Neopeltolide, an active marine-derived macrolide compound shows anti-cell proliferative activities in vitro that could be use primarily in the treatment of cancer also in the treatment of multi-drug resistant cancer cells, secondarily in the treatment of fungal infections preferably in mammal then for the control of fungi growth in spoilage of food, in cosmetic and other consumer items.
In 2014, about 1,665,540 new cancer cases are expected to be diagnosed in the U.S. and about 585,720 are expected to die of cancer, almost 1,600 people per day. Cancer is the second most common cause of death in the US. Cancer is characterized by an accelerated and uncontrolled multiplication of a set of aberrant cells which lose their apoptotic ability. While certain methods and chemical compositions have been developed which aid in inhibiting, remitting, or controlling the growth of, for example, tumors, new methods and antitumor chemical compositions are needed, as well as in multi-drug resistance (MDR).
Infestations in humans, animals and plants have increased, with many having lethal consequences. There are growing needs amongst others in controlling fungi. Fungi are highly resistant microbiological eukaryotic microorganisms. On the one hand, increased use of antibiotics and immunosuppressive drugs are major factors contributing to higher frequency of fungal infections in immunocompromised patients. One the other hand, chemical fungicides have raised environmental and safety concerns (oncogenic nature, teratogenic effects on human and soil pollution) and the regulation of food safety has become more stringent for avoiding food poisoning. While certain methods and chemical compositions have been developed that aid in inhibiting or controlling the growth of fungi, new methods and new effective antifungal compounds or compositions are needed.
The technology is a bioassay-guided fractionation of an anti-cell proliferation compound, neopeltolide - a biologically active macrolide from an ocean sponge - that shows utility in inhibiting cancer cells and fungal growth.
The inventors have shown that neopeltolide compound have potent anti-tumor and anti-fungal activities. It extends to the compositions with the compound, its enantiomeric forms in excess, its analogues and its derived-salts. Neopeltolide compound is useful for inhibiting pathological cellular proliferation in primary end-use of the treatment of cancer as well as in the treatment of multi-drug resistant cancer cells, secondary in the treatment of fungal infections preferably in mammal then for the control of fungi growth in spoilage of food, in cosmetic and other consumer items.
As example, neopeltolide has a cytotoxic activity on tumoral cells candidates (A549 human lung adenocarcinoma, NCI-ADR RES, and P388 murine leukemia cell lines) with IC50 values respectively of 1.17nM, 5.1nM and 0.56nM). Also, against a fungi candidate, Candida albicans, neopeltolide reaches its minimum inhibitory concentration (MIC) at 0.625 pg/ml.
This is a sustaining technology that could bring great value by offering a natural alternative for the control of fungi and for the treatment of the multi-drug resistance (MDR) or multidrug resistance-associated protein (MRP) cases.
The primary field of use of the technology is the treatment of cancer. The expansion of new drugs in oncology represents one of the most promising objectives of the pharmaceutical industry. Indeed, across 2013, fifteen new molecular entities were approved by the FDA; out of which seven were for oncology. Currently targeted therapies dominate the oncology pipeline, followed by chemotherapy. The market landscape is highly competitive; however, the need for novel anti-tumor compounds is high.
The secondary field of use is in the development of antifungal products:
U.S. Patent US 7179828 B2 Biologically active neopeltolide compounds Issued on Feb 20th, 2007.
Amy E. Wright, Ph.D. (UC, Riverside) is Research Professor and Director of the Center for Marine Biomedical and Biotechnology Research at Harbor Branch Oceanographic Institute, Florida Atlantic University. She has conducted research, for the past 25 years, in the field of natural products chemistry. Her primary research interests focus on the purification and structure identification of naturally occurring compounds which may have utility in treating cancer. Much of the research focuses on the investigation of deep-sea invertebrates collected using the Johnson-Sea-Link human- occupied submersibles. Over the course of her career, her research group has identified over 100 different marine natural products with biological activity. One compound she identified early in her career has been approved in Europe for the treatment of soft tissue sarcoma.
Shirley A. Pomponi, Ph.D. (University of Miami) is Research Professor and Executive Director of the NOAA Cooperative Institute for Ocean Exploration, Research, and Technology at Harbor Branch Oceanographic Institute, Florida Atlantic University. Her research focuses on marine biotechnology, in general, and sponge systematics, cell and molecular biology, in particular. She has authored or co-authored more than 100 peer-reviewed scientific publications and is co-inventor on several patents.
Peter J. McCarthy, Ph.D. (University of Kent, Canterbury, UK) is Research Professor at the Center for Marine Biomedical and Biotechnology Research, Harbor Branch Oceanographic Institute, Florida Atlantic University. His research focuses on the discovery of novel natural products and enzymes produced by heterotrophic marine-derived microorganisms.
Oncology, Fungal infection, Food microbiology, Autoimmune Diseases and Inflammatory Diseases.
BrochureBiologically active neopeltolide compounds
Patent Number | US7179828 |
Patent Status | Issued |
Issue Date | February 20, 2007 |