Project description:The transcription factor FOXO1 directs germinal center (GC) polarity and supports affinity maturation by silencing immune activation programs in GC B cells. Recurrent somatic mutations in GC-derived B cell non-Hodgkin lymphomas (B-NHL) often target and reportedly activate FOXO1 by preventing its negative regulation by PI3K. Herein, using ad hoc mouse models, engineered cell lines and primary tumor specimens, we show instead that FOXO1 mutant proteins display altered transcriptional activities suggestive of partial loss-of-function. These defects drive simultaneous hyperactivation of signaling pathways (Stress Activated Protein Kinase -SAPK/JNK, Phosphoinositide 3-kinase -PI3K/AKT) and gene expression programs typically activated in GC B cells upon positive selection. Such changes confer mutant B cells with competitive advantages in response to key immune signals, leading to abnormal amplification of GC responses. Evidence of these FOXO1 ‘mutant’ gene programs can be found in a fraction of human B-NHL and predict clinical outcome, thus implying the frequent co-option of positive selection programs during GC-derived B-NHL pathogenesis.

Project description:The transcription factor FOXO1 directs germinal center (GC) polarity and supports affinity maturation by silencing immune activation programs in GC B cells. Recurrent somatic mutations in GC-derived B cell non-Hodgkin lymphomas (B-NHL) often target and reportedly activate FOXO1 by preventing its negative regulation by PI3K. Herein, using ad hoc mouse models, engineered cell lines and primary tumor specimens, we show instead that FOXO1 mutant proteins display altered transcriptional activities suggestive of partial loss-of-function. These defects drive simultaneous hyperactivation of signaling pathways (Stress Activated Protein Kinase -SAPK/JNK, Phosphoinositide 3-kinase -PI3K/AKT) and gene expression programs typically activated in GC B cells upon positive selection. Such changes confer mutant B cells with competitive advantages in response to key immune signals, leading to abnormal amplification of GC responses. Evidence of these FOXO1 ‘mutant’ gene programs can be found in a fraction of human B-NHL and predict clinical outcome, thus implying the frequent co-option of positive selection programs during GC-derived B-NHL pathogenesis.

Project description:PI3K signaling and FOXO transcription factors play opposing roles at several B cell developmental stages. We show here abundant nuclear FOXO1 expression in the proliferative compartment of the germinal center (GC), its dark zone (DZ), and PI3K activity, downregulating FOXO1, in the GC light zone (LZ), where cells are selected for further differentiation. However, here FOXO1 is expressed in c-Myc+ cells destined for DZ reentry. Upon FOXO1 ablation by genetic means or induction of PI3K activity GCs become devoid of their DZ, due at least partly to the downregulation of the chemokine receptor CXCR4. While this is known to prevent proper cyclic selection of cells expressing high-affinity antibodies, the initiation of immunoglobulin switching is essentially dependent on FOXO1 activity. All samples were obtained from mouse germinal center (GC) B cells (Cgamma1-cre; YFP, P110*, FOXO1 f/f or PTEN f/f animals). Cells used for microarray analysis were FACS sorted cells.

Project description:PI3K signaling and FOXO transcription factors play opposing roles at several B cell developmental stages. We show here abundant nuclear FOXO1 expression in the proliferative compartment of the germinal center (GC), its dark zone (DZ), and PI3K activity, downregulating FOXO1, in the GC light zone (LZ), where cells are selected for further differentiation. However, here FOXO1 is expressed in c-Myc+ cells destined for DZ reentry. Upon FOXO1 ablation by genetic means or induction of PI3K activity GCs become devoid of their DZ, due at least partly to the downregulation of the chemokine receptor CXCR4. While this is known to prevent proper cyclic selection of cells expressing high-affinity antibodies, the initiation of immunoglobulin switching is essentially dependent on FOXO1 activity.

Project description:FOXO1 acts as a tumor suppressor in solid tumors. The oncogenic PI3K pathway suppresses FOXO1 transcriptional activity by enforcing its nuclear exclusion upon AKT-mediated phosphorylation. We show here abundant nuclear expression of FOXO1 in Burkitt lymphoma (BL), a germinal center (GC) B cell derived lymphoma whose pathogenesis is linked to PI3K activation. Recurrent FOXO1 mutations which prevent AKT targeting and lock the transcription factor in the nucleus are used by BL to circumvent mutual exclusivity between PI3K and FOXO1 activation. Using genome editing in human and mouse lymphomas in which MYC and PI3K cooperate synergistically in tumor development we demonstrate pro-proliferative and anti-apoptotic activity of FOXO1 in BL and identify its nuclear localization as an oncogenic event in GC B cell derived lymphomagenesis.

Project description:The pathways regulating the formation of the germinal center (GC) dark- (DZ) and light- (LZ) zones are unknown. We show that FOXO1 expression is restricted to the GC DZ and is required for DZ formation, since its absence in mice leads to the complete loss of DZ gene programs and the formation of LZ-only GCs. FOXO1-negative GC B-cells display normal somatic hypermutation, but defective affinity maturation and class switch recombination. The function of FOXO1 in sustaining the DZ program involves the transactivation of the chemokine receptor CXCR4, and the cooperation with BCL6 in the trans-repression of genes involved in immune activation, DNA-repair and plasma cell differentiation. These results have also implications for understanding the role of FOXO1 mutations in lymphomagenesis. We used microarrays to determine the consequences of FOXO1 deletion in the GC B cell comparment, and correlate these data with phenotypic changes GC B cell subpopulations were collected by Fluorescence Activated Cell Sorting (FACS) from B cell enriched fractions of splenic mononuclear cell pools (12 days after SRBC immunization). 20ng of total RNA (RIN>9) for each sample was used as a template for linear cDNA amplification (Ovation RNA amplification Kit, NuGen). cDNA was labeled using the Encore Biotin Labeling Kit (NuGen) and hybridized to Affymetrix Mouse 430.2 gene expression arrays

Project description:The pathways regulating the formation of the germinal center (GC) dark- (DZ) and light- (LZ) zones are unknown. We show that FOXO1 expression is restricted to the GC DZ and is required for DZ formation, since its absence in mice leads to the complete loss of DZ gene programs and the formation of LZ-only GCs. FOXO1-negative GC B-cells display normal somatic hypermutation, but defective affinity maturation and class switch recombination. The function of FOXO1 in sustaining the DZ program involves the transactivation of the chemokine receptor CXCR4, and the cooperation with BCL6 in the trans-repression of genes involved in immune activation, DNA-repair and plasma cell differentiation. These results have also implications for understanding the role of FOXO1 mutations in lymphomagenesis. We used microarrays to determine the consequences of FOXO1 deletion in the GC B cell comparment, and correlate these data with phenotypic changes

Project description:This SuperSeries is composed of the following subset Series: GSE40655: Novel Foxo1-dependent Transcriptional Programs Control Treg Cell Function [Affymetrix gene expression data] GSE40656: Novel Foxo1-dependent Transcriptional Programs Control Treg Cell Function [ChIP-Seq] Refer to individual Series

Project description:Mapping of WT FOXO1 and M1L FOXO1 binding sites in SUDHL4 cells

Project description:Germinal center (GC) B cells cycle between two states, the light zone (LZ) and the dark zone (DZ), and in the latter they proliferate and hypermutate their immunoglobulin genes. How this functional transition takes place is still controversial. In this study, we demonstrate that ablation of Foxo1 after GC development led to the loss of the DZ GC B cells and disruption of the GC architecture. Mechanistically, even upon provision of adequate T cell help, Foxo1-deficient GC B cells showed less proliferative expansion than controls. Moreover, we found that the transcription factor BATF was transiently induced in LZ GC B cells in a Foxo1-dependent manner and that deletion of BATF similarly led to GC disruption. Thus, our results are consistent with a model where the switch from the LZ to the DZ is triggered after receipt of T cell help, and suggest that Foxo1-mediated BATF up-regulation is at least partly involved in this switch.