Your search keyword '"Christopher Corless"' showing total 5 results

1. Apoptosis-stimulating protein of p53 (ASPP2) heterozygous mice are tumor-prone and have attenuated cellular damage–response thresholds

Author

Kerstin M. Kampa, Jared D. Acoba, Dexi Chen, Joel Gay, Hunjoo Lee, Kelly Beemer, Emerson Padiernos, Nataya Boonmark, Zhiyi Zhu, Alice C. Fan, Alexis S. Bailey, William H. Fleming, Christopher Corless, Dean W. Felsher, Louie Naumovski, and Charles D. Lopez

Subjects

Heterozygote, T cell, Apoptosis, Thymus Gland, Biology, medicine.disease_cause, Lymphoma, T-Cell, law.invention, Mice, law, Neoplasms, medicine, Animals, Genetic Predisposition to Disease, Multidisciplinary, Tumor Suppressor Proteins, Cell Cycle, Heterozygote advantage, Cell cycle, Biological Sciences, Molecular biology, Embryonic stem cell, Mice, Mutant Strains, medicine.anatomical_structure, Gamma Rays, Suppressor, Carcinogenesis, Apoptosis Regulatory Proteins, G1 phase

Abstract

The expression of ASPP2 (53BP2L), a proapoptotic member of a family of p53-binding proteins, is frequently suppressed in many human cancers. Accumulating evidence suggests that ASPP2 inhibits tumor growth; however, the mechanisms by which ASPP2 suppresses tumor formation remain to be clarified. To study this, we targeted the ASPP2 allele in a mouse by replacing exons 10–17 with a neoR gene. ASPP2 −/− mice were not viable because of an early embryonic lethal event. Although ASPP2 +/− mice appeared developmentally normal, they displayed an increased incidence of a variety of spontaneous tumors as they aged. Moreover, γ-irradiated 6-week-old ASPP2 +/− mice developed an increased incidence of high-grade T cell lymphomas of thymic origin compared with ASPP2 +/+ mice. Primary thymocytes derived from ASPP2 +/− mice exhibited an attenuated apoptotic response to γ-irradiation compared with ASPP2 +/+ thymocytes. Additionally, ASPP2 +/− primary mouse embryonic fibroblasts demonstrated a defective G 0 /G 1 cell cycle checkpoint after γ-irradiation. Our results demonstrate that ASPP2 is a haploinsufficient tumor suppressor and, importantly, open new avenues for investigation into the mechanisms by which disruption of ASPP2 pathways could play a role in tumorigenesis and response to therapy.

Published

2009

2. Abstract B184: HSP90 inhibitor STA-9090 potently suppresses heterogeneous KIT kinase-domain mutations responsible for gastrointestinal stromal tumor progression during imatinib therapy

Author

Michael Heinrich, Jennifer G. Morgan, Bernadette Liegl, Tanya A. Rege, Wen-Bin Ou, George D. Demetri, Christopher D.M. Fletcher, Jonathan A. Fletcher, Christopher Corless, Kevin Foley, Rachel Donsky, Chandrajit P. Raut, Yuexiang Wang, Stephen Swank, and Maria Debiec-Rychter

Subjects

Cancer Research, Mutation, GiST, Sunitinib, Imatinib, PDGFRA, Cell cycle, Biology, medicine.disease_cause, digestive system diseases, Hsp90 inhibitor, Oncology, Immunology, medicine, Cancer research, Tyrosine kinase, medicine.drug

Abstract

Background: Most GISTs express mutant KIT or PDGFRA oncoproteins, which are targets of tyrosine kinase inhibitors (TKIs), such as front-line imatinib (IM) or second-line sunitinib (SU). GIST clinical resistance to IM or SU is commonly associated with the acquisition of heterogeneous secondary mutations in the KIT/PDGFRA ATP-binding pocket (ABP) or activation loop (AL), which maintain the constitutively activated state of these kinases. We therefore asked whether the heterogeneous IM-resistant KIT oncoproteins in GIST are uniformly HSP90 clients, and whether they can be inhibited by STA-9090, a synthetic small molecule HSP90 inhibitor that is structurally unrelated to the first-generation natural product-derived ansamycin HSP90 inhibitor 17-AAG. Methods: KIT and PDGFRA were genotyped in up to 15 metastases from each of 10 patients whose metastatic GIST had progressed after IM therapy. Kinase mutants were biochemically profiled for IM and STA-9090 sensitivity in: 1. Ba/F3 cells transformed by mutant KIT constructs; 2. GIST cell lines (IM-sensitive and IM-resistant); and 3. a novel assay measuring inhibition of kinase phosphorylation after drug treatment in GIST48B (KIT-negative) GIST cells transfected with mutant KIT constructs. Drug effects on proliferation, apoptosis and cell cycle were evaluated in five GIST cell lines, including a KIT-dependent GIST subline (GIST882B) that is resistant to 17-AAG. Results: As many as 8 different secondary KIT IM-resistance mutations (both ABP and AL) were detected in individual patients whose GISTs progressed after IM therapy. All mutations were sensitive to STA-9090. STA-9090 was 5-15 fold more potent than 17-AAG against these IM-resistant KIT secondary mutations, and was at least as effective against the primary + secondary (IM-resistant) mutations in combination, as compared to the primary IM-sensitive mutation alone (Table). STA-9090 also potently inhibited the 17-AAG resistant GIST882B cell line. Conclusions: STA-9090 was more potent than 17-AAG against a panel of KIT mutations found in TKI-resistant GISTs. STA-9090 potency was undiminished against combination activating KIT mutations (including secondary kinase-domain resistance mutations), as typically occur in IM-resistant GIST clones. Based on these results, we hypothesize that STA-9090 might have broad clinical activity against IM-resistant GIST. Table: IC50 (nM) for GIST viability: HSP90-inhibition vs. imatinib GIST Line STA-9090 17-AAG Imatinib GIST882: KIT Ex 13 40 200 300 GIST882B 35 >1000 300 GIST430: KIT Ex 11 + V654A (ABP) 20 300 >1000 Citation Information: Mol Cancer Ther 2009;8(12 Suppl):B184.

Published

2009

3. Apoptosis Stimulating Protein of p53 (ASPP2) Heterozygous Mice Are Lymphoma-Prone and Display Attenuated Apoptosis and Cell Cycle Checkpoints

Author

Charles Lopez, Christopher Corless, Lothar Kanz, Marcus M Schittenhelm, Emerson Padiernos, Zhyi Zhu, Joel Gay, Kelly Beemer, Hun-Joo Lee, Dexi Chen, Jared Acoba, and Kerstin Maria Kampa

Subjects

Cell cycle checkpoint, medicine.diagnostic_test, Immunology, Cell Biology, Hematology, Biology, medicine.disease_cause, Biochemistry, Molecular biology, Flow cytometry, Apoptosis, In vivo, Phosphoprotein, Gene expression, medicine, Carcinogenesis, Ex vivo

Abstract

Introduction: p53 is an important tumor suppressor, and loss of p53 pathway function is a common event in human cancer. ASPP2 is a damage-inducible p53 binding protein that enhances apoptosis, at least in part, by selective stimulation of p53 pro-apoptotic target genes. Low ASPP2 expression occurs in many human tumors and as we have previously demonstrated, correlates with poor clinical outcome in patients with B-cell lymphomas. However, the mechanisms by which ASPP2 suppresses tumor formation remain unknown. Methods: To rigorously study ASPP2 in vivo function, we targeted the ASPP2 allele in a mouse model by homologous recombination by replacing exons 10–17 with a neoR gene. Aging mice were followed for spontaneous tumor formation. Additionally, six week old mice were irradiated at different doses and followed for tumor development. To explore the functional consequences of low ASPP2 expression, ASPP2+/− and ASPP2+/+ thymocytes were subjected ex vivo to 5Gy ionizing irradiation and apoptosis was assessed by Annexin-V/PI staining and flow cytometry. We also irradiated ASPP2+/+ and ASPP2+/−MEFs (mouse embryonic fibroblasts) with 5Gy and performed cell cycle analysis. Furthermore, we conducted global gene expression profiling between the unirradiated and irradiated ASPP2+/+ and ASPP2+/−MEFs using an Affymetrix GeneChip® Mouse Gene 1.0 ST Array. Moreover, phosphoproteomic analysis was performed on unirradiated and irradiated ASPP2+/+ and ASPP2+/−MEFs using 2-dimensional gel electrophoresis, fluorescent phosphoprotein dye Pro-Q Diamond staining, and liquid chromatography tandem mass spectroscopy. Results: We were unable to generate ASPP2−/− mice due to an early embryonic lethal defect. However, ASPP2+/− mice appear developmentally normal and reproduce. We observed an increased formation of spontaneous tumors in aging ASPP2+/− mice compared to ASPP2 +/+ mice (43% vs. 22%, at 115 weeks, p=0.011). Additionally we were able to show that after ionizing radiation, ASPP2+/− mice develop high-grade lymphomas in a dose-dependent manner at a significantly higher incidence at 50 weeks compared to ASPP2+/+ mice (p = 0.024 and p = 0.045, 6 Gy and 10.5 Gy respectively). Immunophenotyping demonstrated that these were high-grade T-cell lymphomas of thymic origin. Since ASPP2 is damage-inducible and promotes apoptosis, we wished to determine the extent to which reduction in ASPP2 expression attenuated the cellular damage response. We therefore gamma-irradiated ex vivo ASPP2+/+ and ASPP2+/−thymocytes in short-term culture and found a two-fold reduction in apoptosis in ASPP2+/− thymocytes compared to ASPP2+/+ thymocytes. Additionally, after 5 Gy gamma-irradiation, ASPP2+/− MEFs exhibited an attenuated G0/G1 checkpoint compared to ASPP2+/+ MEFs. Preliminary analysis of global gene expression in ASPP2+/+ and ASPP2+/− MEFs shows specific differences in gene expression patterns after damage. Likewise, preliminary analysis of phosphoproteomics between ASPP2+/+ and ASPP2+/− MEFs after damage, demonstrate differences in the phosphophorylation status of 170 proteins. Conclusions: ASPP2 is a haploinsufficient tumor suppressor, and reduction in ASPP2 expression attenuates both cell cycle checkpoints and apoptosis-induction after damage. These results suggest that reduction of ASPP2 levels modulate the cellular damage response, possibly at transcriptional as well as post-transcriptional levels, and provide a functional explanation for the increased tumor incidence in ASPP2+/− mice---since attenuated damage-response thresholds would lead to an impaired ability to eliminate cells that have accumulated tumorigenic mutations. Our study provides important insights into the p53-ASPP2 axis, and opens new avenues for investigation into its role in tumorigenesis and response to therapy.

Published

2008

4. Apoptosis Stimulating Protein of p53 (ASPP2) Haploinsufficiency Promotes Irradiation-Induced High Grade Lymphomas in a Mouse Model

Author

Kerstin M. Kampa, Jared D. Akoba, Dexi Chen, Kelly Beemer, Joel Gay, Zhiyi Zhu, Emerson Padiernos, Christopher Corless, Alexis Baily, William H. Flemming, and Charles D. Lopez

Subjects

Pathology, medicine.medical_specialty, Myeloid, Immunology, Cell Biology, Hematology, Biology, medicine.disease, Biochemistry, Lymphoma, medicine.anatomical_structure, Immunophenotyping, Apoptosis, medicine, Cancer research, Bone marrow, CD5, Diffuse large B-cell lymphoma, CD8

Abstract

Apoptosis Stimulating Protein of p53 (ASPP2) binds the tumor suppressor protein p53 and promotes damage-induced apoptosis in part through stimulation of p53 apoptotic function. We have previously demonstrated that low ASPP2 levels correlate with poor clinical outcome in patients with diffuse large B-cell lymphoma treated with anthracycline-based chemotherapy, which is consistent with its role as a tumor suppressor. We targeted the ASPP2 allele in a mouse model by homologous recombination using a knockout vector that replaced exons 10–17 with a neoR gene. Although ASPP2−/− is an early embryonic lethal event, ASPP2+/– mice appeared developmentally normal and reproduce. Importantly, ASPP2+/– mice developed tumors spontaneously at a higher frequency than sibling ASPP2+/+ controls. We now show that after ionizing irradiation, ASPP2+/– mice develop high grade lymphatic malignancies compared to ASPP2+/+ mice. ASPP2+/+ and +/– mice were irradiated, with either 6 Gy or 10,5 Gy, 8 weeks after birth. Following irradiation, mice were monitored weekly by blood smears and flow cytometry if suspicious cells were observed. Tumor formation was detected as early as 17 weeks post-irradiation. In the 10,5 Gy group, ASPP2+/– mice developed thymic lymphomas (7/31), while no tumors were detected in ASPP2+/+ mice (0/14). Tumor-free survival was statistically significant (p= 0,045, log-rank test). In the 6 Gy dose group 9 out of 28 of the ASPP2+/– mice developed high-grade thymic lymphomas compared to 0/20 ASPP2+/+ mice. Tumor-free survival was statistically significant (p=0,024, log-rank test). Immunophenotyping and flow cytometry on mice with circulating tumor cells from whole unfractionated gated viable bone marrow (Bm) cells revealed that the Bm was typically almost completely replaced by CD4neg, CD5+, CD8+ leukemic/lymphoma cells that are negative for B-cell (B220) and myeloid markers (Mac-1/Gr-1). Preliminary analysis demonstrated that MEFs (mouse embryonic fibroblasts) from ASPP2+/– mice treated with doxorubicin, serum starvation or irradiation had an attenuated G1/G0 checkpoint arrest. Ongoing experiments are being conducted in thymocytes prepared from mice of different ASPP2 and p53 genotypes. Our data demonstrates that ASPP2 plays an important role in suppressing the development of lymphomas after irradiation in a mouse model. Consequently, disruption of the p53-ASPP2 axis may be important in lymphomagenesis and response to therapy. Furthermore, our data provides a rationale for the future study of ASPP2 expression in patients during the formation of secondary hematologic malignancies after therapies with DNA damaging agents.

Published

2007

5. ASPP2 Haploinsufficiency Promotes Tumor Formation in a Mouse Model

Author

Charles D. Lopez, Louie Naumovski, Christopher Corless, Dean Felsher, Alice Fan, Emerson Padiernos, Zhiyi Zhu, Joel Gay, Kelly Beemer, Dexi Chen, Jared D. Acoba, and Kerstin M. Kampa

Subjects

Pathology, medicine.medical_specialty, Cell cycle checkpoint, Immunology, Cell Biology, Hematology, Biology, medicine.disease, Biochemistry, Molecular biology, Lymphoma, Leukemia, Apoptosis, In vivo, medicine, Doxorubicin, Sarcoma, Diffuse large B-cell lymphoma, medicine.drug

Abstract

ASPP2 interacts with the tumor suppressor protein p53 and promotes damage-induced apoptosis in part through stimulation of p53-mediated apoptosis. We have previously demonstrated that low ASPP2 levels correlate with poor clinical outcome in patients with diffuse large B-cell lymphoma treated with anthracycline-based chemotherapy. Moreover, reduced ASPP2 expression has been demonstrated in other tumor types. These findings led us to hypothesize that ASPP2 may function as a tumor suppressor. To further explore this, we targeted the ASPP2 allele in a mouse by homologous recombination using a knockout vector that replaced exons 10–17 with a neoR gene. Two separate ES clones were used for blastocyst injections to generate several chimeras that were used to generate ASPP2 heterozygous mice. ASPP2+/− mice appear developmentally normal and reproduce. However ASPP2−/− mice could not be generated. Genotype analysis as early as Ed 6.5 did not detect ASPP2−/− embryos---which implies an early embryonic lethal defect in the homozygote. ASPP2+/− (n=135) and ASPP2+/+ (n=63) sibling mice were observed for spontaneous tumor formation. Overall median tumor-free survival was 117 weeks in the ASPP2+/− mice verses 125 weeks in the ASPP2+/+mice (p = 0.035 log-rank test). Overall tumor incidence (at 115 weeks) for ASPP2+/− and ASPP2+/+ mice was 43% and 22%, respectively. The incidence of tumor types, from all tumors detected, was similar between ASPP2+/− and ASPP2+/+ mice: 34% versus 33% (lymphoma), 18% versus 14% (sarcoma), and 47% versus 52% (carcinoma), respectively. Compound p53+/−;ASPP2+/− mice did not exhibit accelerated tumor formation relative to p53+/−;ASPP2+/+ mice. Additionally, a tet-Myc:ASPP2+/− lymphoma mouse model did not exhibit accelerated lymphomagenesis. However, preliminary data suggests that ASPP2+/− mice may have an increased incidence of irradiation-induced leukemia/lymphoma when compared to ASPP2+/+ mice, and confirmatory studies are ongoing. In response to ionizing radiation, doxorubicin, or serum-starvation, preliminary analysis reveals a G0/G1 checkpoint defect in ASPP2+/− MEFs compared to ASPP2+/+ MEFs. Our results provide in vivo evidence that ASPP2 can function as a tumor suppressor. Further studies are underway to determine the mechanism of this observation.

Published

2006