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New Method of Gene Therapy
Alters Immune Cells for
Treatment of Advanced
Melanoma; Technique May Also
Apply to Other Common
Cancers
A team of researchers at the
National Cancer Institute
(NCI), part of the National
Institutes of Health, has
demonstrated sustained
regression of advanced
melanoma in a study of 17
patients by genetically
engineering patients’ own
white blood cells to
recognize and attack cancer
cells. The study appears in
the online edition of the
journal Science on August
31, 2006*.
“These results represent the
first time gene therapy has
been used successfully to
treat cancer. Moreover, we
hope it will be applicable
not only to melanoma, but
also for a broad range of
common cancers, such as
breast and lung cancer,”
said NIH Director Elias A.
Zerhouni, M.D.
Autologous lymphocytes — a
person’s own white blood
cells — have previously been
used to treat metastatic
melanoma. In a process
called adoptive cell
transfer, lymphocytes are
first removed from patients
with advanced melanoma.
Next, the most aggressive
tumor-killing cells are
isolated, multiplied in the
lab, and then reintroduced
to patients who have been
depleted of all remaining
lymphocytes. While
reasonably successful, this
method can only be used for
melanoma patients and only
for those who already have a
population of specialized
lymphocytes that recognize
tumors as abnormal cells.
Thus, NCI researchers, led
by Steven A. Rosenberg,
M.D., Ph.D., sought an
effective way to convert
normal lymphocytes in the
lab into cancer-fighting
cells. To do this, they drew
a small sample of blood that
contained normal lymphocytes
from individual patients and
infected the cells with a
retrovirus in the
laboratory. The retrovirus
acts like a carrier pigeon
to deliver genes that encode
specific proteins, called T
cell receptors (TCRs), into
cells. When the genes are
turned on, TCRs are made and
these receptor proteins
decorate the outer surface
of the lymphocytes. The TCRs
act as homing devices in
that they recognize and bind
to certain molecules found
on the surface of tumor
cells. The TCRs then
activate the lymphocytes to
destroy the cancer cells.
In this study, newly
engineered lymphocytes were
infused into 17 patients
with advanced metastatic
melanoma. There were three
groups of patients in this
study. The first group
consisted of three patients
who showed no delay in the
progression of their
disease. As the study
evolved, the researchers
improved the treatment of
lymphocytes in the lab so
that the cells could be
administered in their most
active growth phase. In the
remaining two groups,
patients received the
improved treatments. Two
patients experienced cancer
regression, had sustained
high levels of genetically
altered lymphocytes, and
remained disease-free over
one year. One month after
receiving gene therapy, all
patients in the last two
groups still had 9 percent
to 56 percent of their TCR-expressing
lymphocytes. There were no
toxic side effects
attributed to the
genetically modified cells
in any patient.
Approaches to increase the
function of the engineered
TCRs — including the
development of TCRs that can
bind to tumor cells more
tightly — and to further
optimize delivery methods
using retroviruses are under
investigation. In addition,
the researchers believe it
may be beneficial to further
modify lymphocytes by
inserting molecules that
assist in directing
lymphocytes to cancerous
tissues. Clinical trials are
being conducted to enhance
treatment effectiveness
using total body radiation
therapy to deplete a
patient’s supply of
non-altered lymphocytes
before replacing them with
purely engineered cells. The
researchers also have
isolated TCRs that recognize
common cancers other than
melanoma.
“We are currently treating
advanced melanoma patients
using adoptive transfer of
genetically altered
lymphocytes, and we have now
expressed other lymphocyte
receptors that recognize
breast, lung, and other
cancers,” said Rosenberg.
“These very exciting
successes in treating
advanced melanoma bring hope
that this type of gene
therapy, altering
lymphocytes, could be used
in many types of common
cancers and could be
achievable in the near
future,” said NCI Director
John E. Niederhuber, M.D. He
acknowledged Rosenberg for
his persistent and visionary
study of the role of the
immune system in the
treatment of cancer. “He is
one of the leaders we all
look to for moving us
forward,” Niederhuber said.
Skin cancer is the most
common of all cancers.
According to the American
Cancer Society, melanoma
accounts for about 4 percent
of skin cancer cases, but it
is also the most serious and
most aggressive type. In the
United States, an estimated
62,190 new cases of melanoma
will be diagnosed and
approximately 7,910 people
will die of the disease in
2006.
For more information about
cancer, please visit the NCI
Web site at http://www.cancer.gov,
or call NCI's Cancer
Information Service at
1-800-4-CANCER
(1-800-422-6237).
The National Institutes of
Health (NIH) — The Nation's
Medical Research Agency —
includes 27 Institutes and
Centers and is a component
of the U.S. Department of
Health and Human Services.
It is the primary federal
agency for conducting and
supporting basic, clinical
and translational medical
research, and it
investigates the causes,
treatments, and cures for
both common and rare
diseases. For more
information about NIH and
its programs, visit
www.nih.gov.
*Morgan
RA, Dudley ME, Wunderlich
JR, Hughes MS, Yang JC,
Sherry RM, Royal RE,
Topalian SL, Kammula US,
Restifo NP, Zheng Z, Nahvi
A, de Vries CR,
Rogers-Freezer LJ,
Mavroukakis SA, Rosenberg
SA. Cancer regression in
patients mediated by
transfer of genetically
engineered lymphocytes.
Science Express. Online
August 31, 2006.
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