ライフサイエンスコーパス: lymphomagenesis

1 cells, which is the typical program seen in lymphomagenesis.

2 null mice, show delayed onset of MYC-induced lymphomagenesis.

3 n mechanism of NF-kappaB deregulation during lymphomagenesis.

4 of malignant transformation in virus-driven lymphomagenesis.

5 ) checkpoint are required for ThPOK-mediated lymphomagenesis.

6 tential mechanism of gammaherpesvirus-driven lymphomagenesis.

7 d we add new mechanistic insight into B-cell lymphomagenesis.

8 nal center B cells is thought to precipitate lymphomagenesis.

9 viously unrecognized role of BRCA1 in B-cell lymphomagenesis.

10 initiate and maintain oncogenesis, including lymphomagenesis.

11 lation of epigenetic-repressive marks during lymphomagenesis.

12 n, tumour apoptosis and prevention of T-cell lymphomagenesis.

13 ng a critical function of PTEN in preventing lymphomagenesis.

14 s is critical to understand viral-associated lymphomagenesis.

15 t substitute for LMP1 in EBV-positive B cell lymphomagenesis.

16 novel link between ThPOK, TCR signaling, and lymphomagenesis.

17 its repression by MYC contributes to B-cell lymphomagenesis.

18 establish PTPN1 mutations as new drivers in lymphomagenesis.

19 tudy the multistep transformation process in lymphomagenesis.

20 implications for the role of NF-kappaB in GC lymphomagenesis.

21 ressor function of IRF5 in IR-induced thymic lymphomagenesis.

22 function in CD40-driven B-cell expansion and lymphomagenesis.

23 with tumor suppressor properties involved in lymphomagenesis.

24 BCL6 may function in a 'hit-and-run' role in lymphomagenesis.

25 thereby contribute to B-cell homeostasis and lymphomagenesis.

26 a critical component of API2-MALT1-dependent lymphomagenesis.

27 of IRF5, p53 and PUMA in DNA damage-induced lymphomagenesis.

28 ation critically control EBV-mediated B cell lymphomagenesis.

29 mu-Myc mouse model, resulting in decelerated lymphomagenesis.

30 proliferation, processes fundamental to EBV lymphomagenesis.

31 id context that K171E IKKbeta contributes to lymphomagenesis.

32 r effects allowing for the oncogene to drive lymphomagenesis.

33 in vivo, it plays a critical role in B-cell lymphomagenesis.

34 tors, the disruption of which contributes to lymphomagenesis.

35 on of apoptosis resistance during Myc-driven lymphomagenesis.

36 Dnmt1 in a mouse model of MYC-induced T-cell lymphomagenesis.

37 rom cell proliferation and those specific to lymphomagenesis.

38 tivation, potentially contributing to B-cell lymphomagenesis.

39 an unexpected role of the IL-10R pathway in lymphomagenesis.

40 bolic pathways that contribute to sustaining lymphomagenesis.

41 tic activation, processes fundamental to EBV lymphomagenesis.

42 r microenvironment contributes to EBV-driven lymphomagenesis.

43 guish early versus late genetic eventsduring lymphomagenesis.

44 ropose that these genes play a role in DLBCL lymphomagenesis.

45 q21 may be a critical determinant of NK cell lymphomagenesis.

46 y accelerated the rate of Myc-induced B-cell lymphomagenesis.

47 r understanding of the molecular programs of lymphomagenesis.

48 is implicated in control of GC reaction and lymphomagenesis.

49 AIP3 targeting on miR-125a/miR-125b-mediated lymphomagenesis.

50 n about the additional lesions necessary for lymphomagenesis.

51 ion promotes immune evasion and virus-driven lymphomagenesis.

52 f evidence supports a causal role of PCBs in lymphomagenesis.

53 tor (BCR) signaling by PAX5 contributes to B-lymphomagenesis.

54 t knowledge on BCL6 function and its role in lymphomagenesis.

55 cer-associated ARED genes is disabled during lymphomagenesis.

56 contribute to c-Myc-induced KSHV-associated lymphomagenesis.

57 The deficient mice are prone to B-cell lymphomagenesis.

58 demonstrating the oncogenic role of MALT1 in lymphomagenesis.

59 expected to be mutually exclusive events in lymphomagenesis.

60 terations targeting key loci in human T cell lymphomagenesis.

61 ism of GC selection and the role of c-Myc in lymphomagenesis.

62 nd HIV proteins could directly contribute to lymphomagenesis.

63 cusses recent findings on the role of AID in lymphomagenesis.

64 lted in rapid, fatal lymphoproliferation and lymphomagenesis.

65 est that FOXO1 repression contributes to cHL lymphomagenesis.

66 our understanding of oncogenic mechanisms in lymphomagenesis.

67 ccelerate and enhance the dissemination of T-lymphomagenesis.

68 vated Dnmt3b in a mouse model of MYC-induced lymphomagenesis.

69 ation and whose de-regulation is involved in lymphomagenesis.

70 l loss of E6AP attenuated Myc-induced B-cell lymphomagenesis.

71 to RAG-initiated genomic rearrangements and lymphomagenesis.

72 hat reduction in HAT dosage is important for lymphomagenesis.

73 llular oncogenic processes that arise during lymphomagenesis.

74 nsights into the mechanism of viral-mediated lymphomagenesis.

75 ubclinical immune system function influences lymphomagenesis.

76 regulated NF-kappaB signaling can facilitate lymphomagenesis.

77 flammation and chronic B-cell stimulation in lymphomagenesis.

78 epigenetic modifications might contribute to lymphomagenesis.

79 genes might initiate genomic instability and lymphomagenesis.

80 us tumors and showed accelerated Myc-induced lymphomagenesis.

81 e to DNA damage and the suppression of early lymphomagenesis.

82 ggesting that chronic HBV infection promotes lymphomagenesis.

83 tions for understanding the role of Gfi-1 in lymphomagenesis.

84 an oncoprotein that cooperates with c-Myc in lymphomagenesis.

85 rminal center (GC) reaction and important in lymphomagenesis.

86 n in tumor-derived cells suppressed leukemia/lymphomagenesis.

87 -renewal, and differentiation while opposing lymphomagenesis.

88 t non-Ig genes and thereby promote GC B-cell lymphomagenesis.

89 tem, but collaborates strongly with c-Myc in lymphomagenesis.

90 eculation that vitamin D may protect against lymphomagenesis.

91 from a chromosomal translocation involved in lymphomagenesis.

92 ion of pre-B cells and, subsequently, during lymphomagenesis.

93 nal center (GC) B cells and is implicated in lymphomagenesis.

94 ough its ability to accelerate c-Myc-induced lymphomagenesis.

95 ng new strategies to inhibit MALT1-dependent lymphomagenesis.

96 nce survival in a mouse model of Myc-induced lymphomagenesis.

97 ha in Notch pathway activation during T-cell lymphomagenesis.

98 er immune function, which may be relevant to lymphomagenesis.

99 have examined the role of circadian genes in lymphomagenesis.

100 in B cell development, immune function, and lymphomagenesis.

101 ngiogenesis, thus revealing targets to block lymphomagenesis.

102 that are commonly targeted during GC B cell lymphomagenesis.

103 CD30 signaling increases the risk of B-cell lymphomagenesis.

104 f BCL6 and significantly delayed BCL6-driven lymphomagenesis.

105 underlying mechanisms of EBV-induced B-cell lymphomagenesis.

106 as a cell-extrinsic suppressor of GC B cell lymphomagenesis.

107 is on how Tfh cell signals may contribute to lymphomagenesis.

108 how their application to study clonal B-cell lymphomagenesis.

109 eir inactivation is thought to contribute to lymphomagenesis.

110 pment but completely abrogates Eu-Myc-driven lymphomagenesis.

111 ell activation is hyperactivated, leading to lymphomagenesis.

112 ed gammaherpesvirus infection and associated lymphomagenesis.

113 hypothesis that sex hormones play a role in lymphomagenesis.

114 ression that can contribute to viral-induced lymphomagenesis.

115 tion resulting from Blimp1 loss in ABC-DLBCL lymphomagenesis.

116 section of early steps in the progression to lymphomagenesis.

117 h as autoimmunity, chronic inflammation, and lymphomagenesis.

118 itical role for BCL-W in B cell survival and lymphomagenesis.

119 ssion of apoptosis with implications for EBV lymphomagenesis.

120 o-operative mutations leading to spontaneous lymphomagenesis.

121 tations might play an important role in PTFL lymphomagenesis.

122 of the tumor microenvironment that promotes lymphomagenesis.

123 ay represent a novel animal model of gastric lymphomagenesis.

124 hat MTHFR variants contribute to pSS-related lymphomagenesis.

125 clonogenicity, suggesting a role of vp17s in lymphomagenesis.

126 ied that Akt2 cooperates with Dlx5 in T-cell lymphomagenesis.

127 alone and cooperate in development of B-cell lymphomagenesis.

128 uming that HIV is only indirectly related to lymphomagenesis.

129 onal collaboration between Gfi1 and c-Myc in lymphomagenesis.

130 erate with MYC over-expression to accelerate lymphomagenesis.

131 into the pathways that contribute to B-cell lymphomagenesis.

132 al center (GC) reaction and is implicated in lymphomagenesis.

133 et this TCR must be downregulated for T-cell lymphomagenesis.

134 d NF-kappaB pathway previously implicated in lymphomagenesis.

135 es cause GC B cells to become susceptible to lymphomagenesis.

136 ph nodes to identify potential mechanisms of lymphomagenesis.

137 ene expression in mouse GC B cells, promotes lymphomagenesis.

138 sibility that HIV may directly contribute to lymphomagenesis.

139 type p53 it leads to significantly increased lymphomagenesis (56%) when compared with control mice (2

140 on are thought to be the main drivers of HIV lymphomagenesis, although the current scenario does not

141 sults reveal a pre-neoplastic stage in human lymphomagenesis and a cascade of somatic mutations leadi

142 ement, and restoring TTP impairs Myc-induced lymphomagenesis and abolishes maintenance of the maligna

143 tein-Barr virus (EBV) has been implicated in lymphomagenesis and can be found infecting tumor cells a

144 Identifying the mechanism of lymphomagenesis and cell-of-origin from which PTCLs aris

145 ir-146b significantly delayed PTEN-deficient lymphomagenesis and delayed c-myc oncogene induction, a

146 at, while loss of one copy of Rpl22 promotes lymphomagenesis and disseminated disease, loss of both c

147 We review competing models of lymphomagenesis and highlight evolving evidence that som

148 on by constitutively active EZH2 facilitates lymphomagenesis and identifies EZH2 as a possible therap

149 tand the pathobiologic link of HCV in B cell lymphomagenesis and its optimal management in the oncolo

150 Finally, lymphomagenesis and lymphoma proliferation depended upon

151 mu-Myc transgenic mouse, greatly accelerates lymphomagenesis and mortality.

152 ficantly accelerated p19Arf deletion-induced lymphomagenesis and promoted rapid metastasis.

153 ressor that directly protects against B cell lymphomagenesis and provides a strong rationale for bloc

154 , explaining how HVEM loss contributes to GC lymphomagenesis and revealing a cell-extrinsic tumor-sup

155 Strikingly, PARP14 deficiency delayed B lymphomagenesis and reversed the block to B-cell maturat

156 etwork, we can elucidate known mechanisms of lymphomagenesis and suggest candidate tumorigenic altera

157 mor development, accelerated Emu-Myc-induced lymphomagenesis and susceptibility to carcinogenesis.

158 on and subsequent induction of BCL6 promotes lymphomagenesis and that this pathway may be a potential

159 y controlled therapeutic targets involved in lymphomagenesis and tumor progression.

160 svirus infection has been implicated in both lymphomagenesis and, somewhat controversially, autoimmun

161 e(+)/Emicro-myc mice significantly inhibited lymphomagenesis, and all lymphomas that did arise in the

162 ht a multifaceted role for TMEM30A in B-cell lymphomagenesis, and characterize intrinsic and extrinsi

163 LCL formation serves as a model for lymphomagenesis, and LCLs are phenotypically similar to

164 viral integration site in retrovirus-induced lymphomagenesis, and new, emerging data suggest a role o

165 This study implicates oncogenic NKX2-3 in lymphomagenesis, and provides a valid experimental mouse

166 as miRNAs during B-cell differentiation and lymphomagenesis, and recent advancements in targeted str

167 mor development, accelerated Emu-Myc-induced lymphomagenesis, and rendered mice susceptible to carcin

168 ng of the processes and pathways involved in lymphomagenesis, and some of the pathways mutated here m

169 3 dysfunction, recent advances implicated in lymphomagenesis, and therapeutic approaches to overcomin

170 Lymphomagenesis appears stepwise from the t(14;18) trans

171 e found that DNA methylation profiles during lymphomagenesis are largely influenced by the methylatio

172 echanisms underlying API2-MALT1-induced MALT lymphomagenesis are not fully understood.

173 ors that predispose individuals toward viral lymphomagenesis are poorly understood.

174 t collaborative roles between MYC and EBV in lymphomagenesis are unclear.

175 quences of these mutations and their role in lymphomagenesis are unknown.

176 t Pole lymphomas, but rather likely promoted lymphomagenesis as observed in humans.

177 tion of INK4 control on Cdk4 does not affect lymphomagenesis, B-cell maturation, and functions in Cdk

178 o have implications for the role of FOXO1 in lymphomagenesis because they suggest that constitutive F

179 C1, PRC2 is a tumor suppressor in Emicro-myc lymphomagenesis, because disease onset was accelerated b

180 ase-dead (KD) ATM protein solely accelerates lymphomagenesis beyond ATM loss.

181 s of Dicer function was not advantageous for lymphomagenesis, but rather, Dicer ablation was strongly

182 of just one Rpl22 allele accelerates T-cell lymphomagenesis by activating NF-kappaB and inducing the

183 ption of one or both Patz1 alleles may favor lymphomagenesis by activating the BCL6 pathway.

184 ng indicates that EBV and KSHV contribute to lymphomagenesis by affecting genomic stability and by su

185 rant expression of FOXP1 might contribute to lymphomagenesis by blocking this terminal B-cell differe

186 somatic mutations of MEF2B may contribute to lymphomagenesis by deregulating BCL6 expression, and MEF

187 Activation-induced deaminase (AID) can drive lymphomagenesis by generating off-target DNA breaks at l

188 EBV therefore drives lymphomagenesis by hijacking long-range enhancer hubs an

189 conditional knockout in T cells accelerated lymphomagenesis by increasing cellular proliferation, wh

190 VEM interaction with BTLA may play a role in lymphomagenesis by interfering with Vgamma9Vdelta2 T-cel

191 suppressor gene whose early loss facilitates lymphomagenesis by remodeling the epigenetic landscape o

192 y and sufficient for promoting c-myc-induced lymphomagenesis by repressing apoptosis.

193 We show that loss of Dnmt1 delays lymphomagenesis by suppressing normal hematopoiesis and

194 e analyses demonstrate that miR-17~92 drives lymphomagenesis by suppressing the expression of multipl

195 ll expansion and potentially KSHV-associated lymphomagenesis by targeting C/EBPbeta.

196 e normal counterpart of FL and DLBCL, and in lymphomagenesis by using conditional GC-directed deletio

197 Lymphomagenesis can be accelerated by crossing in a furt

198 PDK1 is shown to be essential for lymphomagenesis caused by deletion of PTEN in T cell pro

199 capacity to support division, while limiting lymphomagenesis caused by deregulated growth.

200 neous craniofacial abnormalities and delayed lymphomagenesis compared with Atm(-/-) controls.

201 641F) can collaborate with Myc to accelerate lymphomagenesis demonstrating a cooperative role of EZH2

202 at HIV structural proteins may contribute to lymphomagenesis directly, because they can persist long

203 ese events are not restricted to APL because lymphomagenesis driven by deletion of p53 or, to a lesse

204 mplete ablation of Hdac1 and Hdac2 abrogated lymphomagenesis due to a block in early thymic developme

205 signaling in macrophages can promote B-cell lymphomagenesis during chronic Helicobacter infection.

206 er and how these mutations may contribute to lymphomagenesis, either individually or in combination.

207 humans and mouse models have indicated that lymphomagenesis evolves through the accumulation of mult

208 ions, opening the possibility that multi-hit lymphomagenesis gradually occurs throughout life during

209 (+/-) mice showed a dramatic acceleration of lymphomagenesis, greater even than that observed in Emic

210 ever, modeling control of gammaHV-associated lymphomagenesis has been challenging.

211 role for B-cell-receptor (BCR) signalling in lymphomagenesis has been inferred by studying immunoglob

212 A genetic or functional role for FOXP1 in lymphomagenesis, however, remains unknown.

213 ransformation during gammaherpesvirus-driven lymphomagenesis, identification of host and viral factor

214 dition, chronic CD30 signaling led to B-cell lymphomagenesis in aged mice.

215 s inhibited by rapamycin, which also rescues lymphomagenesis in Atm-deficient mice.

216 Importantly, reduced lymphomagenesis in c-Myc(Tg)CD19(-)/(-) mice was not due

217 EBNA3A contributes to efficient EBV-induced lymphomagenesis in CBH mice.IMPORTANCE The EBV protein E

218 the INK4-Cdk4 checkpoint can participate in lymphomagenesis in conjunction with additional alteratio

219 mice induces GC hyperplasia and accelerated lymphomagenesis in cooperation with BCL2.

220 , genetic inactivation of Dnmt3b accelerated lymphomagenesis in Dnmt3a(Delta/Delta) mice, demonstrati

221 ents potentially responsible for the delayed lymphomagenesis in Dnmt3a(Delta/Delta) mice.

222 As such, the loss of caspase-2 enhances lymphomagenesis in Emicro-Myc transgenic mice, and caspa

223 gnaling also appears to modulate the risk of lymphomagenesis in gastric mucosa-associated lymphoid ti

224 behind the possible different mechanisms of lymphomagenesis in HIV-associated Burkitt lymphoma and e

225 ent promotes Epstein-Barr virus (EBV)-driven lymphomagenesis in Hodgkin lymphoma by a novel pathway i

226 the many genes whose mutation contributes to lymphomagenesis in humans, relatively little is known ab

227 with gammaherpesviruses (gammaHV) can cause lymphomagenesis in immunocompromised patients.

228 vo, establish a preclinical model for B cell lymphomagenesis in immunosuppressed patients, and valida

229 The lymphomagenesis in mice derived from a reprogrammed T ce

230 omic instability and germinal center derived lymphomagenesis in mice infected with Plasmodium to recr

231 del, we observed a significant inhibition of lymphomagenesis in mice lacking one or both alleles of S

232 as and co-suppression of both genes promotes lymphomagenesis in mice.

233 malignancy or accelerate Myc-induced B-cell lymphomagenesis in mice.

234 with p53 deficiency, progressed rapidly into lymphomagenesis in mice.

235 Phip, a chromatin regulator, which suppress lymphomagenesis in mice.

236 identify which genes cooperate with BCL6 in lymphomagenesis in our BCL6 transgenic mice.

237 te that BCL6 expression is maintained during lymphomagenesis in part through DNA methylation that pre

238 mechanisms underlie genomic instability and lymphomagenesis in Rag2(c/c) p53(-/-) and Atm(-/-) mice.

239 c-rel-/- mice display significantly earlier lymphomagenesis in the c-Myc driven, Emu-Myc model of B-

240 e, and loss of Prdm11 accelerates MYC-driven lymphomagenesis in the Emicro-Myc mouse model.

241 Lymphomagenesis in the presence of deregulated MYC requi

242 SIRT3 knockout attenuated B cell lymphomagenesis in VavP-Bcl2 mice without affecting norm

243 p27(kip1) degradation process, to accelerate lymphomagenesis in vivo.

244 ency shortens the life span of, and promotes lymphomagenesis in, mice deficient in p53.

245 at Src kinase is pathogenically activated in lymphomagenesis induced by FGFR1 fusion genes, implying

246 SMZL lymphomagenesis involves antigen and/or superantigen sti

247 Previous studies have shown that MYC-driven lymphomagenesis is associated with mammalian target of r

248 ism by which Gfi1 collaborates with c-Myc in lymphomagenesis is incompletely understood.

249 It is well known that IR-induced thymic lymphomagenesis is markedly enhanced by p53 deficiency,

250 Lymphomagenesis is prevented if thymocyte development is

251 tt's lymphoma (BL), the role of the virus in lymphomagenesis is unclear.

252 2 is a serine-threonine kinase whose role in lymphomagenesis is unknown.

253 -17 approximately 92- overexpression induces lymphomagenesis/leukemogenesis, we generated a B-cell-sp

254 gest that predisposition of MIM-null mice to lymphomagenesis may involve aberrant interactions betwee

255 ons, providing evidence for a cyclic reentry lymphomagenesis mechanism.

256 ation in a mouse model of MYC-induced T-cell lymphomagenesis (MTCL).

257 deletion-induced delay in Myc-driven B-cell lymphomagenesis, nor allowed a single B-cell lymphoma to

258 ding of the pathogenesis of autoimmunity and lymphomagenesis of autoimmune lymphoproliferative syndro

259 e role of specific signaling pathways in the lymphomagenesis of MCL and the biologic basis for ibruti

260 sus-like disease of BXSB.Yaa mice and B cell lymphomagenesis of SJL mice.

261 cell growth in mouse xenografts and postpone lymphomagenesis onset in murine transplantation models.

262 pients might be exposed to increased risk of lymphomagenesis or autoimmunity.

263 to reveal novel factors that participate in lymphomagenesis or to define biomarkers of onset or prog

264 V-6A genome from the telomere contributed to lymphomagenesis, or was coincidental, remains unclear bu

265 t gene results in protection from IR-induced lymphomagenesis rather than enhanced susceptibility to.

266 chd1 in Emu-Myc transgenic mice that undergo lymphomagenesis reduced disease latency by 50% relative

267 ement of lesions at the very early stages of lymphomagenesis, refines the diagnostic criteria for som

268 mechanisms that contribute to EBV-associated lymphomagenesis remain unclear.

269 the relevance of these 2 FL BCR features for lymphomagenesis remains unclear.

270 Furthermore, lymphomagenesis requires the expression of both prerearr

271 ts dysregulation, frequently associated with lymphomagenesis, requires robust dynamical modeling tech

272 penetrance and that, conversely, Myc-driven lymphomagenesis stringently requires two intact alleles

273 BCL that suppresses B-cell proliferation and lymphomagenesis, suggesting pharmaceutical targeting of

274 serial transplantation models of MYC-driven lymphomagenesis, supporting the idea that the mutational

275 Our findings identify Ment as an enhancer of lymphomagenesis that contributes to the tumor suppressor

276 ght into the role of the microenvironment in lymphomagenesis, these findings expose a unique molecula

277 7 overexpression also promotes mature B-cell lymphomagenesis; this is physiologically relevant as we

278 ations and deletions in FBXO11 contribute to lymphomagenesis through BCL6 stabilization.

279 iates the humoral immune response and drives lymphomagenesis through formation of bivalent chromatin

280 rging evidence supports a key role of AID in lymphomagenesis through genome-wide off-target induction

281 of routine residential UVR exposure against lymphomagenesis through mechanisms possibly independent

282 oes not change the overall rate, it modifies lymphomagenesis to favor mature B cell lymphomas that ar

283 port that SIRT4 represses Myc-induced B cell lymphomagenesis via inhibition of mitochondrial glutamin

284 of T-cell malignancy, and found that T-cell lymphomagenesis was accelerated in mice bearing both mut

285 Accelerated lymphomagenesis was associated with increased accumulati

286 To study the role of Notch in T-cell lymphomagenesis, we developed a highly tumorigenic cell

287 further characterize these EZH2 mutations in lymphomagenesis, we generated a mouse line where EZH2(Y6

288 nd the role of miRNAs in B cell function and lymphomagenesis, we generated short-RNA libraries from n

289 To identify TFs central to lymphomagenesis, we identified lymphoma type-specific ac

290 To understand how PRD suppresses lymphomagenesis, we introduced the cancer-associated PRD

291 e p53 deficient mouse model with accelerated lymphomagenesis, we previously observed whole chromosome

292 ein synthesis and attenuation of Myc-induced lymphomagenesis, we showed that Myc-induced UPR activati

293 rts its effects and how it may contribute to lymphomagenesis, we sought to characterize the outcome o

294 e relationship between parasitic disease and lymphomagenesis, we used Plasmodium chabaudi (Pc) to pro

295 P1 together with LMP2A, EBNA3A only promotes lymphomagenesis when the EBNA2 target Myc is also overex

296 ficiency of Smarcal1 resulted in accelerated lymphomagenesis, whereas haploinsufficiency of Zranb3 in

297 ar subsets has implications for human B cell lymphomagenesis, which originates mostly from GC B cells

298 or during the onset of Emu-myc-driven B cell lymphomagenesis, while p73 modulated tumor dissemination

299 of PTEN was found to be a powerful driver of lymphomagenesis within the thymus characterized by overe

300 s a layer of Myc autoregulation critical for lymphomagenesis yet partly dispensable for normal develo