Scientists from the Salk Institute have, for the first time, directly converted human skin cells into transplantable white blood cells, which are the soldiers of the immune system that fight infections and invaders. This work could prompt the creation of new therapies that introduce new white blood cells into the body that can attack diseased or cancerous cells or augment immune responses for other conditions.
This work, which shows that only a small amount of genetic manipulation could prompt this direct conversion, was published in the journal Stem Cells.
“The process is quick and safe in mice,” says senior author Juan Carlos Izpisua Belmonte, who holds the Salk’s Roger Guillemin Chair. “It circumvents long-standing obstacles that have plagued the reprogramming of human cells for therapeutic and regenerative purposes.”
The problems that Izpisua Belmonte mentions, includes the long time (at least two months) numbingly tedious cell culture work it takes to produce, characterize and differentiate induced pluripotent stem (iPS) cells. Blood cells derived from iPSCs also have other obstacles: they engraft into organs or bone marrow poorly and can cause tumors.
The new method designed by Izpisua Belmonte and his team, however, only takes two weeks, does not produce tumors, and engrafts well.
“We tell skin cells to forget what they are and become what we tell them to be—in this case, white blood cells,” says one of the first authors and Salk researcher Ignacio Sancho-Martinez. “Only two biological molecules are needed to induce such cellular memory loss and to direct a new cell fate.”
This faster reprogramming technique developed by Belmonte’s team utilized a form of reprogramming that does not go through a pluripotency stage. Such techniques are called indirect lineage conversion or direct reprogramming. Belmonte’s group has demonstrated that such approaches can reprogram cells to form the cells that line blood vessels. Thus instead of de-differentiating cells into an embryonic stem cell-type stage, these cells are rewound just enough to instruct them to form the more than 200 cell types that constitute the human body.
Direct reprogramming used in this study uses a molecule called SOX2 to move the cells into a more plastic state. Then, the cells are transfected with a genetic factor called miRNA125b that drives the cells to become white blood cells. Belmonte and his group are presently conducting toxicology studies and cell transplantation proof-of-concept studies in advance of potential preclinical and clinical studies.
“It is fair to say that the promise of stem cell transplantation is now closer to realization,” Sancho-Martinez says.
Study co-authors include investigators from the Center of Regenerative Medicine in Barcelona, Spain, and the Centro de Investigacion Biomedica en Red de Enfermedades Raras in Madrid, Spain.