Engineering the first chimeric antibody in targeting intracellular PRL-3 oncoprotein for cancer therapy in mice.

Antibodies are considered as 'magic bullets' because of their high specificity. It is believed that antibodies are too large to routinely enter the cytosol, thus antibody therapeutic approach has been limited to extracellular or secreted proteins expressed by cancer cells. However, many oncogenic proteins are localized within the cell. To explore the possibility of antibody therapies against intracellular targets, we generated a chimeric antibody targeting the intracellular PRL-3 oncoprotein to assess its antitumor activities in mice. Remarkably, we observed that the PRL-3 chimeric antibody could efficiently and specifically reduce the formation of PRL-3 expressing metastatic tumors. We further found that natural killer (NK) cells were important in mediating the therapeutic effect, which was only observed in a nude mouse model (T-cell deficient), but not in a Severe Combined Immunodeficiency' (scid ) mouse model (B- and T-cell deficient), indicating the anticancer effect also depends on host B-cell activity. Our study involving 377 nude and scid mice suggest that antibodies targeting intracellular proteins can be developed to treat cancer.

Targeting intracellular oncoproteins with antibody therapy or vaccination.

Antibody-based therapies have better specificity and thus improved efficacy over standard chemotherapy regimens, which result in extended survival and improved quality of life for cancer patients. Because antibodies are viewed as too large to access intracellular locations, antibody therapy has traditionally targeted extracellular or secreted proteins expressed by cancer cells. However, many oncogenic proteins are found within the cell (such as intracellular phosphatases/kinases and transcription factors) and have therefore not been pursued for antibody therapies. Here, we explored the possibility of antibody therapy or vaccination against intracellular proteins. As proofs of concept, we selected three representative intracellular proteins as immunogens for tumor vaccine studies: PRL-3 (phosphatase of regenerating liver 3), a cancer-associated phosphatase; EGFP (enhanced green fluorescent protein), a general reporter; and mT (polyomavirus middle T), the polyomavirus middle T oncoprotein. A variety of tumors that expressed these intracellular proteins were clearly inhibited by their respective exogenous antibodies or by antigen-induced host antibodies (vaccination). These anticancer activities were reproducibly observed in hundreds of C57BL/6 tumor-bearing mice and MMTV-PymT transgenic breast tumor mice. Our in vivo data suggest that immunotherapies can target not only extracellular but also intracellular oncoproteins.

PRL-3, a metastasis associated tyrosine phosphatase, is involved in FLT3-ITD signaling and implicated in anti-AML therapy.

Combination with other small molecule drugs represents a promising strategy to improve therapeutic efficacy of FLT3 inhibitors in the clinic. We demonstrated that combining ABT-869, a FLT3 inhibitor, with SAHA, a HDAC inhibitor, led to synergistic killing of the AML cells with FLT3 mutations and suppression of colony formation. We identified a core gene signature that is uniquely induced by the combination treatment in 2 different leukemia cell lines. Among these, we showed that downregulation of PTP4A3 (PRL-3) played a role in this synergism. PRL-3 is downstream of FLT3 signaling and ectopic expression of PRL-3 conferred therapeutic resistance through upregulation of STAT (signal transducers and activators of transcription) pathway activity and anti-apoptotic Mcl-1 protein. PRL-3 interacts with HDAC4 and SAHA downregulates PRL-3 via a proteasome dependent pathway. In addition, PRL-3 protein was identified in 47% of AML cases, but was absent in myeloid cells in normal bone marrows. Our results suggest such combination therapies may significantly improve the therapeutic efficacy of FLT3 inhibitors. PRL-3 plays a potential pathological role in AML and it might be a useful therapeutic target in AML, and warrant clinical investigation.

Monoclonal antibodies target intracellular PRL phosphatases to inhibit cancer metastases in mice.

PRL-1 (phosphatase of regenerating liver-1), PRL-2 and PRL-3 are protein tyrosine phosphatases with a C-terminal prenylation motif that are localized to the inner leaflet of the plasma membrane and early endosomes. A variety of metastatic PRL-overexpressing cancers have been reported. Therefore, the three PRL-phosphatases represent an intriguing group of proteins being validated as biomarkers and therapeutic targets in cancer. Targeting intracellular PRLs to prevent cancer metastasis by exogenous reagents is a challenging task. In an attempt to destroy PRL-overexpressing cancer cells with their respective PRL-antibodies, we generated an animal model that allows rapid formation of aggressive metastatic tumors caused by inoculation of PRL-1- or PRL-3-expressing cells. Surprisingly, mice treated with PRL-1 or PRL-3 mAbs show inhibition of tumor formation by approximately 90% compared to untreated mice. Here we provide the first examples that PRL-1 and PRL-3 mAbs are able to target their respective phosphatases specifically and efficiently despite their intracellular localization to block cancer metastasis in experimental animals. Furthermore, we also demonstrate that PRL-1 mAb specifically blocks the formation of metastatic tumors formed by PRL-1- (but not PRL-3-) expressing cells; while PRL-3 mAb specifically blocks tumor formation of PRL-3- (but not PRL-1-) expressing cells. More importantly, we show that metastatic tumor formation by A2780 human ovarian cancer cells that express endogenous PRL-3 is dramatically blocked by PRL-3 antibodies. In contrast, the PRL-3 antibody treatment has no effect on tumor formation of CT26 mouse colon cancer cells which do not naturally express PRL-3 protein. Our data provide hope for the treatment of PRL-expressing cancers and will prompt a reevaluation of a wide spectrum of intracellular oncoproteins as possible targets with mAbs for anticancer therapy.