TrkA overexpression in non-tumorigenic human breast cell lines confers oncogenic and metastatic properties.

BACKGROUND/PURPOSE: TrkA overexpression occurs in over 20% of breast cancers, including triple-negative breast cancers (TNBC), and has recently been recognized as a potential driver of carcinogenesis. Recent clinical trials of pan-Trk inhibitors have demonstrated targeted activity against tumors harboring NTRK fusions, a relatively rare alteration across human cancers. Despite this success, current clinical trials have not investigated TrkA overexpression as an additional therapeutic target for pan-Trk inhibitors. Here, we evaluate the cancerous phenotypes of TrkA overexpression relative to NTRK1 fusions in human cells and assess response to pharmacologic Trk inhibition. EXPERIMENTAL DESIGN/METHODS: To evaluate the clinical utility of TrkA overexpression, a panel of TrkA overexpressing cells were developed via stable transfection of an NTRK1 vector into the non-tumorigenic breast cell lines, MCF10A and hTERT-IMEC. A panel of positive controls was generated via stable transfection with a CD74-NTRK1 fusion vector into MCF10A cells. Cells were assessed via various in vitro and in vivo analyses to determine the transformative potential and targetability of TrkA overexpression. RESULTS: TrkA overexpressing cells demonstrated transformative phenotypes similar to Trk fusions, indicating increased oncogenic potential. TrkA overexpressing cells demonstrated growth factor-independent proliferation, increased PI3Kinase and MAPKinase pathway activation, anchorage-independent growth, and increased migratory capacity. These phenotypes were abrogated by the addition of the pan-Trk inhibitor, larotrectinib. In vivo analysis demonstrated increased tumorgenicity and metastatic potential of TrkA overexpressing breast cancer cells. CONCLUSIONS: Herein, we demonstrate TrkA overexpressing cells show increased tumorgenicity and are sensitive to pan-Trk inhibitors. These data suggest that TrkA overexpression may be an additional target for pan-Trk inhibitors and provide a targeted therapy for breast cancer patients.

A prodrug-doped cellular Trojan Horse for the potential treatment of prostate cancer.

Despite considerable advances in prostate cancer research, there is a major need for a systemic delivery platform that efficiently targets anti-cancer drugs to sites of disseminated prostate cancer while minimizing host toxicity. In this proof-of-principle study, human mesenchymal stem cells (MSCs) were loaded with poly(lactic-co-glycolic acid) (PLGA) microparticles (MPs) that encapsulate the macromolecule G114, a thapsigargin-based prostate specific antigen (PSA)-activated prodrug. G114-particles (∼950 nm in size) were internalized by MSCs, followed by the release of G114 as an intact prodrug from loaded cells. Moreover, G114 released from G114 MP-loaded MSCs selectively induced death of the PSA-secreting PCa cell line, LNCaP. Finally, G114 MP-loaded MSCs inhibited tumor growth when used in proof-of-concept co-inoculation studies with CWR22 PCa xenografts, suggesting that cell-based delivery of G114 did not compromise the potency of this pro-drug in-vitro or in-vivo. This study demonstrates a potentially promising approach to assemble a cell-based drug delivery platform, which inhibits cancer growth in-vivo without the need of genetic engineering. We envision that upon achieving efficient homing of systemically infused MSCs to cancer sites, this MSC-based platform may be developed into an effective, systemic 'Trojan Horse' therapy for targeted delivery of therapeutic agents to sites of metastatic PCa.

Anti-tumor effect of combination therapy with intratumoral controlled-release paclitaxel (PACLIMER microspheres) and radiation.

BACKGROUND: Paclitaxel is one of the few chemotherapeutics effective in patients with advanced protstate cancer. Paclitaxel has also been reported to have radiosensitizing effects in prostate cancer. Local delivery of a controlled-release paclitaxel product may allow for increase local concentrations of paclitaxel at the tumor site and, in conjunction with radiation, may enhance cell kill by its radiosensitization mechanism. METHODS: Orthotopic LNCaP tumors were injected with 40% PACLIMER Microspheres (40% loading; w:w) when tumors were 100-200 mm(3). Twenty-eight days post cell injection, mice were sacrificed, tumors weighed, and serum measured for PSA. TSU-xenografts were injected with PACLIMER Microspheres (10% and 40% loaded; w:w) or placebo microspheres when the tumors were approximately 100 mm(3). Half of xenograft tumors were irradiated with a single dose (10 Gy) of radiation. Tumor volume was followed over time. RESULTS: Forty percent PACLIMER Microspheres significantly reduced tumor growth in the LNCaP orthotopic model. PSA was a good indicator of response. Forty percent PACLIMER Microspheres had a significant effect on slowing TSU growth compared to placebo microspheres. Addition of a single acute dose of radiation significantly enhanced the effect of 10% PACLIMER Microspheres (P < 0.05), had minimal effect on 40% PACLIMER Microspheres, and no enhancing effect on tumors treated with placebo microspheres. CONCLUSIONS: A controlled-release formulation of paclitaxel can be very effective in the treatment of prostate cancer. Additionally, PACLIMER Microspheres may be effectively used as a radiosensitizer in genitourinary cancers.