Islamabad, Feb 4 : A
report from investigators at the Massachusetts General Hospital (MGH) Cancer
Center has defined the role of a recently identified gene abnormality in a
deadly form of lung cancer. Tumors driven by rearrangements in the ROS1 gene
represent 1 to 2 percent of non-small-cell lung cancers (NSCLC), the leading
cause of cancer death in the U.S.
The researchers show that ROS1-driven
tumors can be treated with crizotinib, which also inhibits the growth of tumors
driven by an oncogene called ALK, and describe the remarkable response of one
patient to crizotinib treatment.
"ROS1 encodes a protein that is
important for cell growth and survival, and deregulation of ROS1 through
chromosomal rearrangement drives the growth of tumors," says Alice Shaw, MD,
PhD, of the MGH Cancer Center -- co-lead author of the paper which has been
published in the Journal of Clinical Oncology. "This finding is important
because we have drugs that inhibit ROS1 and could lead to the sort of dramatic
clinical response we describe in this paper."
The current findings add
ROS1 to the list of genes known to drive NSCLC growth when altered -- a list
that includes KRAS, mutations of which account for about 25 percent of cases;
EGFR, accounting for 10 to 15 percent; and ALK, rearranged in about 4 percent.
Altogether, known cancer-causing genetic changes have been found in a little
more than half of NSCLC tumors. Originally identified in brain tumors, ROS1
rearrangement previously had been identified in one NSCLC patient and one NSCLC
cell line. The current study was designed to determine the frequency of ROS1
rearrangement in NSCLC and to define the characteristics of patients with
ROS1-rearranged tumors.
The investigators screened tumor samples from
more than 1,000 NSCLC patients treated at the MGH, Vanderbilt University, the
University of California at Irvine, and Fudan University in Shanghai, China.
ROS1 rearrangement was identified in 18 tumor samples, for a prevalence of 1.7
percent; ALK rearrangements were identified in 31 samples, with no samples
showing alterations in both genes. Patients with ROS1-positive tumors tended to
be younger, never to have smoked and to have a type of lung cancer called
adenocarcinoma -- characteristics very similar to those of ALK-positive
patients.
An earlier MGH study of an experimental ALK inhibitor had found
the drug suppressed the growth of a ROS1-positive cell line in addition to
ALK-positive cell lines, suggesting that ROS1-positive tumors might be sensitive
to the ALK-inhibitor crizotinib. This observation led corresponding author John
Iafrate, MD, PhD, and his team to develop a diagnostic test that could identify
ROS1-positive tumors. Around the time that test became clinically available, a
lung cancer patient whose tumor had not responded to drugs targeting EGFR
mutations was referred to the MGH Cancer Center for genetic testing. His tumor
was negative for ALK but later proved to harbor a ROS1 rearrangement, and he was
enrolled in an extension of the crizotinib clinical trial first reported in the
October 28, 2010, New England Journal of Medicine.
"When he enrolled in
the trial last April, this patient was extremely sick -- with significant weight
loss and very low oxygen levels -- and was barely able to walk," says Shaw.
"Within a few days of starting crizotinib, he felt better; and by the time we
scanned his chest at seven weeks, the tumors had essentially disappeared from
his lungs." Nine months after starting crizotinib therapy, this patient
continues to do well. Additional ROS1-positive patients have been enrolled in
this trial at MGH, at UC Irvine and at the University of Colorado.
Shaw
is an assistant professor of Medicine and Iafrate is an associate professor of
Pathology at Harvard Medical School. Co-lead authors are Kristin Bergethon, MGH
Pathology, and Sai-Hong Ignatius Ou, MD, PhD, University of California at
Irvine. The study was supported by grants from the National Institutes of Health
and from Pfizer, which received FDA approval for crizotinib in August
2011.
Additional co-authors are Ryohei Katayama, Eugene Mark, Julie
Batten, Eunice Kwak, Jeffrey Clark, Jeffrey Engelman, and Mari Mino Kenudson,
MGH Cancer Center; Christina Siwak-Tapp, University of California at Irvine;
Keith D. Wilner, Pfizer; Christine Lovly, Nerina McDonald, Pierre Massion,
Adriana Gonzalez, David Carbone, and William Pao, Vanderbilt University Medical
Center; Pierre Massion, Nashville Veterans Affairs Medical Center; Rong Fang and
Hongbin Ji, Shanghai Institutes for Biological Sciences; and Haiquan Chen,
Shanghai Medical College, Fudan University.
Massachusetts General
Hospital, founded in 1811, is the original and largest teaching hospital of
Harvard Medical School. The MGH conducts the largest hospital-based research
program in the United States, with an annual research budget of more than $750
million and major research centers in AIDS, cardiovascular research, cancer,
computational and integrative biology, cutaneous biology, human genetics,
medical imaging, neurodegenerative disorders, regenerative medicine,
reproductive biology, systems biology, transplantation biology and
photomedicine.
Ends
SA/EN
Subscribe to:
Post Comments (Atom)
0 comments:
Post a Comment