Nearly every oncologist can tell the story of
cancer patients who beat the odds, responding so well to treatment that they
continued to live many years disease-free, while most of their peers worsened
and eventually died.
Dr. David Solit decided to find out why.
Solit, an oncologist at Memorial Sloan-Kettering
Cancer Center in New York City, delved into the case of a woman with advanced
bladder cancer who volunteered for a 45-patient study of the Novartis drug Afinitor. He discovered that a combination of
two gene mutations made her particularly receptive to the treatment.
"Every other patient died, but she's without
evidence of disease for more than three years now," said Solit.
Over the past century, such patients - sometimes
called "outliers" or "super responders" - have stood out by
staging remarkable recoveries, or long-term benefit, from cancer drugs that
provide little or no help to others. Little heed has been paid to them because
there was no way to know why they fared so well. In most cases, the drugs that
helped them were abandoned because they helped too few patients.
Now, armed with huge advances in genetic sequencing
technology and growing knowledge of the genetic underpinnings of cancer, a
handful of top academic centers are taking a new look at outlier patients. The
research may lead to new uses for well-known treatments as it becomes clearer
why particular patients respond so well, or even revive drugs left for dead if
the right patient population for the treatment can be identified.
"These experiences have always been out there,
where somebody's grandmother was told she had two months to live and they tried
something and she bounced back," said Dr. Bill Hahn, an oncologist with
the Dana-Farber Cancer Institute. "But nobody ever understood why grandma
responded in such a really amazing way."
The Bethesda, Maryland-based National Cancer
Institute (NCI) and academic researchers it sponsors have just launched
"super responder" initiatives to match patients having little-known
gene mutations to drugs already shown to help others with the same mutations,
even if their tumors are for a variety of organs.
New York's Sloan-Kettering, prompted largely by
Solit's research, aims to create an "outlier" clinic devoted to
explaining exceptional responses. Other projects are underway at Houston's MD
Anderson Cancer Center and Boston's Dana-Farber.
Drugmakers are cautious, if only because they are
sufficiently busy trying to develop new medicines against some 300 identified
cancer gene mutations. With the priority on developing drugs that will help
large numbers of patients, they are reluctant, at least for now, to look
backward to salvage failed drug studies.
"We've tried to develop our drugs very
specifically so we actually develop the drug for the right population of
patients" in the first place, said Sandra Horning, a senior oncology
executive at Roche's Genentech unit.
But Harold Varmus, director of the NCI, says
drugmakers stand to benefit hugely from outlier research.
"(Drugmakers) are struggling now," Varmus
said. "They know there's a lot of genetic damage in tumors, but they don't
know which kind of genetic damage represents the best target for developing new
drugs."
GENOME SEQUENCING AS STEP ONE
Fueling the research is new technology that has
brought the cost of sequencing the human genome down from tens of millions of
dollars to about $5,000. The cost of such analysis is expected to drop to as
little as $1,000 in the next few years.
"It will be cheaper to do your whole genome
sequencing than to get an MRI scan," said Dr. Christopher Austin, director
of the National Center for Advancing Translational Sciences. "When that
happens, identifying whether a mutation is making you an exceptional responder
will be much easier."
Austin expects special-responder research will
eventually link individual gene mutations to totally different ailments beyond
cancer, allowing drugmakers to broaden the use of their medicines.
A tumor sample from Solit's patient underwent whole
genome sequencing - meaning all genes within it were analyzed for mutations, or
variations, in the repeat stretches of compounds called bases that make up the
genetic code.
"She had 17,000 mutations in her tumor that
were not found in her normal cells," Solit said. After months of analyzing
140 mutations that were considered suspects, two of them - genes named TSC1 and
NF2 - stood out.
"It was like, 'Wow,' that's why the patient
was unique, and why even though Afinitor was generally disappointing in the
bladder cancer trial, it was the right drug for her," Solit said. "It
was the combination of both mutations that probably led to her complete response,"
especially the TSC1 mutation.
Zeroing in on the two genes - among more than
20,000 human genes that make proteins - would not have been possible even five
years ago, Solit said. "Maybe we would have looked at one gene and if that
didn't show anything we'd look at another. Now we can sequence the entire
genome and look at every gene, every needle in the haystack, at the same
time."
By linking the TSC1 mutation to bladder cancer,
Solit has discovered a new "biomarker," or suspected link, to the
disease, while simultaneously identifying a possible appropriate drug for
patients with any type of cancer who have that mutation.
The next step, he said, is to develop a diagnostic
test for the TSC1 mutation and use it to screen patients being treated at his
hospital for all varieties of cancer.
"We hope by year's end to be routinely doing
TSC1 testing on large numbers of patients," Solit said. "The mutation
could be important across tumor types."
Once a small group of patients with the mutation is
identified, they would all be treated with Afinitor - which is now approved for
cancers of the breast, kidney and pancreas - regardless of the type of cancer.
"If I was sitting in a pharmaceutical firm and
I read about David Solit's case, I would say, 'Gee, this is a remarkable
change: the mutations that can be found are reasonable targets for developing
drugs,'" the NCI's Varmus said.
RESURRECTING DRUGS, FINDING NEW USES
Hundreds of drugs have been abandoned over the
years after failing clinical trials, although many had their own exceptional
responders.
Some of those drugs could be resurrected, and newer
ones could be saved, if the genetic links are established, Solit said. He sees
Roche's Avastin as a candidate for study for new, or more targeted, uses as
well.
With annual sales of more than $6 billion, Avastin
is approved to treat cancers of the colon, lung and kidney.
The U.S. Food and Drug Administration in late 2011
withdrew its approval of Avastin for breast cancer, three years after clearing
it for the condition. Subsequent research showed the drug was not effective
enough to justify its risks, even though some women had strong responses to the
medicine.
Philippe Bishop, a senior research executive at
Roche's Genentech unit, said exceptional responses have been seen in patients
taking Avastin for breast cancer and other cancers, but no specific genetic
reason has been identified.
To get a clearer picture, the company last year
started an online study called Invite, in which patients who have taken Avastin
are asked to donate a saliva sample for genetic analysis, and to complete a
survey that can help assess whether they had an exceptional response to
Avastin.
"We're trying to correlate what makes them
unique and maybe what part of their genetic makeup makes them do so well,"
Bishop said, adding that exceptional response would be defined as being alive
for a long time without their disease getting worse.
MD Anderson, meanwhile, is encouraging its doctors
to submit tumor samples from exceptional responders in past drug trials for a
detailed genetic analysis.
"We're looking at data from several dozen
trials in a variety of cancers," said senior researcher Dr. Funda
Meric-Bernstam.
She noted exceptional responders also include
patients who fare exceptionally poorly in trials, in terms of side effects or
development of drug resistance. "They are the flip side of the coin, so we
want to know why their tumor outsmarted the drug." That information could
help in designing drugs that sidestep side effects and produce more-prolonged
benefit.
Novartis, like Genentech and other drugmakers, designs its
cancer studies around patients with a single pre-identified cancer-gene
mutation.
But research chief Mark Fishman said the Swiss
drugmaker has also begun routinely sequencing tumors of the patients for
another 300 known cancer-gene mutations before they enter early-stage studies,
an extra step that could help explain eventual exceptional responses to its
drugs.
"In any given patient, if we analyze only one
gene we may not have a complete enough picture of the cancer because sometimes
you have a time bomb sitting in another gene," Fishman said. Such
interaction of cancer genes is a main reason drugs no longer work - why the
cancer recurs - after an initial period of effectiveness from a drug, he said.
Dana-Farber's Hahn said he knows of no trials that
have pulled together patients having the same gene mutation as one already tied
to a special response to a given drug. But Dana-Farber, the NCI and
Sloan-Kettering have such studies on their drawing boards, he said.
The research centers will have to work together
nationally and overseas to find patients with the shared mutations, Hahn said.
"Even if there are only one or two in individual hospitals, you can put
them together and do a trial that has a reasonable number of patients."
An NCI initiative is attempting to recover tumor
samples from exceptional responders in up to 200 U.S. drug trials it has
supported. It will sequence them to find "actionable mutations" that
can be targeted for improved treatment.
"This is an incredibly promising
opportunity," Varmus said, "for us to take advantage of our new
skills and analyze what's really wrong with the cancer cell, and figure out if
we have some ways to destroy that cell."
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