Dendritic cells in clinical trials for multiple myeloma

Due to the existence of the truly specific tumor antigen idiotype in multiple myeloma and based on encouraging data from dendritic cell vaccinated B-cell non-Hodgkin's lymphoma (NHL) patients, dendritic cell-based vaccination was first initiated in myeloma patients in 1995. This overview will summarize published and ongoing clinical trials in patients with multiple myeloma who are treated with idiotype-based dendritic cell (Id/DC) vaccination. All groups of investigators have found that Id/DC vaccination of multiple-myeloma patients is feasible and that myeloma-specific immunity can be induced in heavily pretreated individuals. In future trials, new dendritic cell-based immunization strategies will be investigated based on techniques like RNA transfection of DC.

Reichardt VL, Brossart P., Methods Mol Med. 2005;109:127-36

Seliciclib -CYC202- Shown to Kill Myeloma Cells

Cyclacel, a UK-based biopharmaceutical company, announced at the American Society for Hematology (ASH) meeting that seliciclib (CYC202 or R-roscovitine) killed multiple myeloma cancer cells by causing them to commit suicide. Seliciclib is Cyclacel's leading Cyclin Dependent Kinase (CDK) inhibitor drug.

Researchers at Dana Farber Cancer Institute and Harvard Medical School reported their findings that seliciclib had potent cytotoxic effects against nine different multiple myeloma cell lines removed from patients with multiple myeloma that were both sensitive and resistant to conventional chemotherapy. The drug appeared to induce myeloma cells to commit suicide through apoptosis by blocking the production of a protein that is required for cancer cell survival. The investigators concluded that their study provided pre-clinical support for a clinical trial of seliciclib, either alone or in combination with other agents with the objective of improving patient outcomes in multiple myeloma.

Seliciclib is currently in Phase II clinical trials as a single therapy in multiple myeloma as well as two other B-cell hematological malignancies: B-cell Chronic Lymphocytic Leukemia (B-CLL) and Mantle Cell Lymphoma.

Scientists Stalk PPAR-gamma, Find Novel Cancer Connection

In laboratory tests on multiple myeloma cells, University of Rochester researchers found that this type of cancer expresses a protein that makes it an easy target for an existing class of diabetes drugs. After more investigation, they hope the discovery will lead to a new, targeted therapy for myeloma patients.

“To our knowledge, this is the first time anyone has shown that multiple myeloma cells are sensitive to these agents, and we found multiple myeloma cells are killed quite effectively,” said lead author Richard P. Phipps, Ph.D., professor of Environmental Medicine and of Oncology at the University of Rochester Medical Center.

The research was reported in the November issue of Clinical Immunology.

The drugs in question are from the thiazolidinedione (TZD) class of anti-diabetic therapies, known as PPAR-gamma ligands. They bind to PPAR-gamma, a protein associated with multiple myeloma and many other cancers, as well as chronic inflammation and diabetes. When the drugs bind to PPAR-gamma, at least in laboratory experiments, the cancerous cells are destroyed.

PPAR-ligands are emerging as a new type of cancer therapy because they directly target errant cells and stop tumor growth, at least in animal models. Phipps’ laboratory also found that the PPAR-ligands currently used in anti-diabetic drugs could induce a type of cell death called apoptosis. This is significant because multiple myeloma is very difficult to treat, as it is usually resistant to drug-induced apoptosis.

Another encouraging factor is that the anti-diabetes drugs were able to kill the multiple myeloma cells, despite the fact that myeloma produces its own growth factor (Interleukin 6), which usually enables the cancer to multiply more effectively. Furthermore, the Phipps lab found that the effectiveness of the TZD drugs was enhanced when combined with Vitamin A-like compounds.

Co-investigator Steven Bernstein, M.D., who treats myeloma patients at the university’s James P. Wilmot Cancer Center, is cautious but hopeful about the prospects of this research leading to a new treatment. “Although we are optimistic about these early findings, we need to do further investigation to understand how the TZD class of drugs work against multiple myeloma, before clinical trials are warranted.”

High-dose chemotherapy and stem-cell transplant are the standard treatments. Recently, patients have also experienced some success with two new, biologically targeted therapies: thalidomide, which was given decades ago to women for morning sickness, and the proteosome inhibitor Velcade, which targets the parts of the cell that regulates protein expression, Bernstein said. The latest research may offer a third novel approach.

The myeloma research emerged from a larger investigation conducted by Phipps’ laboratory into inflammation, the culprit of many serious illnesses. One area of focus is how the immune system reacts to PPAR-ligands.

Simvastatin induces death of multiple myeloma cell lines

BACKGROUND: Accumulating reports indicate that statins widely prescribed for hypercholesteromia have antineoplastic activity. We hypothesized that because statins inhibit farnesylation of Ras that is often mutated in multiple myeloma (MM), as well as the production of interleukin (IL)-6, a key cytokine in MM, they may have antiproliferative and/or proapoptotic effects in this malignancy.

METHODS: U266, RPMI 8226, and ARH77 were treated with simvastatin (0-30 microM) for 5 days. The following aspects were evaluated: viability (IC50), cell cycle, cell death, cytoplasmic calcium ion levels, supernatant IL-6 levels, and tyrosine kinase activity.

RESULTS: Exposure of all cell lines to simvastatin resulted in reduced viability with IC50s of 4.5 microM for ARH77, 8 microM for RPMI 8226, and 13 microM for U266. The decreased viability is attributed to cell-cycle arrest (U266, G1; RPMI 8226, G2M) and cell death. ARH77 underwent apoptosis, whereas U266 and RPMI 8226 displayed a more necrotic form of death. Cytoplasmic calcium levels decreased significantly in all treated cell lines. IL-6 secretion from U266 cells was abrogated on treatment with simvastatin, whereas total tyrosine phosphorylation was unaffected.

CONCLUSIONS: Simvastatin displays significant antimyeloma activity in vitro. Further research is warranted for elucidation of the modulated molecular pathways and clinical relevance.

Gronich N, Drucker L, Shapiro H, Radnay J, Yarkoni S, Lishner M., Department of Medicine, Laboratories, Sapir Medical Center, Meir Hospital, Kfar-Saba, Israel.

Journal Investig Med. 2004 Jul;52(5):335-44