Imaging B Cells in a Mouse Model of Multiple Sclerosis Using 64Cu-Rituximab PET.

B lymphocytes are a key pathologic feature of multiple sclerosis (MS) and are becoming an important therapeutic target for this condition. Currently, there is no approved technique to noninvasively visualize B cells in the central nervous system (CNS) to monitor MS disease progression and response to therapies. Here, we evaluated 64Cu-rituximab, a radiolabeled antibody specifically targeting the human B cell marker CD20, for its ability to image B cells in a mouse model of MS using PET. Methods: To model CNS infiltration by B cells, experimental autoimmune encephalomyelitis (EAE) was induced in transgenic mice that express human CD20 on B cells. EAE mice were given subcutaneous injections of myelin oligodendrocyte glycoprotein fragment1-125 emulsified in complete Freund adjuvant. Control mice received complete Freund adjuvant alone. PET imaging of EAE and control mice was performed 1, 4, and 19 h after 64Cu-rituximab administration. Mice were perfused and sacrificed after the final PET scan, and radioactivity in dissected tissues was measured with a γ-counter. CNS tissues from these mice were immunostained to quantify B cells or were further analyzed via digital autoradiography. Results: Lumbar spinal cord PET signal was significantly higher in EAE mice than in controls at all evaluated time points (e.g., 1 h after injection: 5.44 ± 0.37 vs. 3.33 ± 0.20 percentage injected dose [%ID]/g, P < 0.05). 64Cu-rituximab PET signal in brain regions ranged between 1.74 ± 0.11 and 2.93 ± 0.15 %ID/g for EAE mice, compared with 1.25 ± 0.08 and 2.24 ± 0.11 %ID/g for controls (P < 0.05 for all regions except striatum and thalamus at 1 h after injection). Similarly, ex vivo biodistribution results revealed notably higher 64Cu-rituximab uptake in the brain and spinal cord of huCD20tg EAE, and B220 immunostaining verified that increased 64Cu-rituximab uptake in CNS tissues corresponded with elevated B cells. Conclusion: B cells can be detected in the CNS of EAE mice using 64Cu-rituximab PET. Results from these studies warrant further investigation of 64Cu-rituximab in EAE models and consideration of use in MS patients to evaluate its potential for detecting and monitoring B cells in the progression and treatment of this disease. These results represent an initial step toward generating a platform to evaluate B cell-targeted therapeutics en route to the clinic.

AshwaMAX and Withaferin A inhibits gliomas in cellular and murine orthotopic models.

Glioblastoma multiforme (GBM) is an aggressive, malignant cancer Johnson and O'Neill (J Neurooncol 107: 359-364, 2012). An extract from the winter cherry plant (Withania somnifera ), AshwaMAX, is concentrated (4.3 %) for Withaferin A; a steroidal lactone that inhibits cancer cells Vanden Berghe et al. (Cancer Epidemiol Biomark Prev 23: 1985-1996, 2014). We hypothesized that AshwaMAX could treat GBM and that bioluminescence imaging (BLI) could track oral therapy in orthotopic murine models of glioblastoma. Human parietal-cortical glioblastoma cells (GBM2, GBM39) were isolated from primary tumors while U87-MG was obtained commercially. GBM2 was transduced with lentiviral vectors that express Green Fluorescent Protein (GFP)/firefly luciferase fusion proteins. Mutational, expression and proliferative status of GBMs were studied. Intracranial xenografts of glioblastomas were grown in the right frontal regions of female, nude mice (n = 3-5 per experiment). Tumor growth was followed through BLI. Neurosphere cultures (U87-MG, GBM2 and GBM39) were inhibited by AshwaMAX at IC50 of 1.4, 0.19 and 0.22 µM equivalent respectively and by Withaferin A with IC50 of 0.31, 0.28 and 0.25 µM respectively. Oral gavage, every other day, of AshwaMAX (40 mg/kg per day) significantly reduced bioluminescence signal (n = 3 mice, p < 0.02, four parameter non-linear regression analysis) in preclinical models. After 30 days of treatment, bioluminescent signal increased suggesting onset of resistance. BLI signal for control, vehicle-treated mice increased and then plateaued. Bioluminescent imaging revealed diffuse growth of GBM2 xenografts. With AshwaMAX, GBM neurospheres collapsed at nanomolar concentrations. Oral treatment studies on murine models confirmed that AshwaMAX is effective against orthotopic GBM. AshwaMAX is thus a promising candidate for future clinical translation in patients with GBM.

Short communication: nanoparticle thermotherapy and external beam radiation therapy for human prostate cancer cells.

UNLABELLED: Nanoparticle thermotherapy (NPTT) uses monoclonal antibody-linked iron oxide magnetic nanoparticles (bioprobes) for the tumor-specific thermotherapy of cancer by hysteretic heating of the magnetic component of the probes through an externally applied alternating magnetic field (AMF). The present study investigated the effect of NPTT on a human prostate cancer cell line, DU145. The concept of total heat dose (THD) as a measure for NPTT was validated on a cellular level and THD was correlated to cell death in vitro. The study, furthermore, explored the potential enhancement of the NPTT effect through added external beam radiation therapy (EBRT), because both forms of treatment have a different, and potentially complementary, mechanism of causing cell death. METHODS: Using carbodiimide, (111)In-DOTA-ChL6 was conjugated to dextran iron oxide 20-nm particles with polyethylene glycol COOH groups on the surface and purified as (111)In-bioprobes. NPTT and EBRT were applied alone and combined to cells labeled with the bioprobes. Cell response was monitored by measuring lactate dehydrogenase (LDH), a product of cytolysis, in the medium. This distinct focus on the response to NPTT was possible, since we found in previous studies that the LDH assay was relatively insensitive to the response of cells (without bioprobes) to EBRT in the dose levels given here. RESULTS: NPTT showed a significantly increased cell death at a total calculated heat dose of 14.51 and 29.02 J/g cells (50% and 100% AMF duty, 350 Oe, 136 kHz, 12 cycles, 20 minutes total), compared with AMF exposure in the absence of bioprobes. Adding EBRT to NPTT did not increase cell death, as measured by LDH. However, EBRT given to cells labeled with bioprobes caused significant cell death at radiation doses of 10 Gy and higher. CONCLUSIONS: In human prostate cancer cell cultures, NPTT applied as a single modality caused cell death that correlated with THD estimation; complete cell death occurred at 14.51 J/g cells. Consequently, enhancement of the NPTT effect through the addition of EBRT could not be addressed. Interestingly, EBRT induced cell death on bioprobe-labeled cells at EBRT levels that did not show cell death in the absence of bioprobes; this phenomenon is worth investigating further.