Ave biotech investor,
morituri te salutant.
Last week, aptamer company Regado Biosciences imploded in a spectacular fashion after it had to permanently terminate a large pivotal phase III trial of its lead therapeutic program, REG1. It followed notification that an unacceptable rate of serious anaphylactic adverse events had occurred.
Aptamers are oligonucleotides that recognize their protein targets based on their 3-dimensional shape, instead of sequence complementarity as is the case with most other oligo-based mechanisms of action.
Because REG1 involves oligonucleotides and
pegylation chemistry, the event warrants the close attention of the wider oligonucleotide therapeutics
field. This blog tries to summarize what
is known about REG1 and the adverse events and aims to pinpoint potential safety landmines as well as suggest strategies to circumvent them for the benefit of ongoing and future oligonucleotide drug candidates.
REG1 a 2-component system for the tight regulation of
hemostasis
The bane of anticoagulant drug development is that too
much of it and/or inhibiting clotting at the wrong drug targets can lead to great
morbidity and death due to uncontrolled bleeding.
REG1 aims to address this catch 22 by providing an oligonucleotide-based
aptamer that binds and therefore inhibits a key regulator of the clotting cascade, Factor IXa, but with the twist that the inhibition can in turn be turned off at will by administering an antisense oligonucleotide that has sequence complementary to that of the aptamer. This disrupts the 3-dimensional shape of the aptamer thus abrogating its ability to bind Factor IXa.
The aptamer (pegnivacogin) itself consists of a heavily
modified 31mer oligonucleotide with lots of 2’-O-methyl and 2’-O-fluoro
residues (~10kDa molecular weight). However, the bulk of the drug is made of a 40kDa polyethyleneglycol (PEG) moiety appended to the 5’ end of the oligonucleotide.
The antisense oligonucleotide functioning as the antidote meanwhile is an unassuming 15mer 2’-O-methylated RNA, hardly something that would catch the eye of an oligonucleotide toxicologist.
The reason why the aptamer had been modified with PEG was to extend
its circulation half-life. What
otherwise would likely be a half-life of a few minutes for a simple 2'-O-methyl/fluoro oligonucleotide, obviously of little use for the intended regulation of blood clotting, could thereby be extended to over 24 hours when administered intravenously (à REG1) or an even more impressive ~1 week when injected subcutaneously (àREG2).
Serious allergic events in REGULATE PCI study
The REGULATE-PCI study that has just been terminated aimed to enroll
approximately 13000 (!) subjects undergoing percutaneous (through the skin)
coronary interventions (PCI) to unclog arteries around the heart. Because things tend to clot around devices
introduced into the human body and in the presence of physical stresses such as
clot disruptions, such procedures have to be performed with the concurrent use
of anti-clotting agents (anticoagulants).
The study was terminated when after about one quarter of the target enrolment (~3200), an imbalance in what the company described as ‘serious allergic adverse events’ in its
press release was noted by the body tasked with ensuring the safety of clinical
trial participants (DSMB).
Unfortunately, I was not able to retrieve a replay of the
conference call held by the company to discuss the trial termination to gather
more information on the nature of the adverse events.
It is, however, logical to assume that the serious allergic
events are the same that had already been noted in the phase II RADAR
trial. Specifically, 3 of the ~500
subjects that received REG1 had allergic reactions ‘shortly’ after infusion of the pegnivacogin aptamer, 2 of which
were considered ‘serious’ and in fact led to a stopping of the phase II trial
after it was deemed that the study already had enough statistical power. The affected patients were successfully
managed with antihistamines and steroids (Povsic et al. 2013).
Immune reactions not foreign to Oligonucleotide
Therapeutics
Immune stimulation, of course, is also the main safety risk
of Oligonucleotide Therapeutics as a class.
We are all familiar with injection site reactions, alternative
complement activations and attendant cytokine elevations, antibody generation to phosphorothioated oligonucleotides etc. Some of
them, e.g. TKM-Ebola most recently, have led to Clinical Holds or the
discontinuation of drug candidates. On
the other hand, thousands of subjects have been given oligonucleotide
therapeutics, some for years, with apparently acceptable safety profiles.
So is the
oligonucleotide component of pegnivacogin the culprit for the ‘serious’
allergic reactions?
After reviewing the data, the safety issue is unlikely due
to the aptamer itself. A naked, in this
case 2’-O-methylated, 2’-fluoro oligonucleotide alone is expected to be very
safe, at least in terms of acute toxicity.
This conclusion can be drawn for example from the administration of naked,
non-phosphorothioated oligonucleotides, including the systemic programs of
Quark Pharmaceuticals.
On the other hand, the reason for the apparent safety of unformulated oligonucleotides could
be simply because such an oligonucleotide is rapidly excreted into urine and
therefore has little chance to be toxic. This is, however, unlikely since the allergic reactions were reported to occur
shortly after drug administration, at a time when there would still be considerable concentrations of naked oligonucleotides left in circulation, therefore allowing for such a comparison.
It is interesting that only REG1 has been terminated so far,
but not REG2. Although this shoe could yet drop due to an abundance of caution, it suggests that the
serious allergic events are dependent on the intravenous route of
administration, a route of administration that is more generally plagued by immune-related ‘infusion reactions’ from small molecules to large biologics.
...enter Omontys...
This brings me to the topic of Omontys,
aka peginesatide. Omontys, of course, is a pegylated peptide that had to be withdrawn from the market
18 months ago following similar (rare) allergic events, including fatalities
due to anaphylactic shock.
Like
pegnivacogin, the pegylation in Omontys had a molecular weight of 40kDa.
Like pegnivacogin, there were both
intravenous and subcutaneous versions of peginesatide, but only the intravenous
version was associated with the severe allergies that occurred shortly after
drug administration.
Like pegnivacogin,
the allergies only occurred during the first administration of peginesatide (note: for pegnivacogin there is just 1
administration).
So taken together with the well-known hypersensitivity
often seen in response to PEG, the evidence strongly points
towards PEG as the culprit, not the oligonucleotide.
Pegylation widely used in RNAi Therapeutics
This unfortunately does not entirely exonerate
oligonucleotide therapeutics. The reason
is that pegylation is a widely used tool in the biotech industry, and within
Oligonucleotide Therapeutics, RNAi Therapeutics has made ample use of it and
promises to support advances in delivery, especially beyond the liver.
This raises the question of whether such problematic
compounds can be spotted earlier. If
not, or if the decision is to continue development, can simple allergy tests
identify the subjects that should not get the drug, or would anti-histamine
and/or steroid pre-treatment be practical and acceptable? Or is it even just a manufacturing/quality
control issue or a matter of the molecular weight of PEG? I’m sure some of
these questions sound familiar to the readers of this blog, and I expect that
the field will learn over time if and when to use these and other strategies.
As both fearlessness and fear can be fatal to drug
development and investment returns, it is worth reminding ourselves here that
numerous pegylated drugs have been approved and are being commercialized. Also, there are various degrees of allergic
events, some more serious than others.
Finally, as a former Affymax (and Lehman Brothers in case you wanted to know) investor who lost a
few feathers, I and Affymax just were incredibly unlucky.
It is my contention that Omontys would be widely used today if it had not been for the conservative market entry strategy by Omontys-distributor Fresenius Medical Care which
involved the close monitoring of the first commercial Omontys patients which picked up the very rare events.
Also, why simple strategies such as the use
of anti-histamines or just going with the subcutaneous version were not
attempted to salvage Omontys remains a mystery to me. Blame it on the damaged goods theory.
For the sake of Regado investors and medicine, let’s hope
that the parallels end here and Regado won’t follow in the footsteps of Affymax
to bankruptcy and class action lawyers.
Scripps Florida Scientists Make Diseased Cells Synthesize Their Own Drug
ReplyDeleteTargeting RNA Repeats
Myotonic dystrophy type 2, a relatively mild and uncommon form of the progressive muscle weakening disease, is caused by a type of RNA defect known as a “tetranucleotide repeat,” in which a series of four nucleotides is repeated more times than normal in an individual’s genetic code. In this case, a cytosine-cytosine-uracil-guanine (CCUG) repeat binds to the protein MBNL1, rendering it inactive and resulting in RNA splicing abnormalities that, in turn, results in the disease.
In the study, a pair of small molecule “modules” the scientists developed binds to adjacent parts of the defect in a living cell, bringing these groups close together. Under these conditions, the adjacent parts reach out to one another and, as Disney describes it, permanently hold hands. Once that connection is made, the small molecule binds tightly to the defect, potently reversing disease defects on a molecular level.
“When these compounds assemble in the cell, they are 1,000 times more potent than the small molecule itself and 100 times more potent than our most active lead compound,” said Research Associate Suzanne Rzuczek, the first author of the study. “This is the first time this has been validated in live cells.”
Given the predictability of the process and the nearly endless combinations, translating such an approach to cellular systems could be enormously productive, Disney said. RNAs make ideal targets because they are modular, just like the compounds for which they provide a molecular template.
Not only that, he added, but many similar RNAs cause a host of incurable diseases such as ALS (Lou Gehrig’s Disease), Huntington’s disease and more than 20 others for which there are no known cures, making this approach a potential route to develop lead therapeutics to this large class of debilitating diseases.
http://www.scripps.edu/news/press/2014/20140902disney.html