Sending positive signals and good (calcium) vibes

In this issue of JEM, Yada et al. (https://doi.org/10.1084/jem.20222178) demonstrate that effective antibody affinity selection in germinal centers relies on the store-operated calcium entry (SOCE) component of the B cell receptor (BCR) signaling network. Therefore, active BCR signaling is as relevant to positive selection as the function of BCRs as endocytic receptors, answering a question that had puzzled experts for a while. These findings transform our understanding of the mechanisms supporting adaptive immune responses (to vaccines, for example) and have important implications for interpreting the genomics and pathogenesis of germinal center-derived B cell lymphomas.

Cutting Edge: Neutrophil Complement Receptor Signaling Is Required for BAFF-Dependent Humoral Responses in Mice

T cell-independent (TI) B cell responses to nonprotein Ags involve multiple cues from the innate immune system. Neutrophils express complement receptors and activated neutrophils can release BAFF, but mechanisms effectively linking neutrophil activation to TI B cell responses are incompletely understood. Using germline and conditional knockout mice, we found that TI humoral responses involve alternative pathway complement activation and neutrophil-expressed C3a and C5a receptors (C3aR1/C5aR1) that promote BAFF-dependent B1 cell expansion and TI Ab production. Conditional absence of C3aR1/C5aR1 on neutrophils lowered serum BAFF levels, led to fewer Peyer's patch germinal center B cells, reduced germinal center B cells IgA class-switching, and lowered fecal IgA levels. Together, the results indicate that sequential activation of complement on neutrophils crucially supports humoral TI and mucosal IgA responses through upregulating neutrophil production of BAFF.

Mutations in the transcription factor FOXO1 mimic positive selection signals to promote germinal center B cell expansion and lymphomagenesis

The transcription factor forkhead box O1 (FOXO1), which instructs the dark zone program to direct germinal center (GC) polarity, is typically inactivated by phosphatidylinositol 3-kinase (PI3K) signals. Here, we investigated how FOXO1 mutations targeting this regulatory axis in GC-derived B cell non-Hodgkin lymphomas (B-NHLs) contribute to lymphomagenesis. Examination of primary B-NHL tissues revealed that FOXO1 mutations and PI3K pathway activity were not directly correlated. Human B cell lines bearing FOXO1 mutations exhibited hyperactivation of PI3K and Stress-activated protein kinase (SAPK)/Jun amino-terminal kinase (JNK) signaling, and increased cell survival under stress conditions as a result of alterations in FOXO1 transcriptional affinities and activation of transcriptional programs characteristic of GC-positive selection. When modeled in mice, FOXO1 mutations conferred competitive advantage to B cells in response to key T-dependent immune signals, disrupting GC homeostasis. FOXO1 mutant transcriptional signatures were prevalent in human B-NHL and predicted poor clinical outcomes. Thus, rather than enforcing FOXO1 constitutive activity, FOXO1 mutations enable co-option of GC-positive selection programs during the pathogenesis of GC-derived lymphomas.

Dynamic regulation of B cell complement signaling is integral to germinal center responses

B cell maturation within germinal centers (GCs) generates diversified B cell pools and high-affinity B cell antigen receptors (BCRs) for pathogen clearance. Increased receptor affinity is achieved by iterative cycles of T cell-dependent, affinity-based B cell positive selection and clonal expansion by incompletely understood mechanisms. Here, we found that as part of a physiologic program, GC B cells repressed expression of decay-accelerating factor (DAF/CD55) and other complement C3-convertase regulators via Bcl-6, but increased C5b-9 inhibitor (CD59) expression. These changes permitted C3 cleavage on GC B cell surfaces, without membrane attack complex formation, and activated C3a-receptor and C5a-receptor signals required for positive selection. Genetic disruption of this pathway in antigen-activated B cells, by conditional transgenic DAF overexpression or deletion of C3a and C5a receptors, limited mTOR activity in response to BCR-CD40 signaling, causing premature GC collapse and impaired affinity maturation. These results reveal that coordinated shifts in complement regulation within the GC provide crucial signals underlying GC B cell positive selection.

Mammalian Cell Fusion Assays for the Study of Cell Cycle Progression by Functional Complementation

Cell cycle progression, or its arrest upon checkpoint activation, is directed by a complex array of cellular processes dependent on the diffusion of chemical signals. These signals regulate the onset of each cell cycle phase and prevent undesired phase transitions. Functional complementation is a robust strategy to identify such signals, by which mutant phenotypes are rescued through complementation with candidate factors. Here we describe a method that reclaims a five-decade old mammalian cell-cell fusion strategy of functional complementation to study the molecular control of cell cycle progression. The generation of cell-cell fusions (heterokaryons) allows for the analysis, via immunofluorescence, of cell cycle regulator dynamics and evaluating the effective rescue of cell cycle progression in specific genetic settings.

Abstract PO-36: Functional bypass of cell cycle entry checkpoints by MYC T58A mutation in germinal center-derived lymphomas

Somatic missense mutations targeting MYC's coding sequence are found in >50% of Burkitt lymphomas and in a small fraction of diffuse large B-cell lymphomas. These mutations typically arise in translocated MYC alleles and cluster at specific protein residues, particularly Threonine 58 (T58). Previous studies in non-B cell models suggested that MYC mutations enhance oncogenic properties by escaping MYC-induced apoptosis. However, the functional impact of these mutations on the biology of germinal center (GC) B cells, where these mutations arise, has never been investigated. In GC B cells, MYC expression is induced by positive selection signals during cognate interactions with T follicular helper cells, concurrent with activation of PI3K and mTOR signaling. PI3K and mTOR are activated upon CD40 and B-cell receptor co-engagement and are critically required for positive selection and clonal expansion of GC B cells. Using newly generated MYC T58A knock-in mouse models, we found that MYC T58A mutation allows B cells to bypass a cell cycle entry checkpoint dependent on PI3K and mTOR activities. Exposure of wild-type (WT) B cells to rapamycin or, less markedly, to PI3K inhibitors, prevented the proliferation upon CD40 and IL4 stimulation ex vivo (a cytokine combination mimicking T-cell help) whereas MYC T58A mutant B cells divided multiple times and maintained adequate rates of active biosynthesis. Similarly, administration of rapamycin to immunized WT mice collapsed formed GCs while MYC T58A GCs maintained normal size and proliferation rates in vivo. These phenotypes were in part explained by the effects of PI3K/mTOR signaling on GSK3-beta, a kinase that normally phosphorylates MYC T58 to control protein turnover. Differences in metabolic and gene expression profiles between MYC WT and T58A cells offered additional insights into the mechanisms by which this mutation bypasses PI3K/mTOR checkpoint. Finally, we found that GC B cell-specific overexpression of MYC T58A, resulted in abnormally enlarged GCs upon immunization, a phenotype common to lymphoma models. Altogether, these results indicate that MYC somatic mutations confer competitive advantages to B cells by bypassing a strict requirement for upstream signals during cell cycle entry, which may support the clonal expansion of MYC mutant B cells during GC responses. These results have important translational implications, particularly given the increasing interest in the potential use of PI3K and/or mTOR inhibitors in the treatment of lymphomas.

Citation Format: Jongkuen Lee, David Dominguez-Sola. Functional bypass of cell cycle entry checkpoints by MYC T58A mutation in germinal center-derived lymphomas [abstract]. In: Proceedings of the AACR Virtual Meeting: Advances in Malignant Lymphoma; 2020 Aug 17-19. Philadelphia (PA): AACR; Blood Cancer Discov 2020;1(3_Suppl):Abstract nr PO-36.

Abstract PO-40: FOXO1 mutations mimic positive selection signals to promote germinal center B-cell expansion and lymphomagenesis

The transcription factor FOXO1 directs germinal center (GC) polarity and supports affinity maturation by modulating immune activation programs in GC B cells. Recurrent somatic mutations targeting FOXO1 in GC-derived B-cell non-Hodgkin lymphomas (B-NHL) are thought to disrupt its negative regulation by PI3K and function as gain-of-function, constitutively active alleles. Herein, we demonstrate that B-NHL FOXO1 mutants are instead hypomorphic alleles encoding proteins with altered transcriptional activities. Analysis of Foxo1 mutant mouse models, engineered cell lines, and primary samples shows that B-NHL FOXO1 mutations induce simultaneous hyperactivation of Stress Activated Protein Kinase -SAPK/JNK and Phosphoinositide 3-kinase -PI3K/AKT signaling pathways and gene expression programs characteristic of GC B cells undergoing positive selection. These alterations confer mutant B cells with a competitive advantage in response to key immune signals, leading to abnormal amplification of GC responses. Moreover, we find that FOXO1 mutant-driven transcriptional programs are prevalent in human B-NHL and predict poor clinical outcomes. These results imply the frequent co-option of GC positive selection programs in the pathogenesis of GC-derived lymphomas.

Citation Format: Mark P. Roberto, Gabriele Varano, Rosa Viñas-Castells, Antony B. Holmes, Rahul Kumar, Pedro Farinha, David W. Scott, David Dominguez-Sola. FOXO1 mutations mimic positive selection signals to promote germinal center B-cell expansion and lymphomagenesis [abstract]. In: Proceedings of the AACR Virtual Meeting: Advances in Malignant Lymphoma; 2020 Aug 17-19. Philadelphia (PA): AACR; Blood Cancer Discov 2020;1(3_Suppl):Abstract nr PO-40.

PRDM15 is a key regulator of metabolism critical to sustain B-cell lymphomagenesis

PRDM (PRDI-BF1 and RIZ homology domain containing) family members are sequence-specific transcriptional regulators involved in cell identity and fate determination, often dysregulated in cancer. The PRDM15 gene is of particular interest, given its low expression in adult tissues and its overexpression in B-cell lymphomas. Despite its well characterized role in stem cell biology and during early development, the role of PRDM15 in cancer remains obscure. Herein, we demonstrate that while PRDM15 is largely dispensable for mouse adult somatic cell homeostasis in vivo, it plays a critical role in B-cell lymphomagenesis. Mechanistically, PRDM15 regulates a transcriptional program that sustains the activity of the PI3K/AKT/mTOR pathway and glycolysis in B-cell lymphomas. Abrogation of PRDM15 induces a metabolic crisis and selective death of lymphoma cells. Collectively, our data demonstrate that PRDM15 fuels the metabolic requirement of B-cell lymphomas and validate it as an attractive and previously unrecognized target in oncology.

Analysis of the Germinal Center Reaction in Tissue Sections

Germinal centers are short-lived microanatomical compartments with essential roles in adaptive immunity. These lymphoid structures can be identified in secondary lymphoid organs using both flow cytometry and immunohistological analyses, but only the latter provides useful architectural and spatial information. Here we describe how to use immunofluorescence and immunohistochemistry with specific antibodies to precisely highlight the cellular and architectural features of germinal centers, both in human and mouse secondary lymphoid organs, and to study their normal development and disturbance in disease.

FBXO11 inactivation leads to abnormal germinal-center formation and lymphoproliferative disease

The BCL6 proto-oncogene encodes a transcriptional repressor that is required for the germinal center (GC) reaction and is implicated in lymphomagenesis. BCL6 protein stability is regulated by F-box protein 11 (FBXO11)-mediated ubiquitination and degradation, which is impaired in ∼6% of diffuse large B-cell lymphomas that carry inactivating genetic alterations targeting the FBXO11 gene. In order to investigate the role of FBXO11 in vivo, we analyzed GC-specific FBXO11 knockout mice. FBXO11 reduction or loss led to an increased number of GC B cells, to an altered ratio of GC dark zone to light zone cells, and to higher levels of BCL6 protein in GC B cells. B-cell receptor-mediated degradation of BCL6 was reduced in the absence of FBXO11, suggesting that FBXO11 contributes to the physiologic downregulation of BCL6 at the end of the GC reaction. Finally, FBXO11 inactivation was associated with the development of lymphoproliferative disorders in mice.

Abstract B25: Disruption of KMT2D-dependent histone methylation perturbs GC B cell development and cooperates with BCL2 deregulation in lymphomagenesis

Modulation of chromatin accessibility through histone modification is a key step in the regulation of gene transcription and its disruption by genetic lesions has been implicated in malignant transformation. Indeed, a consistent theme in recent cancer genome studies has been the discovery of recurrent mutations in multiple histone/chromatin modifier genes, including methyltransferases, acetyltransferases and histone themselves. Among these, KMT2D (MLL2 or MLL4), encoding for a histone H3K4 methyltransferase, emerged as one of the most common targets of genetic lesion in B cell non-Hodgkin lymphoma, being found in ~30% of diffuse large B cell lymphoma (DLBCL) and ~90% of follicular lymphoma (FL), which together account for over 70% of all lymphoma diagnoses (Pasqualucci et al, Nat Genetics 2011; Morin et al, Nature 2011). KMT2D mutations are mostly represented by truncating events that are predicted to remove the protein C-terminal enzymatic domains, thus inactivating its function; however, missense mutations were also found in a subset of cases, suggesting selection for a functional role. These events are biallelically distributed in one third of mutated cases, while the remaining >60% harbor monoallelic mutations, consistent with a role as a tumor suppressor. Interestingly, analysis of the history of clonal evolution during FL transformation to DLBCL suggests that KMT2D mutations may be already present in a common precursor clone before divergent evolution to FL or DLBCL, suggesting an early role during B cell clonal expansion (Pasqualucci et al, Cell Rep, 2014; Green et al, Blood, 2013).

To elucidate the functional consequences of KMT2D mutations, we first examined the effects of 16 DLBCL/FL-derived KMT2D missense mutant alleles on its enzymatic activity in vitro. The results showed that all 8 mutants located in the C-terminal portion of the protein were associated with significantly diminished H3K4 mono-, di- and tri-methylation activity. Consistently, a significant reduction in global methylation was observed in Kmt2d deficient murine B-cells, as well as in 4 biallelically truncated cell lines, indicating that this methyltransferase can influence all three H3K4 modifications.

To gain further insights into the program regulated by KMT2D in germinal center (GC) B cells (i.e. the normal counterpart of FL/DLBCL) and the mechanism by which its loss contributes to lymphomagenesis, we crossed mice carrying a conditional Kmt2d knockout allele (Lee J et al, Elife, 2013) with either CD19Cre or Cγ1Cre deletor mice, leading to gene inactivation early during B-cell development (Kmt2dCD19KO), thus mimicking the postulated “common precursor model,” or specifically in mature, GC B-cells (Kmt2dCγ1KO). Notably, deletion of Kmt2d before, but not after initiation of the GC reaction led to a significant increase in GC B-cells and enhanced B cell proliferation. These changes were accompanied by the acquisition of distinct transcriptional signatures enriched in cell cycle regulation and apoptosis genes. A cross-species strategy combining gene expression profile analysis of murine GC B-cells and Kmt2d chromatin immunoprecipitation and sequencing of purified human GC B cells identified a core of KMT2D direct targets genes involved in biological programs with critical functions in B cells physiology, including B cell receptor signaling, lymphocyte migration, and chemokine signaling components. Finally, while loss of Kmt2d alone in Kmt2dCγ1KO was not sufficient to induce tumor development, its combination with VavP-BCL2 transgenic mice increased the incidence of GC-derived lymphomas resembling the features of the human tumors. These data support a role for KMT2D as a tumor suppressor gene whose early loss during B cell development facilitates lymphomagenesis by remodeling the epigenetic landscape of the cancer precursor cell.

Citation Format: Jiyuan Zhang, David Dominguez-Sola, Shafinaz Hussein, Ji-Eun Lee, Antony B. Holmes, Mukesh Bansal, Sofija Vlasevska, Tongwei Mo, Hongyan Tang, Katia Basso, Kai Ge, Riccardo Dalla-Favera, Laura Pasqualucci. Disruption of KMT2D-dependent histone methylation perturbs GC B cell development and cooperates with BCL2 deregulation in lymphomagenesis. [abstract]. In: Proceedings of the AACR Special Conference on Chromatin and Epigenetics in Cancer; Sep 24-27, 2015; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2016;76(2 Suppl):Abstract nr B25.

Disruption of KMT2D perturbs germinal center B cell development and promotes lymphomagenesis

Mutations in the gene encoding the KMT2D (or MLL2) methyltransferase are highly recurrent and occur early during tumorigenesis in diffuse large B cell lymphoma (DLBCL) and follicular lymphoma (FL). However, the functional consequences of these mutations and their role in lymphomagenesis are unknown. Here we show that FL- and DLBCL-associated KMT2D mutations impair KMT2D enzymatic activity, leading to diminished global H3K4 methylation in germinal-center (GC) B cells and DLBCL cells. Conditional deletion of Kmt2d early during B cell development, but not after initiation of the GC reaction, results in an increase in GC B cells and enhances B cell proliferation in mice. Moreover, genetic ablation of Kmt2d in mice overexpressing Bcl2 increases the incidence of GC-derived lymphomas resembling human tumors. These findings suggest that KMT2D acts as a tumor suppressor gene whose early loss facilitates lymphomagenesis by remodeling the epigenetic landscape of the cancer precursor cells. Eradication of KMT2D-deficient cells may thus represent a rational therapeutic approach for targeting early tumorigenic events.

p14ARF directly interacts with Myc through the Myc BoxII domain

Myc is a well known proto-oncogene encoding for a transcription factor whose activity is tightly regulated in the cellular context. Myc was the first oncogene recognized to activate the ARF tumor suppressor gene which suppresses cell proliferation partly through stabilization of the p53 tumor suppressor protein but which also has p53-independent growth-suppressive functions. Recent studies have indicated that mouse p19ARF negatively regulates Myc's transcriptional activity. We here show that the human p14ARF directly associates with Myc and relocates Myc from the nucleoplasm to the nucleolus. We found that p14ARF interacts with the Myc-Max complex and the binding of p14ARF does not interfere with Myc-Max interaction in vitro. Protein interaction assays define the Myc BoxII as a critical domain required for interaction with p14ARF. Moreover, we identify 30 amino acids encompassing Myc BoxII domain required for p14ARF interaction and colocalization in vivo. Finally, we show that p14ARF down regulates Myc activated transcription and that this activity cannot be addressed to an intrinsic p14ARF repressor domain.

MYC and the control of DNA replication

The MYC oncogene is a multifunctional protein that is aberrantly expressed in a significant fraction of tumors from diverse tissue origins. Because of its multifunctional nature, it has been difficult to delineate the exact contributions of MYC's diverse roles to tumorigenesis. Here, we review the normal role of MYC in regulating DNA replication as well as its ability to generate DNA replication stress when overexpressed. Finally, we discuss the possible mechanisms by which replication stress induced by aberrant MYC expression could contribute to genomic instability and cancer.

Distinction between asymptomatic monoclonal B-cell lymphocytosis with cyclin D1 overexpression and mantle cell lymphoma: from molecular profiling to flow cytometry

PURPOSE

According to current diagnostic criteria, mantle cell lymphoma (MCL) encompasses the usual, aggressive variants and rare, nonnodal cases with monoclonal asymptomatic lymphocytosis, cyclin D1-positive (MALD1). We aimed to understand the biology behind this clinical heterogeneity and to identify markers for adequate identification of MALD1 cases.

EXPERIMENTAL DESIGN

We compared 17 typical MCL cases with a homogeneous group of 13 untreated MALD1 cases (median follow-up, 71 months). We conducted gene expression profiling with functional analysis in five MCL and five MALD1. Results were validated in 12 MCL and 8 MALD1 additional cases by quantitative reverse transcription polymerase chain reaction (qRT-PCR) and in 24 MCL and 13 MALD1 cases by flow cytometry. Classification and regression trees strategy was used to generate an algorithm based on CD38 and CD200 expression by flow cytometry.

RESULTS

We found 171 differentially expressed genes with enrichment of neoplastic behavior and cell proliferation signatures in MCL. Conversely, MALD1 was enriched in gene sets related to immune activation and inflammatory responses. CD38 and CD200 were differentially expressed between MCL and MALD1 and confirmed by flow cytometry (median CD38, 89% vs. 14%; median CD200, 0% vs. 24%, respectively). Assessment of both proteins allowed classifying 85% (11 of 13) of MALD1 cases whereas 15% remained unclassified. SOX11 expression by qRT-PCR was significantly different between MCL and MALD1 groups but did not improve the classification.

CONCLUSION

We show for the first time that MALD1, in contrast to MCL, is characterized by immune activation and driven by inflammatory cues. Assessment of CD38/CD200 by flow cytometry is useful to distinguish most cases of MALD1 from MCL in the clinical setting. MALD1 should be identified and segregated from the current MCL category to avoid overdiagnosis and unnecessary treatment.

MEF2B mutations lead to deregulated expression of the oncogene BCL6 in diffuse large B cell lymphoma

MEF2B encodes a transcriptional activator and is mutated in ∼11% of diffuse large B cell lymphomas (DLBCLs) and ∼12% of follicular lymphomas (FLs). Here we found that MEF2B directly activated the transcription of the proto-oncogene BCL6 in normal germinal-center (GC) B cells and was required for DLBCL proliferation. Mutation of MEF2B resulted in enhanced transcriptional activity of MEF2B either through disruption of its interaction with the corepressor CABIN1 or by rendering it insensitive to inhibitory signaling events mediated by phosphorylation and sumoylation. Consequently, the transcriptional activity of Bcl-6 was deregulated in DLBCLs with MEF2B mutations. Thus, somatic mutations of MEF2B may contribute to lymphomagenesis by deregulating BCL6 expression, and MEF2B may represent an alternative target for blocking Bcl-6 activity in DLBCLs.

Cdc45 is a critical effector of myc-dependent DNA replication stress

c-Myc oncogenic activity is thought to be mediated in part by its ability to generate DNA replication stress and subsequent genomic instability when deregulated. Previous studies have demonstrated a nontranscriptional role for c-Myc in regulating DNA replication. Here, we analyze the mechanisms by which c-Myc deregulation generates DNA replication stress. We find that overexpression of c-Myc alters the spatiotemporal program of replication initiation by increasing the density of early-replicating origins. We further show that c-Myc deregulation results in elevated replication-fork stalling or collapse and subsequent DNA damage. Notably, these phenotypes are independent of RNA transcription. Finally, we demonstrate that overexpression of Cdc45 recapitulates all c-Myc-induced replication and damage phenotypes and that Cdc45 and GINS function downstream of Myc.

The proto-oncogene MYC is required for selection in the germinal center and cyclic reentry

After antigenic challenge, B cells enter the dark zone (DZ) of germinal centers (GCs) to proliferate and hypermutate their immunoglobulin genes. Mutants with greater affinity for the antigen are positively selected in the light zone (LZ) to either differentiate into plasma and memory cells or reenter the DZ. The molecular circuits that govern positive selection in the GC are not known. We show here that the GC reaction required biphasic regulation of expression of the cell-cycle regulator c-Myc that involved its transient induction during early GC commitment, its repression by Bcl-6 in DZ B cells and its reinduction in B cells selected for reentry into the DZ. Inhibition of c-Myc in vivo led to GC collapse, which indicated an essential role for c-Myc in GCs. Our results have implications for the mechanism of GC selection and the role of c-Myc in lymphomagenesis.

Identification of human germinal center light and dark zone cells and their relationship to human B-cell lymphomas

Germinal centers (GCs) are sites of B-cell clonal expansion, hypermutation, and selection. GCs are polarized into dark (DZ) and light zones (LZ), a distinction that is of key importance to GC selection. However, the difference between the B cells in each of these zones in humans remains unclear. We show that, as in mice, CXCR4 and CD83 can be used to distinguish human LZ and DZ cells. Using these markers, we show that LZ and DZ cells in mice and humans differ only in the expression of characteristic "activation" and "proliferation" programs, suggesting that these populations represent alternating states of a single-cell type rather than distinct differentiation stages. In addition, LZ/DZ transcriptional profiling shows that, with the exception of "molecular" Burkitt lymphomas, nearly all human B-cell malignancies closely resemble LZ cells, which has important implications for our understanding of the molecular programs of lymphomagenesis.

Burkitt lymphoma: much more than MYC

Chromosomal translocations causing deregulated c-MYC expression are detectable in most Burkitt lymphoma cases. However, little is known about the additional lesions necessary for lymphomagenesis. Now, two independent studies, one of which was performed by Sander et al. in this issue of Cancer Cell, identify constitutive PI3K signaling and CyclinD3 mutations as cooperating lesions in both mice and humans. The results have directly actionable therapeutic implications.

Combined genetic inactivation of β2-Microglobulin and CD58 reveals frequent escape from immune recognition in diffuse large B cell lymphoma

We report that diffuse large B cell lymphoma (DLBCL) commonly fails to express cell-surface molecules necessary for the recognition of tumor cells by immune-effector cells. In 29% of cases, mutations and deletions inactivate the β2-Microglobulin gene, thus preventing the cell-surface expression of the HLA class-I (HLA-I) complex that is necessary for recognition by CD8(+) cytotoxic T cells. In 21% of cases, analogous lesions involve the CD58 gene, which encodes a molecule involved in T and natural killer cell-mediated responses. In addition to gene inactivation, alternative mechanisms lead to aberrant expression of HLA-I and CD58 in >60% of DLBCL. These two events are significantly associated in this disease, suggesting that they are coselected during lymphomagenesis for their combined role in escape from immune-surveillance.

Non-transcriptional control of DNA replication by c-Myc

The c-Myc proto-oncogene encodes a transcription factor that is essential for cell growth and proliferation and is broadly implicated in tumorigenesis. However, the biological functions required by c-Myc to induce oncogenesis remain elusive. Here we show that c-Myc has a direct role in the control of DNA replication. c-Myc interacts with the pre-replicative complex and localizes to early sites of DNA synthesis. Depletion of c-Myc from mammalian (human and mouse) cells as well as from Xenopus cell-free extracts, which are devoid of RNA transcription, demonstrates a non-transcriptional role for c-Myc in the initiation of DNA replication. Overexpression of c-Myc causes increased replication origin activity with subsequent DNA damage and checkpoint activation. These findings identify a critical function of c-Myc in DNA replication and suggest a novel mechanism for its normal and oncogenic functions.