth of TNBC cells to a greater
271 The requirement for Cat-1 when assaying the anchorage-independent growth of transformed fibroblasts
272 t cannot be phosphorylated by AMPK increased anchorage-independent growth of tumor cells and helped t
273 hate 5-kinase (PIPK) Igammai2 in controlling anchorage-independent growth of tumor cells in coordinat
275 owth, but inhibited PDAC cell proliferation, anchorage-independent growth, orthotopic tumor growth, a
278 esvirus 68 (gammaHV68) infection and achieve anchorage-independent growth, providing a cellular reser
279 ogenic H-Ras(V12) to regulate metabolism and anchorage-independent growth, providing novel targets fo
280 eads to markedly increased cell motility and anchorage-independent growth, reduced endocrine sensitiv
282 This diminished both cell proliferation and anchorage-independent growth required for cancer progres
284 activities, both RalA and RalB regulation of anchorage-independent growth required interaction with R
287 ced migration and colony formation, impaired anchorage-independent growth, slower xenograft tumor gro
288 is, they exhibit much greater invasiveness, anchorage-independent growth, spheroid formation, and dr
289 malignant melanoma cell proliferation and/or anchorage-independent growth, suggesting key and non-ove
290 K2 expression alone was sufficient to impair anchorage-independent growth, supporting their nonoverla
291 inhibited HBx stimulation of cell migration, anchorage-independent growth, tumor development in HBxTg
292 tively inhibits melanoma cell proliferation, anchorage-independent growth, tumorigenesis, and tumor m
293 ic cell line U251 reduces their capacity for anchorage-independent growth, two-dimensional migration,
294 ion gene to be dependent on VTI1A-TCF7L2 for anchorage-independent growth using RNA interference-medi
295 s leads to loss of contact inhibition and to anchorage-independent growth, vital traits acquired duri
299 ocyst component was necessary for supporting anchorage-independent growth, whereas RalB interaction w
300 I-induced Akt activation, proliferation, and anchorage-independent growth while retaining responsiven