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1 cyte colony-stimulating factor and increased leukemogenesis).
2 CHD7 is also critical for CBFB-MYH11-induced leukemogenesis.
3 GAB2-SHP2 pathway is essential for lymphoid leukemogenesis.
4 ew genes that promote cytokine signaling and leukemogenesis.
5 enic fusion transcription factors that drive leukemogenesis.
6 ietic stem cell (HSC) functions and promotes leukemogenesis.
7 VPS33B deficiency led to a dramatic delay in leukemogenesis.
8 S1 target gene that cooperates with Hoxa9 in leukemogenesis.
9 ulates normal B cell development or promotes leukemogenesis.
10 ent roles of EED in normal hematopoiesis and leukemogenesis.
11 on and that plays a well-established role in leukemogenesis.
12 f either Mll1 or Dot1l impaired MN1-mediated leukemogenesis.
13 ways nor shown to functionally contribute to leukemogenesis.
14 dently and at different time points prior to leukemogenesis.
15 ency on MLL1 function in NUP98-fusion-driven leukemogenesis.
16 how DNMT3B-mediated DNA methylation affects leukemogenesis.
17 -rearranged AML, associated with accelerated leukemogenesis.
18 lly collaborates with HOXA9 to drive myeloid leukemogenesis.
19 tool to unravel the pathogenesis of MLL-AF4 leukemogenesis.
20 as overexpression of activated AKT1 promoted leukemogenesis.
21 cing H3K27 methylation contributes to T-cell leukemogenesis.
22 th these two important pathways, may promote leukemogenesis.
23 eukemia-initiating cells (LICs) and promotes leukemogenesis.
24 erentiation in AML stem cells and attenuated leukemogenesis.
25 ing 1) plays a pivotal role in acute myeloid leukemogenesis.
26 ietary restriction and profoundly suppressed leukemogenesis.
27 t inactivation of CXXC5 might play a role in leukemogenesis.
28 K79 methylation and cooperates with DOT1L in leukemogenesis.
29 ts, implicating PRC2 dysregulation in WT1mut leukemogenesis.
30 red for hematopoietic stem cell function and leukemogenesis.
31 -repression model for CBFbeta-SMMHC-mediated leukemogenesis.
32 llaborator required for Hoxa9/Meis1-mediated leukemogenesis.
33 ents occurring in -7/del(7q) AMLs to promote leukemogenesis.
34 opoietic stem cell fate determination and in leukemogenesis.
35 of hematopoietic homeostasis, HSC aging, and leukemogenesis.
36 ss of Ikaros contributes to multistep B cell leukemogenesis.
37 liferation required for Hoxa9/Meis1-mediated leukemogenesis.
38 lation of NuRD during lymphopoiesis promotes leukemogenesis.
39 ne in inv(3)(q21;q26) inversions, leading to leukemogenesis.
40 t nodes of the Wnt pathway can contribute to leukemogenesis.
41 ancer progression, with an important role in leukemogenesis.
42 receptor checkpoint and a safeguard against leukemogenesis.
43 tors in the pathogenesis of autoimmunity and leukemogenesis.
44 ollaborate with the CBFB/MYH11 fusion during leukemogenesis.
45 oncogenic Nras signaling in HSC function and leukemogenesis.
46 e discovered a dual role of RUNX1 in myeloid leukemogenesis.
47 RV has not been definitively associated with leukemogenesis.
48 ivity, and are likely to exert a key role in leukemogenesis.
49 s morphogenetic pathway as a target in human leukemogenesis.
50 ired for PML-RARalpha-mediated initiation of leukemogenesis.
51 or that is necessary for MLL-fusion-mediated leukemogenesis.
52 L), and its aberrant activity contributes to leukemogenesis.
53 emic mice with an HDAC inhibitor accelerated leukemogenesis.
54 apoptosis, stem cell-related properties, and leukemogenesis.
55 our knowledge of the role of NPM1 mutant in leukemogenesis.
56 for normal hematopoiesis but is required for leukemogenesis.
57 n of leukemia relevant genes, and eventually leukemogenesis.
58 y downstream effects on candidate drivers of leukemogenesis.
59 and unique role of this microRNA in myeloid leukemogenesis.
60 gnaling node of FLT3-ITD and MOZ-TIF2 driven leukemogenesis.
61 are suggested to contribute significantly to leukemogenesis.
62 o induce embryonic hematopoietic defects and leukemogenesis.
63 a promising strategy to block MLL1-mediated leukemogenesis.
64 unclear how Nras(G12D/+) signaling promotes leukemogenesis.
65 ion on expression of 17 potential drivers of leukemogenesis.
66 such misspliced genes might be important in leukemogenesis.
67 pected prosurvival role for RUNX1 in myeloid leukemogenesis.
68 id and T-lymphoid cells, contribute to overt leukemogenesis.
69 e effects on lymphopoiesis and contribute to leukemogenesis.
70 target genes in MLL1 fusion protein mediated leukemogenesis.
71 2-mediated degradation and may contribute to leukemogenesis.
72 on between mutated KIT and CBFB-MYH11 during leukemogenesis.
73 Tel-PdgfRbeta oncoprotein may contribute to leukemogenesis.
74 ation may be a common oncogenic mechanism in leukemogenesis.
75 lted in clonal expansion, myelodysplasia, or leukemogenesis.
76 ng direct genetic evidence of TAK1's role in leukemogenesis.
77 m cell (HSC) function and is associated with leukemogenesis.
78 nhibition of TAL1 expression and TAL1-driven leukemogenesis.
79 cell-related properties, and is required for leukemogenesis.
80 E2A-PBX1-mediated target gene activation and leukemogenesis.
81 d differentiation and apoptosis, and delayed leukemogenesis.
82 of the endogenous GEF motif leads to reduced leukemogenesis.
83 promote transcription of genes important for leukemogenesis.
84 TAD and oncogenic transcription networks in leukemogenesis.
85 (m(6)A) demethylase, was reported to promote leukemogenesis.
86 epigenetic progress contributing to lineage leukemogenesis.
87 as a checkpoint in B lymphoid maturation and leukemogenesis.
88 f AE+ AML cells, thereby impairing AE driven leukemogenesis.
89 Myc as a co-operating factor in NPM1c-driven leukemogenesis.
90 ough downregulation of key genes involved in leukemogenesis.
91 ction is essential for Notch1-induced T-cell leukemogenesis.
92 ght cooperate with cyclin E hyperactivity in leukemogenesis.
93 nd the role of inherited genetic variants in leukemogenesis.
94 MLL1 is dispensable for MLL-fusion-mediated leukemogenesis.
95 to promote downstream survival signaling and leukemogenesis.
96 insights each model has provided into MLL-FP leukemogenesis.
97 l self-renewal, Asxl2 loss promoted AML1-ETO leukemogenesis.
98 MYC in T-ALL, thereby contributing to T-cell leukemogenesis.
99 ly as secondary events to further potentiate leukemogenesis.
100 atal hematopoiesis and the initiation of MLL leukemogenesis.
101 are secondary events that occur later during leukemogenesis.
102 patients, they cannot completely explain LGL leukemogenesis.
103 apoptosis and differentiation while delaying leukemogenesis.
104 igned to explore different aspects of MLL-FP leukemogenesis.
105 ies, we show that ZFP521 is not required for leukemogenesis, although its absence leads to a signific
106 lasmic (BAALC) gene is implicated in myeloid leukemogenesis and associated with poor outcome in both
108 argeting lymphoid development are central to leukemogenesis and contribute to the arrest in lymphoid
110 Determining the role of these lesions in leukemogenesis and drug resistance should provide import
111 Activation of beta-catenin was linked to CML leukemogenesis and drug resistance through its BCR-ABL-d
114 ne system for studying early events of human leukemogenesis and for evaluating efficacy and mechanism
116 4-MYB/MYC signaling axis in myelopoiesis and leukemogenesis and highlight the critical roles of METTL
117 veral genes previously implicated in myeloid leukemogenesis and HSC function as being regulated in a
118 ether, our findings reveal a role of TAF1 in leukemogenesis and identify TAF1 as a potential therapeu
119 data suggest a role for Mer in acute myeloid leukemogenesis and indicate that targeted inhibition of
120 les for mTORC1 in hematopoietic function and leukemogenesis and inform clinical strategies based on c
121 ndings reveal crucial functions of ALKBH5 in leukemogenesis and LSC/LIC self-renewal/maintenance and
122 revealed that these mutations occur early in leukemogenesis and often persist in clonal remissions.
123 sent a major advance in the understanding of leukemogenesis and prognosis, and have enabled the devel
126 Overexpression of FAS significantly inhibits leukemogenesis and reverses miR-196b-mediated phenotypes
127 nce of the c-Myb-p300 interaction in myeloid leukemogenesis and suggest disruption of this interactio
128 a molecular mechanism for SALL4 function in leukemogenesis and suggest that targeting of the SALL4/M
129 MEIS1, through induction of SYTL1, promotes leukemogenesis and supports leukemic cell homing and eng
131 ne system for studying early events of human leukemogenesis and testing the efficacy of immunotherape
132 g how different mutations cooperate to drive leukemogenesis and the context-dependent effects of onco
134 aordinary advances into the genetic basis of leukemogenesis and treatment responsiveness in ALL.
135 establish a critical role for mutant IDH2 in leukemogenesis and tumor maintenance and identify an IDH
136 remains unclear how its loss contributes to leukemogenesis and whether ongoing PAX5 deficiency is re
137 UP98-KDM5A and NUP98-BPTF fusions in driving leukemogenesis, and demonstrate that blocking this inter
138 inant-negative effect by DNMT3A(R882mut) for leukemogenesis, and describes an attractive strategy for
139 ta revealed a multifaceted role for PAR-1 in leukemogenesis, and highlight this receptor as a potenti
140 ing factor-beta (CBFB) play pivotal roles in leukemogenesis, and inhibition of RUNX1 has now been wid
141 ic oncogene-mediated cell transformation and leukemogenesis, and inhibits all-trans-retinoic acid (AT
142 or engraftment of primary human AML LSCs and leukemogenesis, and it regulates LSC self-renewal predom
143 CDK6 severely attenuated NUP98-fusion-driven leukemogenesis, and NUP98-fusion AML was sensitive to ph
144 MYC regulatory circuit that underlies T cell leukemogenesis, and provide a rationale for therapeutic
145 that PBX3 is a critical cofactor of HOXA9 in leukemogenesis, and targeting their interaction is a fea
146 ifferent stem and progenitor compartments in leukemogenesis are challenges for the identification of
147 ical studies indicate that hematopoiesis and leukemogenesis are dependent upon hypoxia-inducible fact
151 ents that are important initiating events in leukemogenesis but are insufficient to explain the biolo
152 aled mechanisms of blood differentiation and leukemogenesis, but a similar analysis of HSC developmen
153 operate with antecedent molecular lesions in leukemogenesis, but have limited independent prognostic
154 ietic stem cells (HSCs) without induction of leukemogenesis, but requires frequent administration to
155 olar RNAs (snoRNAs), play important roles in leukemogenesis, but the relevant mechanisms remain incom
156 id leukemia (AML), and its inhibition delays leukemogenesis, but whether the metabolic function of AM
159 without gene fusions have been implicated in leukemogenesis by causing deregulation of proto-oncogene
161 We examined the contribution of G2DHE to leukemogenesis by creating a bacterial artificial chromo
162 gest that impaired Icsbp expression enhances leukemogenesis by deregulating processes that normally l
163 croenvironment and propose that ILK promotes leukemogenesis by enabling CLL cells to cope with centro
164 hat Chd7 is important for Cbfb-MYH11-induced leukemogenesis by facilitating RUNX1 regulation of trans
165 anine nucleotide exchange factor Vav3 delays leukemogenesis by p190-BCR-ABL and phenocopies the effec
168 bes a novel mechanism of FLT3 involvement in leukemogenesis by upregulation via chromatin remodeling
169 unx1 is indispensable for Cbfb-MYH11-induced leukemogenesis by working together with CBFbeta-SMMHC to
170 Although this latter function may promote leukemogenesis, concurrent p53 activation also leads to
172 ly targeting two critical signaling nodes in leukemogenesis could represent a therapeutic breakthroug
174 gulation of both normal HSC functions and in leukemogenesis driven by the mixed lineage leukemia (MLL
175 fic advances have provided new insights into leukemogenesis, drug resistance, and host pharmacogenomi
176 vestigated the impact of NCAM1 expression on leukemogenesis, drug resistance, and its role as a bioma
177 mutations play a significant role in myeloid leukemogenesis due to selective missplicing of tumor-ass
178 terminated emergency granulopoiesis, delayed leukemogenesis during emergency granulopoiesis, and norm
179 interactions.IMPORTANCE During virus-induced leukemogenesis, ecotropic mouse leukemia viruses (MLVs)
181 o mutations in genes known to be involved in leukemogenesis (ETV6, NOTCH1, JAK1, and NF1), we identif
183 tractable signaling molecules essential for leukemogenesis facilitates the development of effective
184 cohesin mutations occur as an early event in leukemogenesis, facilitating the potential development o
186 of the role of IDH mutations and (R)-2HG in leukemogenesis has been hampered by a lack of appropriat
190 mTOR complexes (mTORCs) in hematopoiesis and leukemogenesis have not been adequately elucidated.
192 e whether GM-CSF signaling affects RUNX1-ETO leukemogenesis, hematopoietic stem/progenitor cells that
193 een increased levels of IL-15 expression and leukemogenesis, high-risk disease, and CNS relapse and s
194 olved in Mixed Lineage Leukemia (MLL) fusion leukemogenesis; however, its role in prostate cancer (PC
196 of Cdk inhibitory nuclear functions enhances leukemogenesis in a murine CML model compared with compl
197 hymocyte development that is retained during leukemogenesis in a subset of T-ALLs and is reversible w
198 ity of Tet2 loss and PTPN11 D61Y to initiate leukemogenesis in concert with expression of AML1-ETO in
202 cific demethylase KDM5B negatively regulates leukemogenesis in murine and human MLL-rearranged AML ce
203 event in the progression of BCR-FGFR1-driven leukemogenesis in stem cell leukemia and lymphoma syndro
204 ugh aberrant Notch activation contributes to leukemogenesis in T cells, its role in acute myelogenous
205 he transcription factor Meis1 drives myeloid leukemogenesis in the context of Hox gene overexpression
206 tantly, the role of ROCK in hematopoiesis or leukemogenesis in the context of whole organism remains
207 P restores leukemic TADs, transcription, and leukemogenesis in the CTCF-boundary-attenuated AML cells
211 armacological inhibition of BCL6 compromised leukemogenesis in transplant recipient mice and restored
212 M1-mutated AML, the role of NPM1 mutation in leukemogenesis in vivo has not been fully elucidated.
213 ced PRDX2 expression inhibited c-Myc-induced leukemogenesis in vivo on BM transplantation in mice.
214 0(-/-) bone marrow and progression of B-cell leukemogenesis in vivo revealed no differences in diseas
219 h reduced intensity myeloablation to inhibit leukemogenesis, indicating that TRC105 may represent a n
220 echanism by which DNMT3A loss contributes to leukemogenesis is altered DNA methylation and the attend
224 ent samples, NUP98 fusion oncoprotein-driven leukemogenesis is mediated by changes in chromatin struc
228 unctional importance of their interaction in leukemogenesis is unclear.We recently reported that over
230 cell growth and delayed MLL-fusion-mediated leukemogenesis, likely through targeting FLT3 and MYB an
231 of acute myeloid leukemia (AML) and promotes leukemogenesis, making CDX2, in principle, an attractive
232 igations of the pathologic role of Cited2 in leukemogenesis may yield useful information in developin
234 a conditional knockout mouse model inhibited leukemogenesis mediated by the MLL-AF6 fusion oncogene.
235 These findings uncover a novel mechanism of leukemogenesis mediated by the nuclear export pathway an
236 a cell lines derived from human experimental leukemogenesis models yielded 80 hits, of which 10 were
237 tients suggests a novel molecular pathway of leukemogenesis: mutations in the hematopoietic cytokine
239 gulated by chromatin state alteration during leukemogenesis of human acute myeloid leukemia (AML), an
240 es during the course of infection to promote leukemogenesis of infected T cells, our results indicate
241 gest that defective self-renewal ability and leukemogenesis of MLL-Af4 myeloid cells could contribute
243 ertain GATA-2 target genes are implicated in leukemogenesis, only recently have definitive insights e
246 ) or nuclear retention (p27(S10A)) attenuate leukemogenesis over wild-type p27, validating the tumor-
247 myeloid leukemia (AML), often necessary for leukemogenesis, persistent throughout the disease course
248 L, coexpression of IkappaBalphaSR attenuated leukemogenesis, prolonged survival, and reduced myeloid
249 Deletion of CD44 during TCL1-driven murine leukemogenesis reduced the tumor burden in peripheral bl
250 on of Mof in a mouse model of MLL-AF9-driven leukemogenesis reduced tumor burden and prolonged host s
251 hematopoietic compartment results in delayed leukemogenesis, reduced disease burden, and a loss of LS
262 so defective in homing and engraftment, with leukemogenesis rescued by coexpression of chimeric E/L-s
264 cells following intravenous injection, with leukemogenesis restored by direct intrafemoral injection
265 of six miRNAs implicated in B and T lineage leukemogenesis, resulted in profound defects in T cell d
268 referentially at gene bodies.MLL-AF9-induced leukemogenesis showed much less pronounced DNA hypermeth
270 ection for oncogenically initiated cells and leukemogenesis specifically in the context of an aged he
272 /proliferation of leukemic cells and delayed leukemogenesis; such effects could be reversed by forced
273 CDK6 as critical effector of MLL fusions in leukemogenesis that might be targeted to overcome the di
274 stimuli are believed to play a major role in leukemogenesis, the critical determinants are not well d
276 cesses that appear to actively contribute to leukemogenesis, these models may not fully recapitulate
277 el of dual functional properties of SALL4 in leukemogenesis through inhibiting DNA damage repair and
278 for mixed lineage leukemia 1 (MLL1)-mediated leukemogenesis through its direct interaction with MLL1.
280 troduce a robust experimental model of human leukemogenesis to further elucidate key mechanisms invol
283 how Dnmt3b-mediated DNA methylation affects leukemogenesis, we analyzed leukemia development under c
284 y 92- overexpression induces lymphomagenesis/leukemogenesis, we generated a B-cell-specific transgeni
285 he role(s) of EED in adult hematopoiesis and leukemogenesis, we generated Eed conditional knockout (E
288 echanism by which RUNX1 disruption initiates leukemogenesis, we investigated its normal role in murin
289 To examine the role of PAX5 alterations in leukemogenesis, we performed mutagenesis screens of mice
290 tribution of DNMT3A-dependent methylation to leukemogenesis, we performed whole-genome bisulfite sequ
292 in healthy cells and has been shown to drive leukemogenesis when mutated in patients with acute myelo
293 the direct relationship of such mutations to leukemogenesis, when they occur in cells of an apparentl
295 on, PI3Kgamma or PI3Kdelta alone can support leukemogenesis, whereas inactivation of both isoforms su
296 g how ECs and leukemia cells interact during leukemogenesis, which could be used to develop novel tre
298 , with both positive and negative impacts on leukemogenesis, which requires the action of cooperating
299 nt co-occurring mutations cooperate to drive leukemogenesis will be crucial for improving diagnostic