Clinically relevant humanized mouse models of metastatic prostate cancer to evaluate cancer therapies.

There is tremendous need for improved prostate cancer (PCa) models. The mouse prostate does not spontaneously form tumors and is anatomically and developmentally different from the human prostate. Engineered mouse models lack the heterogeneity of human cancer and rarely establish metastatic growth. Human xenografts represent an alternative but rely on an immunocompromised host. Accordingly, we generated PCa murine xenograft models with an intact human immune system (huNOG and huNOG-EXL mice) to test whether humanizing tumor-immune interactions would improve modeling of metastatic PCa and the impact of hormonal and immunotherapies. These mice maintain multiple human cell lineages, including functional human T-cells and myeloid cells. In 22Rv1 xenografts, subcutaneous tumor size was not significantly altered across conditions; however, metastasis to secondary sites differed in castrate huNOG vs background-matched immunocompromised mice treated with enzalutamide (enza). VCaP xenograft tumors showed decreases in growth with enza and anti-Programed-Death-1 treatments in huNOG mice, and no effect was seen with treatment in NOG mice. Enza responses in huNOG and NOG mice were distinct and associated with increased T-cells within tumors of enza treated huNOG mice, and increased T-cell activation. In huNOG-EXL mice, which support human myeloid development, there was a strong population of immunosuppressive regulatory T-cells and Myeloid-Derived-Suppressor-Cells (MDSCs), and enza treatment showed no difference in metastasis. Results illustrate, to our knowledge, the first model of human PCa that metastasizes to clinically relevant locations, has an intact human immune system, responds appropriately to standard-of-care hormonal therapies, and can model both an immunosuppressive and checkpoint-inhibition responsive immune microenvironment.

Engineering Cell-Free Protein Synthesis for High-Yield Production and Human Serum Activity Assessment of Asparaginase: Toward On-Demand Treatment of Acute Lymphoblastic Leukemia.

Acute lymphocytic leukemia (ALL) is a common childhood cancer in the United States, with over 6000 new cases diagnosed each year. Administration of bacterial asparaginase (ASNase) has improved survival rates to nearly 80%, however these therapeutics have high incidence of immunological neutralization and serum activity must be monitored for most effective treatment regimens. Here, a 72% improvement in cell-free protein synthesis (CFPS) of FDA approved l-asparaginase (crisantaspase) is demonstrated by employing an aspartate-fed-batch reactor format. A CFPS-based ASNase activity assay as a tool for therapeutic regimentation and production quality control is also presented. This work suggests that shelf-stable and low-cost Escherichia coli-based CFPS reactions may be employed on-demand to 1) synthesize biologics on-site for patient administration, 2) verify biologic activity for dosage calculations, and 3) monitor therapeutic activity in human serum during the treatment regimen. The combination of both therapeutic production and activity assessment introduces a concept of synergistic utility for bacterial cell lysates in modern medical treatment. Indeed, recent work with CFPS biosensors supports a not-too-distant future when shelf-stable E. coli CFPS systems are used to diagnose, treat, and monitor treatment of diseases in the clinical setting.

Discovery of novel scaffolds for Rho kinase 2 inhibitor through TRFRET-based high throughput screening assay.

Recent advances in basic and clinical studies have identified Rho kinase (ROCK) as an important target potentially implicated in a variety of cardiovascular diseases and ROCK inhibitors were considered as a pharmacological strategy to prevent and treat cardiovascular diseases. To screen the small molecule compound library against ROCK, a high throughput screening (HTS) campaign was carried out using immobilized metal affinity for phosphochemicals (IMAP)-based time-resolved fluorescence resonance energy transfer (TR-FRET) assay. Z' value and signal to background (S/B) ratio were achieved at 0.76 and 5.27 for the pilot library screening of the most diverse set consisting of 15,040 compounds with a reasonable reconfirmation rate. From this screening campaign, four novel scaffolds, such as 3- nitropyridine, 4-methoxy-1,3,5,-triazine, naphthalene-1,4-dione, and 2,3-dihydro-1H-pyrrolo[2,3-b]quinoxaline, were yielded. Particularly, we found that 3-nitropyridine derivatives possess potent inhibitory activity and selectivity for ROCK. Our findings provide important information for the design of novel ROCK inhibitor.