image: An image of the enzyme that is targeted by the sulfated DHPs, the new molecules designed by Desai's team. view more
Credit: Umesh R. Desai, PhD/VCU
RICHMOND, Va. (Nov. 8, 2007) – Virginia Commonwealth University researchers have discovered a new mechanism to inhibit key enzymes that play a major role in clotting disorders, which could lead to novel therapies to treat clots in the lungs and those localized deep in the body in areas such as the legs.
Antithrombotic disorders occur when the effect of thrombin, a protein involved in coagulation, is inhibited, rendering blood unable to clot effectively. These disorders are considered common and can be fatal. Additionally, clotting disorders arise due to complications from other diseases like cancer. Although there are a number of anticoagulation drugs available -- heparins and warfarins -- some patients develop adverse reactions to the therapy and must be closely monitored.
In a study published in the Nov. 2 issue of the Journal of Biological Chemistry, Umesh R. Desai, Ph.D., a professor in the Department of Medicinal Chemistry at the VCU School of Pharmacy, lead investigator on the study, reported on the design of three highly complex molecules with unique anticoagulant properties that were prepared in the laboratory. According Desai, these molecules, known as sulfated DHPs, are completely different from anticoagulants used in the clinic today including heparins, coumarins and hirudins.
The team demonstrated that the molecules were able to inhibit the ability of critical enzymes involved with the cascade of events involved in blood clotting. Specifically, the molecules prevent the normal action of thrombin and factor Xa, which are the critical enzymes targeted by current anticoagulant therapy.
“We have identified a new mechanism that may prevent clotting. This approach may result in new drugs for the treatment of thrombotic disorders, including pulmonary embolism, deep vein thrombosis and more,” said Desai.
“The molecules we have designed may possess several advantages compared to currently available anticoagulation drugs,” he said.
“For example, new anti-clotting therapies may result in reduced hospital stays for patients, fewer side effects, and possibly an overall cost reduction in therapy because our molecules are likely to be synthesized in an inexpensive manner.”
Desai and his team are now investigating which unit or units in the complex molecule are responsible for the anti-clotting activity.
This work was supported by grants from the National Institutes of Health and the American Heart Association National Center.
Desai collaborated with VCU researchers Brian L. Henry, Bernhard H. Monien; and Paul E. Bock, who is affiliated with Vanderbilt University.
About VCU and the VCU Medical Center: Virginia Commonwealth University is the largest university in Virginia and ranks among the top 100 universities in the country in sponsored research. Located on two downtown campuses in Richmond, VCU enrolls nearly 32,000 students in 205 certificate and degree programs in the arts, sciences and humanities. Sixty-five of the programs are unique in Virginia, many of them crossing the disciplines of VCU’s 15 schools and one college. MCV Hospitals and the health sciences schools of Virginia Commonwealth University compose the VCU Medical Center, one of the nation’s leading academic medical centers. For more, see www.vcu.edu.
Journal
Journal of Biological Chemistry