Ashwani K. Sood

Sam-Pointed Domain Containing Ets Transcription Factor in Luminal Breast Cancer Pathogenesis

We previously described frequent overexpression of Sam-pointed domain containing Ets transcription factor (SPDEF), also known as PDEF, in human breast cancer, and suggested a role for this transcription factor in breast tumor progression. To seek evidence in support of this hypothesis, the MCF-12A breast epithelial cell line was transfected with an SPDEF expression plasmid or with control vector plasmid and the transfected cells tested for their tumorigenic growth in vivo. The data showed that SPDEF expression in MCF-12A cells induced accelerated tumor growth in severe combined immune deficient mice compared with vector-transfected MCF-12A cells. Furthermore, Gene Expression Omnibus and Oncomine databases were mined to determine any correlation between SPDEF expression levels and clinical outcome. High SPDEF expression correlated with poor overall survival of patients with estrogen receptor+ breast cancer, in three independent data sets. In contrast, little correlation was observed between SPDEF expression and cancer relapse or remote metastases. SPDEF expression was further found to be restricted to tumors arising in the luminal epithelial lineage including estrogen receptor+ luminal subtype breast tumors, Her2/neu-positive tumors, and apocrine carcinomas. In contrast, little SPDEF expression was found in the basal subtype of breast tumors. Based on these results, we hypothesize that SPDEF has a function in the specification of the progenitor cells of the luminal epithelial lineage that become targets of oncogenesis in luminal breast cancer. (Cancer Epidemiol Biomarkers Prev 2009;18(6):1899–903)

Prostate-derived Ets factor is overexpressed in serous epithelial ovarian tumors.

The frequent overexpression of prostate-derived Ets factor (PDEF) mRNA in ovarian cancer has been previously reported. The aim of this study was to evaluate PDEF protein expression in ovarian cancer and how this expression might vary at different stages of epithelial ovarian tumors in comparison to normal ovary. A new rabbit polyclonal antibody to PDEF was prepared, and immunohistochemistry was performed on tissue sections from 12 normal ovaries, 10 cases of benign serous cystadenoma, 17 cases of low malignant potential tumor, 19 cases of stage 1, and 15 cases of advanced stage primary epithelial (serous) ovarian carcinomas and their peritoneal metastases. Expression levels were assessed based on the percentage of positively staining cells and the intensity of staining. All 12 normal ovary and 10 benign serous cystadenoma cases were negative for PDEF expression. In contrast, 6 of 17 (35%) low malignant potential tumors, 5 of 19 (27%) stage 1, and 5 of 15 (33%) advanced stage ovarian tumors stained positive for PDEF expression. Together, these results show frequent overexpression of PDEF protein in epithelial ovarian tumors and its lack of expression in normal ovary and cystadenomas, and this supports a role for PDEF in ovarian tumorigenesis. Furthermore, these results suggest that PDEF is a potential marker and target in ovarian cancer.

PDEF in Prostate Cancer

Prostate‐derived Ets factor (PDEF) is a relatively recently described member of the Ets family of transcription factors. It differs from other family members in its restricted and epithelial‐specific expression in normal tissues and its unique DNA‐binding motif that together may impart interesting specificity to its function. This communication reviews our current understanding of the expression characteristics of PDEF in normal prostate and in prostate cancer. Also, the biochemical and genetic evidence relating to the role of this transcription factor in prostate cancer is reviewed. Most evidence is consistent with an oncogenic role for PDEF in prostate cancer. Specific observations about the loss of PDEF expression in prostate tumors and its apparent role as a prostate tumor suppressor are also discussed. PDEF is one of the few transcription factors with potential to have a significant impact on the management of prostate cancer. A better understanding of its biology and its role in prostate cancer is urgently needed. Prostate 72:592–596, 2012.

Tumorigenicity of interleukin-2 (IL-2)-cDNA-transfected L1210 lymphoma and its in vivo variants is modulated by changes in IL-2 expression; potential therapeutic implications

SummaryTo study parameters that affect the tumorigenicity of L1210 lymphoma we have analyzed the structure of MHC class I antigens of this tumor. In addition this tumor was transfected with interleukin-2 (IL-2) cDNA in order to determine the effects of high concentrations of IL-2 within the tumor environment. The nucleotide sequence of the class I Kd, Dd and Ld mRNAs from this tumor showed that the encoded amino acid sequence of the corresponding antigens is normal, thus suggesting that the tumorigenicity of L1210 lymphoma is not due to defective antigen presentation to tumor-specific cytotoxic T cells. In contrast, induction of IL-2 expression by cDNA transfection led to loss of tumorigenicity of the IL-2-secreting tumor cells. However, a fraction of long-term-surviving mice developed progressively growing variant tumors that showed substantial decrease or loss of IL-2 expression. These results suggest that IL-2 secretion by tumors is suicidal but, because of tumor heterogeneity, IL-2-loss-variant tumors may arise that are able to escape the immune defenses of the host. The observed consistent loss of IL-2 expression in variant tumors implies that specific targeting of large quantities of IL-2 to tumor cells may be a valuable approach to immunotherapy of cancer. In addition we find that under specific gamma ray irradiation IL-2-secreting tumor cells lose their ability to multiply yet continue to secrete IL-2 at levels equivalent to those secreted by unirradiated cells. Such IL-2-secreting irradiated tumor cells were found to be superior immunogens in comparison to the irradiated parental tumor cells, suggesting their use as tumor vaccines.

PDEF and PDEF-induced proteins as candidate tumor antigens for T cell and antibody-mediated immunotherapy of breast cancer

Novel breast tumor antigens are needed to develop T cell and antibody-based vaccine immunotherapy approach against breast cancer. To this purpose, we have previously shown that PDEF is frequently over expressed in human breast tumors and exhibits highly restricted expression in normal human tissues that is primarily limited to normal prostate. Moreover, PDEF expression correlates with poor overall survival for breast cancer patients. Additionally, Pse (prostate-specific Ets, mouse homologue of PDEF) is immunogenic in female mice and PDEF sequence contains HLA-A2 binding potentially immunogenic peptides. Together, these observations support PDEF as a novel candidate breast tumor antigen. Further, we have identified certain PDEF-induced proteins including CEACAM6, B7-H4, and S100A7 as additional candidate breast tumor antigens.

Prostate-derived Ets factor, an oncogenic driver in breast cancer

Prostate-derived Ets factor (PDEF), a member of the Ets family of transcription factors, differs from other family members in its restricted expression in normal tissues and its unique DNA-binding motif. These interesting attributes coupled with its aberrant expression in cancer have rendered PDEF a focus of increasing interest by tumor biologists. This review provides a current understanding of the characteristics of PDEF expression and its role in breast cancer. The bulk of the evidence is consistent with PDEF overexpression in most breast tumors and an oncogenic role for this transcription factor in breast cancer. In addition, high PDEF expression in estrogen receptor–positive breast tumors showed significant correlation with poor overall survival in several independent cohorts of breast cancer patients. Together, these findings demonstrate PDEF to be an oncogenic driver of breast cancer and a biomarker of poor prognosis in this cancer. Based on this understanding and the limited expression of PDEF in normal human tissues, the development of PDEF–based therapeutics for prevention and treatment of breast cancer is also discussed.

Interleukin-2 secretion by KHT sarcoma cells leads to loss of their vaccine potential.

Abstract We have investigated the effect of interleukin-2 (IL-2) secretion by KHT sarcoma cells upon their vaccine potential in syngeneic C3Hf/He mice. Parental KHT tumor cells were transfected with the plasmid pBCMG-neo-mIL-2 to obtain a transfectant KHT-2-3-7 that secreted 20 units IL-2. KHT-2-3-7 cells elicited protective immunity in only 10% of the immunized mice, compared with 40% of mice immunized with irradiated parental KHT tumor colls. To minimize the contribution of potential antigenic differences between the KHT-2-3-7 transfectant and parental KHT cells, a clone of KHT cells (KHT-C21) was isolated and used in subsequent experiments. A number of transfectants secreting various amounts of IL-2, ranging from 2 units to 200 units, were obtained following transfection of KHT-C21 cells with plasmid pBCMG-neo-mIL-2. Two of the transfectants, C21-13-4 and C21-1, each secreting 200 units IL-2, elicited protective immunity in a significantly lower fraction of mice than did irradiated KHT-C21 parental tumor cells (P<0.0l). Two other transfectants C21-10 and C21-11, secreting 2 and 23 units IL-2 respectively, also showed lower vaccine potential compared with the parental KHT-C21 clone (P<0.05). To minimize further any role for potential antigenic or other molecular differences between the individual transfectants and the clonal KHT-C21 parental cells in lowering their vaccine efficacy, mice were immunized with a mixture of five transfectants, and the results again showed significantly lower vaccine efficacy of the mixture compared with the irradiated parental C21 cells (P<0.0l). In view of published studies showing enhanced or unchanged efficacy of IL-2-secreting tumor cell vaccines, our observation of the lower vaccine potential of IL-2-transduced tumor cells indicates that the vaccine efficacy of IL-2-secreting tumor cells depends on the individual tumor. Such variability/unpredictability would hamper the clinical use of IL-2-secreting tumor cells as vaccines.