Not too long ago, leukemia left us with no chance. Today doctors
can give patients hope by transplanting bone marrow, the starting point
of a “new” immune system. These transplanted cells replace the diseased,
blood-building stem cells in the bone marrow and take over their job of
producing healthy blood cells, while also destroying leukemia cells.
The problem is that this immune system originates from a foreign body
and therefore can also attack healthy tissue in the patient. The skin,
liver, and intestine are most affected by these attacks – their cells
can be destroyed and the organs damaged, sometimes so severely as to
cause organ failure. The medical term for this phenomenon is
graft-versus-host disease (GvHD), and the scale of the problem posed by
this misdirected immune response is illustrated by statistics revealing
that up to 50 percent of all patients ultimately suffer from
GvHD-induced damage; in up to 20 percent of cases this damage is fatal.
Not to ignore the further risk: that one in five leukemia patients
suffer a relapse after the transplant.
In order to combat the cancer effectively, doctors give leukemia
patients chemotherapy and radiation therapy before the transplant. These
treatments destroy the patient’s entire blood-building system, creating
space for the donor’s healthy cells. Any cancer cells that might
survive this treatment are identified and destroyed by the new immune
cells. So that the “foreign” immune system does not turn against healthy
tissue, doctors additionally give patients immunosuppressants to
artificially suppress the immune system. There is a fine balance to be
struck here, as immunosuppressants not only inhibit GvHD but also the
desired immune response, i.e. killing off the cancer cells.
Minimizing the risk of a misdirected immune reaction
Researchers at the Fraunhofer Institute for Cell Therapy and
Immunology IZI in Leipzig are investigating how to improve the situation
for leukemia sufferers. “Our goal is to avoid GvHD without changing how
the new immune effect acts on the tumor,” says Dr. Stephan Fricke, head
of the Immune Tolerance unit at the IZI and doctor at the Department of
Hematology and Oncology, University Hospital Leipzig. “Our hopes are
pinned on monoclonal antibodies, which specifically bind to the surface
of immune cells and prevent the immune cells reacting adversely with the
patient’s tissue.” It’s particularly important that the antibodies also
act on the blood stem cells to be transplanted and on all immune cells
that develop from them. This allows researchers to modulate the cells in
advance of transplantation, causing them to “tolerate” the patient’s
healthy tissue instead of attacking it. “We’re then able to effectively
reduce the risk of a GvHD without any side effects,” explains Fricke.
The antibodies do not alter the immune response against remaining cancer
cells – they are still destroyed as before. This reduces the risk of
leukemia coming back after the transplant.
IZI scientists are currently collaborating with their colleagues from
the Translational Centre for Regenerative Medicine at the Universität
Leipzig on research into the cellular foundations of these effects. What
is the optimum point at which to add the antibodies to the donor bone
marrow? How many antibodies should be used? Setting out to answer these
questions, researchers first simulate both GvHD and the human immune
system using a variety of established models. They can then determine
all relevant parameters based on the simulations.
The researchers have already provided proof of principle, i.e. they were
able to demonstrate that the therapy works. Now initial tests are
underway on mice with a human immune system. The scientists hope that a
clinical study can begin before the year is out.
Source: Fraunhofer Institute for Cell Therapy and Immunology IZI