By Jon Palfreman on Wed, 23 Mar 2016
In 2004, the British chemist Chris
Dobson speculated that there might be a universal elixir out there that could
combat not just alpha-synuclein for Parkinson’s but the amyloids caused by many
protein-misfolding diseases at once. Remarkably, in that same year an Israeli
scientist named Beka Solomon discovered an unlikely candidate for this elixir,
a naturally occurring microorganism called a phage.
Solomon, a professor at Tel Aviv
University, made a serendipitous discovery one day when she was testing a new
class of agents against Alzheimer’s disease. If it pans out, it might mark the
beginning of the end of Alzheimer’s, Parkinson’s, and many other
neurodegenerative diseases. It’s a remarkable story, and the main character
isn’t Solomon or any other scientist but a humble virus that scientists refer
to as M13.
Among the many varieties of
viruses, there is a kind that only infects bacteria. Known as bacteriophages,
or just phages, these microbes are ancient (over three billion years old) and
ubiquitous: they’re found everywhere from the ocean floor to human stomachs.
The phage M13’s goal is to infect just one type of bacteria, Escherichia
coli, or E. coli, which can be found in copious amounts in the
intestines of mammals. Like other microorganisms, phages such as M13 have only
one purpose: to pass on their genes. In order to do this, they have developed
weapons to enable them to invade, take over, and even kill their bacterial
hosts. Before the advent of antibiotics, in fact, doctors occasionally used
phages to fight otherwise incurable bacterial infections.
To understand Solomon’s interest
in M13 requires a little background about her research. Solomon is a leading
Alzheimer’s researcher, renowned for pioneering so-called immunotherapy
treatments for the disease. Immunotherapy employs specially made antibodies,
rather than small molecule drugs, to target the disease’s plaques and tangles.
As high school students learn in biology class, antibodies are Y-shaped
proteins that are part of the body’s natural defense against infection. These
proteins are designed to latch onto invaders and hold them so that they can be
destroyed by the immune system. But since the 1970s, molecular biologists have
been able to genetically engineer human-made antibodies, fashioned to attack
undesirable interlopers like cancer cells. In the 1990s, Solomon set out to
prove that such engineered antibodies could be effective in attacking
amyloid-beta plaques in Alzheimer’s as well.
In 2004, she was running an
experiment on a group of mice that had been genetically engineered to develop
Alzheimer’s disease plaques in their brains. She wanted to see if human-made
antibodies delivered through the animals’ nasal passages would penetrate the
blood-brain barrier and dissolve the amyloid-beta plaques in their brains.
Seeking a way to get more antibodies into the brain, she decided to attach them
to M13 phages in the hope that the two acting in concert would better penetrate
the blood-brain barrier, dissolve more of the plaques, and improve the symptoms
in the mice—as measured by their ability to run mazes and perform similar
tasks.
At the time, Solomon
had no clear idea how a simple phage could dissolve Alzheimer’s plaques.
Solomon divided the rodents into
three groups. She gave the antibody to one group. The second group got the
phage-antibody combination, which she hoped would have an enhanced effect
in dissolving the plaques. And as a scientific control, the third group received
the plain phage M13.
Because M13 cannot infect any
organism except E. coli, she expected that the control group of mice
would get absolutely no benefit from the phage. But, surprisingly, the phage by
itself proved highly effective at dissolving amyloid-beta plaques and in
laboratory tests improved the cognition and sense of smell of the mice. She
repeated the experiment again and again, and the same thing happened. “The mice
showed very nice recovery of their cognitive function,” Solomon says. And when
Solomon and her team examined the brains of the mice, the plaques had been
largely dissolved. She ran the experiment for a year and found that the
phage-treated mice had 80% fewer plaques than untreated ones. Solomon had no
clear idea how a simple phage could dissolve Alzheimer’s plaques, but given
even a remote chance that she had stumbled across something important, she
decided to patent M13’s therapeutic properties for the University of Tel Aviv.
According to her son Jonathan, she even “joked about launching a new company
around the phage called NeuroPhage. But she wasn’t really serious about it.”
The following year, Jonathan
Solomon—who’d just completed more than a decade in Israel’s special forces,
during which time he got a BS in physics and an MS in electrical
engineering—traveled to Boston to enroll at the Harvard Business School. While
he studied for his MBA, Jonathan kept thinking about the phage his mother had
investigated and its potential to treat terrible diseases like Alzheimer’s. At
Harvard, he met many brilliant would-be entrepreneurs, including the
Swiss-educated Hampus Hillerstrom, who, after studying at the University of
St. Gallen near Zurich, had worked for a European biotech venture capital
firm called HealthCap.
Following the first year of
business school, both students won summer internships: Solomon at the medical
device manufacturer Medtronic and Hillerstrom at the pharmaceutical giant
AstraZeneca. But as Hillerstrom recalls, they returned to Harvard wanting more:
“We had both spent…I would call them ‘weird summers’ in large companies, and we
said to each other, ‘Well, we have to do something more dynamic and more
interesting.’ ”
In their second year of the MBA,
Solomon and Hillerstrom took a class together in which students were tasked
with creating a new company on paper. The class, Solomon says, “was called a
field study, and the idea was you explore a technology or a new business idea
by yourself while being mentored by a Harvard Business School professor. So, I
raised the idea with Hampus of starting a new company around the M13 phage as a
class project. At the end of that semester, we developed a mini business plan.
And we got on so well that we decided that it was worth a shot to do this for
real.”
In 2007, with $150,000 in seed
money contributed by family members, a new venture, NeuroPhage Pharmaceuticals,
was born. After negotiating a license with the University of Tel Aviv to
explore M13’s therapeutic properties, Solomon and Hillerstrom reached out to
investors willing to bet on M13’s potential therapeutic powers. By January
2008, they had raised over $7 million and started hiring staff.
Their first employee—NeuroPhage’s
chief scientific officer—was Richard Fisher, a veteran of five biotech
start-ups. Fisher recalls feeling unconvinced when he first heard about the
miraculous phage. “But the way it’s been in my life is that it’s really all
about the people, and so first I met Jonathan and Hampus and I really liked
them. And I thought that within a year or so we could probably figure out if it
was an artifact or whether there was something really to it, but I was
extremely skeptical.”
“Why would a phage
do this to amyloid fibers?”
Fisher set out to repeat Beka
Solomon’s mouse experiments and found that with some difficulty he was able to
show the M13 phage dissolved amyloid-beta plaques when the phage was delivered
through the rodents’ nasal passages. Over the next two years, Fisher and his
colleagues then discovered something totally unexpected: that the humble M13
virus could also dissolve other amyloid aggregates—the tau tangles found in
Alzheimer’s and also the amyloid plaques associated with other diseases,
including alpha-synuclein (Parkinson’s), huntingtin (Huntington’s disease), and
superoxide dismutase (amyotrophic lateral sclerosis). The phage even worked
against the amyloids in prion diseases (a class that includes Creutzfeldt-Jakob
disease). Fisher and his colleagues demonstrated this first in test tubes and
then in a series of animal experiments. Astonishingly, the simple M13 virus
appeared in principle to possess the properties of a “pan therapy,” a universal
elixir of the kind the chemist Chris Dobson had imagined.
This phage’s unique capacity to
attack multiple targets attracted new investors in a second round of financing
in 2010. Solomon recalls feeling a mix of exuberance and doubt: “We had
something interesting that attacks multiple targets, and that was exciting. On
the other hand, we had no idea how the phage worked.”
The
Key
That wasn’t their only problem.
Their therapeutic product, a live virus, it turned out, was very
difficult to manufacture. It was also not clear how sufficient quantities of
viral particles could be delivered to human beings. The methods used in animal
experiments—inhaled through the nose or injected directly into the brain—were
unacceptable, so the best option available appeared to be a so-called
intrathecal injection into the spinal canal. As Hillerstrom says, “It was
similar to an epidural; this was the route we had decided to deliver our virus
with.”
While Solomon and Hillerstrom
worried about finding an acceptable route of administration, Fisher spent long
hours trying to figure out the phage’s underlying mechanism of action. “Why
would a phage do this to amyloid fibers? And we really didn’t have a very good
idea, except that under an electron microscope the phage looked a lot like an
amyloid fiber; it had the same dimensions.”
Boston is a town with enormous
scientific resources. Less than a mile away from NeuroPhage’s offices was MIT,
a world center of science and technology. In 2010, Fisher recruited Rajaraman
Krishnan—an Indian postdoctoral student working in an MIT laboratory devoted to
protein misfolding—to investigate the M13 puzzle. Krishnan says he was immediately
intrigued. The young scientist set about developing some new biochemical tools
to investigate how the virus worked and also devoured the scientific literature
about phages. It turned out that scientists knew quite a lot about the lowly
M13 phage. Virologists had even created libraries of mutant forms of M13. By
running a series of experiments to test which mutants bound to the amyloid and
which ones didn’t, Krishnan was able to figure out that the phage’s special
abilities involved a set of proteins displayed on the tip of the virus, called
GP3. “We tested the different variants for examples of phages with or without
tip proteins, and we found that every time we messed around with the tip
proteins, it lowered the phage’s ability to attach to amyloids,” Krishnan says.
Virologists, it turned out, had
also visualized the phage’s structure using X-ray crystallography and nuclear
magnetic resonance imaging. Based on this analysis, those microbiologists had
predicted that the phage’s normal mode of operation in nature was to deploy the
tip proteins as molecular keys; the keys in effect enabled the parasite to
“unlock” E. coli bacteria and inject its DNA. Sometime in 2011, Krishnan
became convinced that the phage was doing something similar when it bound to
toxic amyloid aggregates. The secret of the phage’s extraordinary powers, he
surmised, lay entirely in the GP3 protein.
As Fisher notes, this is
serendipitous. Just by “sheer luck, M13’s keys not only unlock E. coli;
they also work on clumps of misfolded proteins.” The odds of this happening by
chance, Fisher says, are very small. “Viruses have exquisite specificity in
their molecular mechanisms, because they’re competing with each other…and you
need to have everything right, and the two locks need to work exactly the way
they are designed. And this one way of getting into bacteria also works for
binding to the amyloid plaques that cause many chronic diseases of our day.”
Having proved the virus’s secret
lay in a few proteins at the tip, Fisher, Krishnan, and their colleagues
wondered if they could capture the phage’s amyloid-busting power in a more
patient friendly medicine that did not have to be delivered by epidural. So
over the next two years, NeuroPhage’s scientists engineered a new antibody (a
so-called fusion protein because it is made up of genetic material from
different sources) that displayed the critical GP3 protein on its surface so
that, like the phage, it could dissolve amyloid plaques. Fisher hoped this
novel manufactured product would stick to toxic aggregates just like the phage.
By 2013, NeuroPhage’s researchers
had tested the new compound, which they called NPT088, in test tubes and in
animals, including nonhuman primates. It performed spectacularly,
simultaneously targeting multiple misfolded proteins such as amyloid beta, tau,
and alpha-synuclein at various stages of amyloid assembly. According to Fisher,
NPT088 didn’t stick to normally folded individual proteins; it left normal
alpha-synuclein alone. It stuck only to misfolded proteins, not just dissolving
them directly, but also blocking their prion-like transmission from cell to
cell: “It targets small aggregates, those oligomers, which some scientists
consider to be toxic. And it targets amyloid fibers that form aggregates. But
it doesn’t stick to normally folded individual proteins.” And as a bonus, it
could be delivered by intravenous infusion.
The
Trials
There was a buzz of excitement in
the air when I visited NeuroPhage’s offices in Cambridge, Massachusetts, in the
summer of 2014. The 18 staff, including Solomon, Hillerstrom, Fisher, and
Krishnan, were hopeful that their new discovery, which they called the general
amyloid interaction motif, or GAIM, platform, might change history. A decade
after his mother had made her serendipitous discovery, Jonathan Solomon was
finalizing a plan to get the product into the clinic. As Solomon says, “We now
potentially have a drug that does everything that the phage could do, which can
be delivered systemically and is easy to manufacture.”
Will it work in humans? While
NPT088, being made up of large molecules, is relatively poor at penetrating the
blood-brain barrier, the medicine persists in the body for several weeks, and
so Fisher estimates that over time enough gets into the brain to effectively
take out plaques. The concept is that this antibody could be administered to
patients once or twice a month by intravenous infusion for as long as
necessary.
“If our drug works,
we will see it working in this trial.”
NeuroPhage must now navigate the
FDA’s regulatory system and demonstrate that its product is safe and effective.
So far, NPT088 has proved safe in nonhuman primates. But the big test will be
the phase 1A trial expected to be under way this year. This first human study
proposed is a single-dose trial to look for any adverse effects in healthy
volunteers. If all goes well, NeuroPhage will launch a phase 1B study involving
some 50 patients with Alzheimer’s to demonstrate proof of the drug’s activity.
Patients will have their brains imaged at the start to determine the amount of
amyloid-beta and tau. Then, after taking the drug for six months, they will be
reimaged to see if the drug has reduced the aggregates below the baseline.
“If our drug works, we will see it
working in this trial,” Hillerstrom says. “And then we may be able to go
straight to phase 2 trials for both Alzheimer’s and Parkinson’s.” There is as
yet no imaging test for alpha-synuclein, but because their drug simultaneously
lowers amyloid-beta, tau, and alpha-synuclein levels in animals, a successful
phase 1B test in Alzheimer’s may be acceptable to the FDA. “In mice, the same
drug lowers amyloid beta, tau, and alpha-synuclein,” Hillerstrom says.
“Therefore, we can say if we can reduce in humans the tau and amyloid-beta,
then based on the animal data, we can expect to see a reduction in humans in
alpha-synuclein as well.”
Along the way, the company will
have to prove its GAIM system is superior to the competition. Currently, there
are several drug and biotech companies testing products in clinical trials for
Alzheimer’s disease, against both amyloid-beta (Lilly, Pfizer, Novartis, and
Genentech) and tau (TauRx) and also corporations with products against
alpha-synuclein for Parkinson’s disease (AFFiRiS and Prothena/Roche). But
Solomon and Hillerstrom think they have two advantages: multi-target
flexibility (their product is the only one that can target multiple amyloids at
once) and potency (they believe that NPT088 eliminates more toxic aggregates
than their competitors’ products). Potency is a big issue. PET imaging has
shown that existing Alzheimer’s drugs like crenezumab reduce amyloid loads only
modestly, by around 10%. “One weakness of existing products,” Solomon says, “is
that they tend to only prevent new aggregates. You need a product potent enough
to dissolve existing aggregates as well. You need a potent product because
there’s a lot of pathology in the brain and a relatively short space of time in
which to treat it.”
Future
Targets
NeuroPhage’s rise is an
extraordinary example of scientific entrepreneurship. While I am rooting for
Solomon, Hillerstrom, and their colleagues, and would be happy to volunteer for
one of their trials (I was diagnosed with Parkinson’s in 2011), there are still
many reasons why NeuroPhage has a challenging road ahead. Biotech is a brutally
risky business. At the end of the day, NPT088 may prove unsafe. And it may
still not be potent enough. Even if NPT088 significantly reduces amyloid beta,
tau, and alpha-synuclein, it’s possible that this may not lead to measurable
clinical benefits in human patients, as it has done in animal models.
But if it works, then, according
to Solomon, this medicine will indeed change the world: “A single compound that
effectively treats Alzheimer’s and Parkinson’s could be a twenty billion-dollar-a-year
blockbuster drug.” And in the future, a modified version might also work for
Huntington’s, ALS, prion diseases like Creutzfeldt-Jakob disease, and more.
I asked Jonathan about his mother,
who launched this remarkable story in 2004. According to him, she has gone on
to other things. “My mother, Beka Solomon, remains a true scientist. Having
made the exciting scientific discovery, she was happy to leave the less
interesting stuff—the engineering and marketing things for bringing it to the clinic—to
us. She is off looking for the next big discovery.”
Excerpted from BRAIN STORMS: The Race to Unlock the Mysteries of Parkinson’s Disease
by Jon Palfreman. Published by Scientific American / Farrar, Straus and Giroux,
LLC. Copyright © 2015 by Jon Palfreman. All rights reserved.
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Jon Palfreman
Jon Palfreman, PhD, is a professor emeritus of journalism at the University of Oregon who has produced several award-winning NOVA documentaries.
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http://www.pbs.org/wgbh/nova/next/body/phage-alzheimers-cure/?
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