Apr. 18, 2003 A group of scientists at The Scripps Research Institute (TSRI) has designed a "hybrid" anticancer compound that physically combines the potent punch of a cancer cell-targeting agent with the long-lasting dose of an antibody.
Much as a hybrid bicycle is a cross between two bikes--a road bike frame with mountain bike handlebars, for instance--this hybrid compound is a cross between two molecules. One is a traditional anticancer drug, a small molecule that targets cancer tumors. The other is a type of antibody, which is a protein produced in great abundance by the body’s immune system and found naturally in the bloodstream.
The hybrid of the two, described in an upcoming issue of the journal Proceedings of the National Academy of Sciences, was found to have a profound effect on the size of tumors in mouse models--shrinking tumors of both Kaposi's sarcoma and colon cancers in these preclinical studies. Moreover, this approach is general enough that it could be used to design hybrids against any number of cancers.
"A single antibody can become a whole multiplicity of therapeutics simply by mixing it with the desired small molecule," says TSRI Professor Carlos F. Barbas III, Ph.D., who is Janet and W. Keith Kellogg II Chair in Molecular Biology. Barbas conducted the research with TSRI President Richard A. Lerner, M.D., and several colleagues at TSRI's Skaggs Institute for Chemical Biology.
Steering and Support, Joined at the Hip
The TSRI team built the hybrid molecule with a "catalytic" antibody, a small drug molecule, and a linker molecule that joins the two. The hybrid thus formed borrows the wheels and the frame of the antibody for supports and the handlebars of the small drug molecule for steering ability.
Also called immunoglobulins, antibodies are proteins produced by immune cells that are designed to recognize a wide range of foreign pathogens. After a bacterium, virus, or other pathogen enters the bloodstream, antibodies target antigens--proteins, carbohydrate molecules, and other pieces of the pathogen--specific to that foreign invader. These antibodies then alert the immune system to the presence of the invaders and attract lethal "effector" immune cells to the site of infection.
Antibodies have for many years been seen as useful therapeutics for a number of human diseases ranging from rheumatoid arthritis to leukemia because they are designed to target particular cells and attract other parts of the immune system to the site. There are a dozen antibodies that are approved as therapeutics by the U.S. Food and Drug Administration, and many more under development.
The hybrid the TSRI team created does not use the antibody's targeting ability but rather its other properties--namely its ability to stay around in the bloodstream. While many small-molecule drugs are cleared from the blood by the kidneys in a matter of minutes or hours, the large, soluble antibody molecules are designed by the body to remain in the bloodstream for long periods of time. In fact, in their experiments, Barbas and his colleagues observed that their hybrid antibodies remained in circulation for a week, while the small-molecule drug was cleared in minutes.
Barbas and his colleagues used a catalytic antibody, since these have the ability to react with other molecules like a catalytic enzyme. This ability allowed them to react the antibody with the small drug molecule and "covalently" attach the two with a linker. And while the antibody portion of the hybrids kept them circulating, the small-molecule portion guided them towards cancer cells. In this case, the small molecule they used guided the hybrids to target two molecules known as the integrins alpha(v)beta(3) and alpha(v)beta(5).
Cancerous cells activate endothelial cells to express integrins like alpha(v)beta(3) and alpha(v)beta(5) to promote the process of angiogenesis, the formation of new blood vessels that bring necessary nutrients and oxygen to hungry tumor cells. Block angiogenesis, the thinking goes, and you can starve a tumorlike drying out a lake by diverting all its tributaries. Many cancer cells like breast, ovarian and prostate cancer also express these integrins on their surface, providing for a potential double-strike against the tumor itself as well as its key blood supply.
In its study, the TSRI team found that the affinity of the small molecule for the alpha(v)beta(3) and alpha(v)beta(5) on the surfaces of the tumor cells steered the hybrids towards the tumors. And once there, the antibody part of the hybrid would activate other parts of the immune system--like macrophages and the "compliment" system--that recognize the antibody and destroy the cells to which they are attached.
This proved to work well in the pre-clinical studies performed by the TSRI team. Moreover, say the authors, this hybrid approach could be used as a broad drug-design strategy to rescue compounds that are able to kill cancerous cells in the test tube but have proven ineffective in human trials, or to provide killing function to drugs that may only bind the tumor cells.
"There is a whole world of small molecules that have been developed and tested in the clinic but have failed because of low half-life or poor efficacy," says Barbas. "A single antibody can be used [as a vehicle for many of these small molecules]."
The article, "Chemically programmed monoclonal antibodies for cancer therapy: Adaptor immunotherapy based on a covalent antibody catalyst," authored by Christoph Rader, Subhash C. Sinha, Mikhail Popkov, Richard A. Lerner, and Carlos F. Barbas, III, is available online at: www.pnas.org_cgi_doi_10.1073_pnas.0931308100 and will be published in an upcoming issue of the journal Proceedings of the National Academy of Science.
This work was supported by funds from The Skaggs Institute of Chemical Biology at TSRI and an Investigator Award from the Cancer Research Institute.
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