In addition to its proapoptotic function, caspase-8 is also important for several other processes, including suppressing necroptosis, cell migration, and immune cell survival. In the present study, we report that the loss of caspase-8 in B lymphocytes leads to B-cell malignancies and that the risk for these tumors is further enhanced in the absence of p53. We also report that deficiency of caspase-8 results in impaired cytokinesis and that casp8−/− lymphomas display remarkably elevated levels of chromosomal aberrations. Our data support an important role for caspase-8 in the maintenance of genomic integrity and highlight its tumor-suppressive function.
Introduction
Deregulation of apoptosis has been linked to the pathogenesis of human cancer.1 Caspases are essential for both the death receptor and the mitochondrial apoptotic pathways.2 In addition to the critical role that caspase-8 (casp8) plays in the death receptor apoptotic pathway, mounting evidence also supports its nonapoptotic functions. casp8 is required for blood vessel formation during embryogenesis, survival of hematopoietic progenitors, and for mitogen- or antigen-induced T- and B-cell proliferation.3,,,,–8 casp8 cleavage of the receptor interacting protein kinases (RIPKs) RIPK1 and RIPK3 results in their inhibition and in the suppression of necroptosis, a programmed necrotic cell death.9,–11 We and others have reported that mice lacking casp8 in the B-cell lineage (CD19Cre;casp8fl/fl mice; referred to herein as bcasp8−/− mice) display normal B-cell development and no abnormalities at a young age.7,8 casp8−/− B cells are resistant to Fas killing and also display impaired activation in response to stimulation of TLR2, TLR3, and TLR4.7,8
Homozygous mutations of CASP8 have been reported in 2 immunodeficient patients who also exhibited some features of the autoimmune lymphoproliferative syndrome.4 Immunodeficiency was also observed in mice lacking casp8 in the T- or B-cell lineages.5,7,8 Evidence also exists to support a possible role for CASP8 in human cancer. Loss of CASP8 expression because of hypermethylation of its promoter has been associated with human neuroblastomas with N-MYC amplification,12 small-cell lung carcinoma,13 and relapsed glioblastoma multiforme.14 Inactivation of the CASP8 gene by somatic mutations was also reported for human hepatocellular carcinomas and advanced gastric cancer.15 In addition, loss of CASP8 has been associated with neuroblastoma metastasis.16 Despite these data, compelling evidence is lacking to support a direct causal role for CASP8 inactivation in cancer development.
In the present study, we report that deficiency of casp8 in B cells and mouse embryonic fibroblasts (MEFs) results in impaired cytokinesis. Mice lacking casp8 in the B-cell lineage developed lymphomas with elevated chromosomal instability. Additional loss of p53 in the B cells of these mice further increased their cancer risk. Our data support casp8 as a tumor suppressor important for lymphomagenesis.
Methods
Mice
casp8fl/fl mice,5 p53fl/fl mice17 (obtained from the National Cancer Institute Mouse Repository), Mx1-cre mice,18 and CD19Cre mice19 were used to obtain bcasp8−/−, bcasp8−/−p53−/−, CD19Cre;p53fl/fl, and wild-type (WT) mice. All mice studied were in a mixed 129/J;C57BL/6;FVB genetic background and were genotyped by PCR (primer sequences and PCR conditions are available on request). All experiments were performed in compliance within the Ontario Cancer Institute animal care committee guidelines.
Flow cytometric analysis
Single-cell suspensions prepared from spleen and lymph nodes (LNs) were stained with the following Abs: anti-Thy.1, anti-B220, anti-CD43, anti-IgM, and anti-CD138. Stained cells were analyzed by flow cytometry (FACSCalibur; BD Biosciences) using CellQuest Version 5.3.2 software (Applied Biosystems). Cell death was examined using propidium iodide staining and FACS analysis. Dilution profiles of CFSE (Invitrogen) were examined by FACS to assess B-cell proliferation. Purified B cells were labeled with CFSE and cultured with lipopolysaccharides (LPS; 10 μg/mL; Sigma-Aldrich) for 48 hours in the presence or absence of necrostatin-1 (10μM; Calbiochem).
Western blot analysis
Western blot analysis was performed according to standard protocols. The following Abs were used: p53 (FL393; Santa Cruz Biotechnology), p21 (Santa Cruz Biotechnology), Puma (Cell Signaling Technology), and HRP-Actin (Santa Cruz Biotechnology).
Immunofluorescence
E1A-HRasV12–transformed and 3T3 MEFs were seeded onto coverslips in 24-well tissue-culture dishes; 18 hours later, cells were washed in PBS and fixed in 100% methanol for 10 minutes, and then blocked with 3% goat serum in PBS. Anti–γ-tubulin and anti–α-tubulin (Sigma-Aldrich) were used at a 1:1000 dilution and incubated with cells for 1 hour at room temperature. Labeling was revealed using anti–mouse Ab conjugated to FITC or PE (Molecular Probes). Cells were stained with 4′,6-diamidino-2-phenylindole (DAPI) for 5 minutes, and then mounted with Mowiol 4-88 (Calbiochem). The slides were observed under a Leica DMIRB fluorescence microscope equipped with digital camera (Leica DC 300RF). Images were acquired using Leica Image Manager Version 4.0.0 software. The confocal microscope (Zeiss) was also used with a 63× oil-immersion objective with a numerical aperture of 1.32. Untreated or 36-hour post-IgM activation B cells from bcasp8−/− and WT mice, either untreated or stimulated for 36 hours with anti-IgM, were seeded onto coverslips in 24-well tissue-culture dishes and fixed as described earlier.
ELISA
Serum levels of Ig and antinuclear Abs were determined using 5 pairs of 10- to 12-month-old bcap8−/− mice and WT littermates using mouse immunoglobulin isotype panel kits (Southern Biotechnology Associates) as described previously.20 IL-6 serum levels were examined by ELISA (Fisher Scientific).
SKY analysis
Spectral karyotyping (SKY) was performed on metaphases according to the manufacturer's instructions (Applied Spectral Imaging) and as described previously.21 A minimum of 10 metaphases were analyzed per sample. Metaphases not analyzed by SKY were stained with Giemsa according to the standard procedure. A minimal of 20 metaphases were analyzed per sample using HiSKY analysis software (Applied Spectral Imaging). Chromosomal abnormalities were scored as recommended by the International Standing Committee on Human Cytogenetic Nomenclature in 2009,22 and following the recommendations by Savage et al.23
Histology
Paraffin sections of tumors and normal tissues were stained with H&E for histological analysis as described previously.24 Images were captured with a 10× or 20× HCX lens on a Leica DM4000B microscope (Germany) equipped with a digital camera (Leica DC 300RF). Magnifications used were 10×/0.3, 20×/0.5, and 100×/1.30 at room temperature using Mowiol. Images were acquired using Leica Image Manager Version 4.0.0 Software. All digital images were imported into Photoshop CS4 (Adobe) and adjusted for gain, contrast, and γ settings.
Results
casp8 deficiency promotes B-cell lymphomagenesis
bcasp8−/− mice, which lack casp8 in the B-cell lineage, display no developmental defects and remain tumor free at young ages.7,8 However, in the present study, we monitored cohorts of bcasp8−/− mice and their WT littermates for a period of 60 weeks and observed a shorter lifespan for bcasp8−/− mice (Figure 1A). Kaplan-Meier survival curves indicated that at the end of the observation period, 100% of WT mice (n = 12) were alive, compared with only 18 of 31 (58%) of bcasp8−/− mice (P = .01 by log-rank test). Sick bcasp8−/− mice displayed massive splenomegaly and lymphadenopathy, particularly of the mesenteric LNs (Figure 1B). Examination of H&E-stained sections of spleens and LNs of these mice indicated that 42% of mutant mice developed tumors by 1 year of age (Figure 1C-D and G-H).
The histology of these tumors showed similarities to human multiple myeloma, because the predominant observed cellular phenotype was mature plasma cells (Figure 1F), These tumors were found to be highly invasive and infiltrated multiple tissues and organs, including muscle adipose tissues, liver, bones, colon, and lungs (Figure 1E-H and supplemental Figure 1A-D, available on the Blood Web site; see the Supplemental Materials link at the top of the online article). However, we observed no osteolytic patterns that are characteristic of multiple myeloma (supplemental Figure 1E-F). Therefore, we characterized the tumors as “plasma-cell neoplasms.”
Cytofluorometric analysis of these tumors indicated that they were negative for B220 and for CD138, a marker for plasma B cells (supplemental Figure 1G-H). We next examined the serum level of IL-6, a cytokine important for the differentiation and survival of plasma cells and involved in the development of plasma-cell neoplasms.25,26 ELISA analysis indicated elevated IL-6 serum level in 10- to 12-month-old tumor-bearing bcasp8−/− mice (n = 5) compared with their WT (n = 5) littermates (167.1 vs 35.7 pg/mL, P = .015; supplemental Figure 2A). Because plasma-cell neoplasms can be classified based on their ability to secrete Ig,26,27 we also performed ELISA to examine the serum level of Ig in the tumor-bearing bcasp8−/− mice and their WT littermates. Bim−/− mice were used as positive controls because they develop a systemic lupus erythematosus–like syndrome and display hypergammaglobulinemia.28 The level of serum Ig isotypes in bcasp8−/− mice was found to remain similar between bcasp8−/− mice and their WT littermates (P > .05; supplemental Figure 2B-E). In addition, consistent with the cancerous nature of their disease, bcasp8−/− mice displayed no increased serum level of antinuclear autoantibodies (ANA; supplemental Figure 2F). These data demonstrate that casp8 is a tumor suppressor important for suppressing B-cell lymphomagenesis.
casp8 deficiency preferentially predisposes for B-cell lymphomagenesis
To examine tumor specificity associated with casp8 deficiency, we used the Mx1-cre transgene to delete casp8 in various tissues. Mx1-Cre mice express the transgene Cre under the control of the IFN-α/β–inducible Mx1 promoter.18 Whereas injection of the synthetic double-stranded RNA pI-pC is used to induce IFN expression to trigger Cre expression, several studies have indicated leakiness of the Mx1-Cre transgene and showed that its expression is spontaneously induced by endogenous IFN in the absence of any pI-pC injection.29,–31 We therefore killed a cohort of 16- to 18-month-old Mx1-cre;casp8fl/fl mice (n = 8) and Mx1-cre littermates (n = 5) that had not been injected previously with pI-pC. PCR analysis of genomic DNA indicated variable levels of casp8 deletion in tested tissues, including spleen, LNs, and liver (supplemental Figure 3A). Partial loss of the casp8 protein was confirmed by immunostaining of spleen sections from Mx1-cre;casp8fl/fl mice with anti-casp8 polyclonal Ab (supplemental Figure 3B-D). Whereas no tumors were observed in the Mx1-cre littermates, 7 of 8 (87.5%) Mx1-cre;casp8fl/fl mice examined showed the presence of highly invasive lymphomas of B-cell origin, similar to bcasp8−/− mice (supplemental Figure 4). Therefore, whereas casp8 was deleted in several tissues in Mx1-cre;casp8fl/fl mice, only B-cell lymphomas were observed in these mice, suggesting that casp8 deficiency preferentially predisposes for B-cell malignancy.
Cooperation of casp8 and p53 in tumor suppression
p53 is critical for several cellular processes, including apoptosis, and is the most frequently inactivated tumor suppressor in human cancer.32,33 To examine whether functional interactions exist between p53 and casp8, we crossed bcasp8−/− mice to p53fl/fl mice17 and generated CD19Cre;casp8fl/fl;p53fl/fl (bcasp8−/−p53−/−) mice. Double mutant mice were viable and at 6-10 weeks of age, were healthy and displayed no difference in the number or distribution of their B cells or other immune cells compared with single mutant and WT littermates (supplemental Figure 5A-B).
The effects of p53 inactivation on tumorigenesis of bcasp8−/− mice was examined by monitoring cohorts of CD19Cre;p53fl/fl mice (n = 10) and bcasp8−/−p53−/− mice (n = 30) for a period of 60 weeks. Two of 10 monitored CD19Cre;p53fl/fl mice developed B-cell lymphomas with late latency and died at the age of 54 and 57 weeks, respectively (Figure 2A). In contrast, bcasp8−/−p53−/− mice had a significantly shorter life span and higher frequency of tumors compared with bcasp8−/− mice (P = .04 by log-rank test) and CD19Cre;p53fl/fl mice (P = .015 by log-rank test).
Examination of H&E–stained sections of spleen, LNs, lungs, liver, and kidneys from moribund bcasp8−/−p53−/− mice indicated that these mutants developed plasma-cell neoplasms that were morphologically similar to those observed in bcasp8−/− mice. In addition, similar to bcasp8−/− tumors, bcasp8−/−p53−/− tumors were also negative for CD138. However, in contrast to bcasp8−/− tumors, which were negative for B220, bcasp8−/−p53−/− lymphomas expressed a low level of B220 (supplemental Figure 5C-D). The LNs of tumor-bearing bcasp8−/−p53−/− mice were enlarged by the presence of proliferating tumor cells, with clear invasion of surrounding adipose tissues (Figure 2B) and alteration of the normal nodal architecture (Figure 2C). Tumor infiltration was also evident in hepatic sinusoids and periportal spaces (Figure 2D). At high magnification, tumors were composed of plasma cells at various stages of differentiation (Figure 2E) and displayed elevated numbers of mitotic figures (Figure 2E-G). Examination of the mitotic index of bcasp8−/−p53−/− tumors indicated that it was significantly higher compared with bcasp8−/− tumors (P = .007), and that both tumors were highly proliferating compared with WT and p53−/− B cells (Figure 2H). We conclude that the loss of p53 facilitates B-cell lymphomagenesis associated with casp8 deficiency.
Impaired cytokinesis in the absence of casp8
Failure of cytokinesis is frequently associated with human cancer and has been reported to result from various defects, including anaphase bridges and multipolar and abnormal mitosis.34,,–37 Interestingly, H&E–stained tumor sections from bcasp8−/− mice and bcasp8−/−p53−/− mice displayed mitotic cells with anaphase bridges (Figure 2I-J) and multipolar or abnormal mitosis (Figure 2K-L and supplemental Figure 6A). Multinucleated cells, a common result of cytokinesis failure, were also observed in blood smears of tumor-bearing bcasp8−/− mice (Figure 2M) and in touch smears of kidneys infiltrated with bcasp8−/− tumors (Figure 2N). Therefore, we conclude that tumors deficient for casp8 display cytokinesis defects.
To determine whether cytokinesis defects observed in casp8 mutants preceded tumor development, we have examined H&E–stained spleen sections of tumor-free WT and bcasp8−/− mice for features of cytokinesis failure. Whereas no abnormalities of cytokinesis were observed in the spleens of WT mice, anaphase bridges and multipolar metaphases were readily observed in the spleens of tumor-free bcasp8−/− mice (supplemental Figure 6B-F). These data suggest that cytokinesis defects associated with the absence of casp8 precede B-cell lymphomagenesis in mutant mice.
To further investigate the mechanisms that lead to B-cell malignancy in the absence of casp8, we examined levels of B-cell proliferation and death in healthy bcasp8−/− mice and their WT littermates. Whereas we observed no defect in the proliferation of B cells from bcasp8−/− mice (supplemental Figure 7A), higher level of death was observed in bcasp8−/− B cells compared with WT controls both under untreated conditions and after IgM activation (supplemental Figure 7B-D).
Centrosomes are critical for microtubule organization and function and for chromosome segregation and cytokinesis.34 We therefore examined centrosome numbers in WT and casp8−/− B cells. Because the loss of casp8 has been shown previously to increase the transformation rate of SV40 T-antigen–immortalized casp8−/− MEFs at their late passages,38 we also examined centrosome numbers in E1A-HRasV12–transformed and 3T3-immortalized WT and casp8−/− MEFs. In contrast to WT controls, which predominantly displayed a single centrosome, an increased frequency of multiple centrosomes was observed in casp8−/− B cells and MEFs (Figure 3A-C and supplemental Figure 8A-E and I). Whereas we observed no WT B cells with more than 2 centrosomes, nearly 20% of the examined casp8−/− B cells displayed 3 or more centrosomes (Figure 3B). The number of MEFs with 3 or more centrosomes was also highly increased in the absence of casp8 (supplemental Figure 8I).
Excess of functional centrosomes can lead to aberrant formation of multipolar spindles.34 Consistent with the supernumerary centrosomes of casp8−/− B cells and MEFs, these cells displayed multipolar mitotic spindles (Figure 3C and supplemental Figure 8C-E) and binucleate cells (Figure 3D-E and supplemental Figure 8F). In addition, micronuclei, which can result from abnormal mitosis and cytokinesis,39 were present at a significantly higher frequency in casp8−/− B cells and MEFs compared with WT controls (Figure 3F-G and supplemental Figure 8G,J).
The final step of cytokinesis, “abscission,” consists of cleavage of the cytoplasmic bridge containing the midbody that connects the 2 daughter cells.34,36 Because elongated intercellular bridges are characteristic of defective cytokinesis, we examined their presence in casp8−/− B cells, casp8−/− MEFs, and WT controls after immunofluorescence staining with Abs for α-tubulin. The frequency of intercellular bridges was significantly increased in both casp8−/− B cells and casp8−/− MEFs compared with WT controls (Figure 3H-I and supplemental Figure 8H-K). These data indicate increased frequency of cytokinesis failure in the absence of casp8.
Aneuploidy and elevated structural chromosomal aberrations in tumors deficient in casp8
Aneuploidy and structural chromosomal aberrations are hallmarks of human cancers.34,40 Aneuploidy is frequently associated with impaired mitotic checkpoint signaling, sister chromatid cohesion, and multipolar mitotic spindles, and can also result from chromosomal instability.34 Conversely, chromosomal instability has been shown to result from defects in several cellular processes, including the presence of extra centrosomes.34,35,41 Because supernumerary centrosomes and cytokinesis defects were observed in casp8−/− cells, we used SKY analysis to examine the level of chromosomal instability in bcasp8−/− and bcasp8−/−p53−/− primary tumors. Complex karyotypes with elevated frequencies of numerical and structural chromosomal abnormalities were observed in bcasp8−/− tumors (Figure 4A-B and Table 1). All metaphases from bcasp8−/− tumors were aneuploid and had an overall near-tetraploid pattern. The modal chromosomal number of these tumors varied from 67 (hypertriploid) to 84 (hypertetraploid). Furthermore, a high proportion of the chromosomes of bcasp8−/− tumors displayed structural abnormalities. One fourth of these chromosomes showed centromeric abnormalities (eg, acentric, multicentric, and double-minute chromosomes). Intrachromosomal rearrangements were also observed in bcasp8−/− tumors, because 12% of their chromosomes displayed either duplication or deletion, and 1-3 ring chromosomes were detected in 4 of the 10 metaphases analyzed. Abnormal chromosomes derived from complex translocation patterns involving 2-3 different chromosomal origins were also frequently observed in bcasp8−/− tumors, with an average number of 70 abnormally fused chromosomal segments per metaphase. Triradial chromosomes (1-2) were also observed in 50% of the bcasp8−/− tumor metaphases examined. Only a minority of chromosomes in bcasp8−/− tumors appeared normal by SKY and inverted DAPI analysis.
Elevated level of chromosomal instability was also observed in bcasp8−/−p53−/− tumors, with their chromosome content near-diploid to near-triploid (Figure 4C and supplemental Table 1). Structural rearrangements were limited to the presence of 2-3 abnormally fused chromosomal segments per metaphase, and most of them were clonal. Double-minute chromosomes were also observed (Figure 4D). In contrast to bcasp8−/− tumors, no dicentric, multicentric, triradial, or ring chromosomes were detected in bcasp8−/−p53−/− tumors. These data indicate increased chromosomal instability in lymphomas deficient for casp8.
Responses of casp8-deficient lymphomas to radiation and LPS treatment
Because it is important for cancer therapy, we examined the response of casp8-deficient tumors to irradiation (IR). bcasp8−/− and bcasp8−/−p53−/− B-cell lymphomas were irradiated (6 Gy) and their survival level examined 24 hours after IR. As expected based on the important role that p53 plays in the DNA-damage response, B-cell lymphomas from bcasp8−/−p53−/− mice were highly radioresistant (Figure 5A). However, whereas some bcasp8−/− B-cell lymphomas were highly radiosensitive, others displayed elevated radioresistance (Figure 5A). p53 is frequently inactivated in tumors through various mechanisms, and this inactivation leads to radioresistance. Therefore, we examined whether differences in p53 responses could contribute to the differential IR sensitivity observed with bcasp8−/− B-cell lymphomas. These tumors and WT splenocytes were left untreated or were irradiated (6 Gy) and their level of p53 examined 4 hours later. DNA damage induces activation of p53 that transactivates several target genes.42 Therefore, we also examined the expression level of p21 and Puma, 2 downstream targets of p53 involved in cell-cycle control and apoptosis, respectively. Western blot analysis showed that whereas radiosensitive bcasp8−/− B-cell lymphomas displayed IR-induced expression of p53, p21, and Puma, radioresistant lymphomas failed to increase the expression of p53 or its targets, p21 and Puma, suggesting that loss of p53 activation in these tumors is the cause of their radioresistance (Figure 5B).
casp8−/− B cells display impaired TLR signaling.7,8 Whereas LPS stimulation of TLR4 induced proliferation of WT B cells, it also promoted the killing of casp8−/− B cells. In addition to promoting apoptosis, casp8 has also been shown to inhibit necroptosis.9,–11 This type of cell death takes place in the absence of casp8, and recent studies have demonstrated that genetic deletion of the necroptotic kinase RIPK3 fully rescues embryonic lethality of casp8−/− mice and restores their impaired T-cell homeostasis.43,44 However, whereas necrostatin-1 (Nec1), a specific inhibitor of RIPK1 and necroptosis, was able to fully rescue the survival and proliferation of casp8−/− T cells,45 it failed to rescue survival or proliferation of LPS-stimulated casp8−/− B cells (supplemental Figure 9). Therefore, TLR4 stimulation results in the killing of casp8−/− B cells in a necroptosis-independent manner.
We next examined whether LPS-induced killing of B cells in the absence of casp8 can be exploited to kill bcasp8−/− and bcasp8−/−p53−/− B-cell lymphomas. These tumors, as well as B cells from healthy WT mice and p53−/− littermates, were stimulated ex vivo with LPS for 24 hours and their survival levels determined using the annexin V/propidium iodide assay. Similar to casp8−/− B cells,7 the survival of bcasp8−/− and bcasp8−/−p53−/− B-cell lymphomas was significantly reduced in the presence of LPS (Figure 5C). Therefore, we conclude that whereas a subset of casp8−/− lymphomas is radiosensitive, other tumors display impaired p53 activation and are radioresistant. In contrast, all casp8-deficient B-cell lymphomas display increased death sensitivity to LPS in a p53-independent manner.
Discussion
Whereas decreased expression of CASP8 or its somatic mutations have been reported in human cancer,12,,–15 and loss of casp8 has been shown to facilitate cellular transformation in vitro,38 there is currently no clear evidence to support the idea that in vivo deregulation of CASP8 may promote the initiation of cancer. Using 3 different mouse models, we demonstrate in the present study that the loss of casp8 in B cells is sufficient to lead to B-cell lymphomagenesis. Our data also indicate that p53 deficiency further exacerbates B-cell lymphomagenesis associated with casp8 deficiency. Consistent with the proposed function for CASP8 as a suppressor of metastasis,16 lymphomas developed in bcasp8−/−, Mx1-cre;casp8fl/fl, and bcasp8−/−p53−/− mice were highly invasive.
In contrast to mice lacking casp8 in the B-cell lineage, no spontaneous tumorigenesis was observed in mice with the casp8 mutation specifically targeted to the T-cell lineage24 or mammary epithelial cells (A.H., unpublished data, December 2009). In addition, whereas Mx1-cre;casp8fl/fl displayed deletion of casp8 in various tissues and cell types, these mice only developed B-cell lymphomas. Whereas the mechanisms for this tumor type specificity associated with casp8 deficiency remain unclear, increased necroptosis reported for casp8 deficiency in certain cell types might contribute to these differences in cancer predisposition. For example, impaired proliferation of casp8−/− T cells is rescued by the necroptosis inhibitor Nec1,45 and defective T-cell homeostasis associated with casp8 mutation is rescued in the Ripk3-null background.43,44 In contrast, our data indicate that loss of casp8 in B cells does not lead to their death by necroptosis. Therefore, it remains possible that necroptosis associated with casp8 deficiency in certain cell types and tissues might suppress their tumorigenic risks.
In the present study, we report that the loss of casp8 in B cells and MEFs is accompanied by increased frequency of cytokinesis defects. We also report elevated chromosomal instability in casp8−/− lymphomas. Because cytokinesis failure and chromosomal instability play important roles in cancer development,34,35,46 we propose that they contribute to the B-cell lymphomagenesis associated with casp8 deficiency. However, because of the existence of a close reciprocal relationship between cytokinesis failure and chromosomal instability,34 the specific contribution of each of these defects to the malignancy of bcasp8−/− mice requires further investigation. Nevertheless, whereas we observed no chromosomal instability in B cells from young, tumor-free bcasp8−/− mice, these B cells displayed increased frequency of cytokinesis defects. Therefore, the impaired cytokinesis associated with casp8 deficiency in B cells might precede chromosomal instability and the malignant transformation of these cells.
The numerical and structural chromosomal abnormalities observed in bcasp8−/−p53−/− lymphomas were clonal and less complex compared with those observed with bcasp8−/− lymphomas. The mechanisms for these differences are currently unknown; however, we speculate that the different status of p53 and the different stages of these lymphomas are likely to contribute to their different pattern of chromosomal abnormalities.
Our data indicate that a deficiency of p53 promotes the development of casp8−/− B-cell lymphomas, and that approximately half of examined bcas8−/− tumors are radioresistant and display impaired activation of p53. Therefore, it is possible that the DNA-damage response, including p53 activation, promotes the elimination of aberrant casp8−/− B cells carrying genomic instability and leads to the suppression of cancer risks associated with this mutation.
In conclusion, our data demonstrate that casp8 functions as a tumor suppressor. This novel function of casp8, together with the previously reported immunodeficiency and developmental defects associated with its deficiency, all highlight the importance of this caspase in diseases such as cancer.
The online version of this article contains a data supplement.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734.
Acknowledgments
The authors thank M. Woo, V. Stambolic, L. Pelletier, L. Salmena, and J. Li for helpful discussions and Dr Klaus Rajewsky for providing us with the Mx1-cre mouse line.
This work was supported by the Leukemia & Lymphoma Society of Canada (to R.H.), the Canadian Institute of Health Research (to R.H.), and the Canadian Cancer Society (to J.S.).
Authorship
Contribution: A.H., S.E.G., G.M., B.L., J.K., and A.J. conducted the experiments and performed the data analyses; O.S., J.S., and R.H. performed the data analyses; and A.H. and R.H. designed the experiments and wrote the manuscript.
Conflict-of-interest disclosure: The authors declare no competing financial interests.
Correspondence: Razq Hakem, PhD, Professor, Department of Medical Biophysics and Department of Immunology, University of Toronto University Health Network, Ontario Cancer Institute, 610 University Avenue, Room 10-622, Toronto, ON, M5G 2M9 Canada; e-mail: rhakem@uhnres.utoronto.ca; or Anne Hakem, PhD, University Health Network, Ontario Cancer Institute, 610 University Ave, Room 10-622, Toronto, ON, M5G 2M9 Canada; e-mail: ahakem@uhnres.utoronto.ca.