August 11, 2011
Scientists Discover Innovative Way to Study Blood Clots
(Ivanhoe Newswire) -- Johns Hopkins scientists have launched a pioneering research program to create, for the first time, human platelet cells from stem cells in order to study inherited blood clotting abnormalities ranging from clots that cause heart attacks and stroke to bleeding disorders.
One goal of the Hopkins research is to increase understanding of how genes regulate the function of platelets, which are the sticky cells in blood that are important to stop excessive bleeding. The researchers will also investigate how genetic variations can affect a person's responsiveness to aspirin and other medications that are designed to prevent clotting, in order to find new ways to prevent and treat abnormal clotting. Current anticoagulants, or "blood thinner" medications that are essential to prevent life-threatening complications from some heart or vascular diseases, are not always effective for individuals with certain genetic variations.
"We will work to develop a completely new approach to generating blood cells for people who are desperately in need of chronic infusions," Lewis Becker, M.D., professor of medicine and cardiologist at the Johns Hopkins University School of Medicine, who is the co-principal investigator of the study, called Functional Genomics of Platelet Aggregation Using iPS and Derived Megakaryocites, was quoted as saying.
To begin the research, small blood samples will be taken from 400 adult study volunteers. White blood cells from those donated samples will be transformed into immortal induced pluripotent stems cells, or iPS cells. Those iPS cells can be reprogramed into any type of human tissue. In this case, they will be converted into megakaryocytes, which are few in number, reside in bone marrow and produce platelets. The researchers will use brand new technology developed just four years ago by Japanese scientists to reprogram human cells. Previously, iPS cells could only be obtained from biopsies of skin or other organs, so having the ability to create them from blood samples is a big advance.
"We are essentially turning back the clock, transforming these adults cells back to their origins into an embryonic-like state," says Linzhao Cheng, Ph.D., professor of medicine and associate director for basic research in the Division of Hematology. He is also a member of the Johns Hopkins Institute for Cell Engineering and a co-principal investigator of the study.
The blood samples will come from a large group of people who previously participated in the Johns Hopkins GeneSTAR study, a genetic research initiative with a database of 4,000 people who have family members with early heart disease. That study, which was the largest platelet function study in the world, uncovered an important genetic region related to platelet function and the effect of aspirin on blood clotting.
The five-year study is one of nine new stem cell projects funded by the NIH to examine how gene variants cause disease. "These studies will illuminate how specific genes behave in different tissues and should clarify the mechanisms by which a gene associated with a disease affects the biology of different tissues," Susan B. Shurin, M.D., acting director of the NIH's National Heart, Lung and Blood Institute, was quoted as saying. "Understanding the cellular and tissue biology will allow us to develop and test new therapies and prevention methods. These approaches, using iPS cells on a large scale, could improve the predictive value of preclinical testing, benefit regenerative medicine and reduce the need for animal models of disease," she said.