RNAi Therapeutics Become Real

It’s been a long ride.

The lives of quite a few of us has been consumed now for close to two decades dreaming about a world in which RNAi Therapeutics have real-world clinical impact.  Yesterday, that dream has officially materialized.

TTR knockdown improves disease state

With the conclusion of the most comprehensive clinical study conducted to date in the severe orphan disease ATTR amyloidosis, Alnylam and investigators have found that prolonged knockdown of the causative transthyretin (TTR) gene improved both objective (mNIS+7) and subjective (quality of life) measures of the main manifestation of the disease, peripheral neuropathy.

There is no doubt that this was the result of on-target TTR gene knockdown since this was a strictly controlled study in which the only difference to the placebo group was the administration of the RNAi formulation.  Furthermore, results from a similar study for this indication (NEURO-TTR) by Ionis earlier this year in which related RNaseH antisense oligonucleotide technology was utilized for TTR knockdown also demonstrated disease benefit, albeit a ‘mere’ halt of neuropathy progression in QoL as opposed to the improvement seen here (note: mNIS+7 was reported only with regard to placebo, not versus baseline).

Importantly, this extra benefit is likely explained by the fact  that the Patisiran RNAi formulation had been shown to be slightly more potent than antisense drug candidate Inotersen in earlier-stage studies (here and here).  While considering a ~80-85% vs ~70-75% knockdown may not seem much at first glance, protein deposition, clearance and in particular misfolding that is at the root of the disease are higher-order concentration-dependent processes (think about crystallization) so a difference of ~17.5% vs ~27.5% (>50% more remaining than with Patisiran) remaining insulting protein may well be highly meaningful. 

Of note, phase II data from Patisiran have demonstrated that the ~80-85% knockdown was able to somewhat tilt the tables in favor of TTR tissue clearance, but also that it was not able to fully do so.

It is therefore of utmost importance to push forward with the development of the even more potent GalNAc-enabled RNAi candidate ALN-TTRsc02.  Preliminary phase I data from that candidate suggest that it should be able to reduce TTR levels to 5% or less with subcutaneous dosing as infrequently as every 3-6 months (Patisiran: intravenous every 3 weeks; Inotersen: weekly).

Why this is such a big deal for RNAi Therapeutics

As I had indicated in last week’s post, the phase III APOLLO results represented a make-or-break moment for RNAi Therapeutics.  If it turned out that RNAi- and delivery-related side effects were to outweigh the benefits of gene knockdown at the conclusion of this decade-long, high-visibility program, the financial markets would have reacted violently and starved the industry of the cash necessary to more fully develop the technology (Alnylam with its cash reserves at least would have mounted a comeback eventually).

If it’s one thing I’ve learned about biotech money matters over the last 15 years of riding the RNAi rollercoaster, it is that the perception of a technology is as important for its continued development as its intrinsic technological validity.

Personally, I am most relieved in that the small, but often pervasive transcriptomic off-target changes introduced by an RNAi trigger (à microRNA-type off-targeting) did not have an apparent detrimental effect on the target organ (here: liver) after prolonged, 18-months treatment.  This should not be entirely surprising based on what we’ve learned about microRNA biology- not all targets of a microRNA are biologically relevant- but is still a great relief to see play out in practice.

To wit, the RNAi industry has been overly focused on potency when selecting RNAi trigger sequences for clinical development and mostly relied on bioinformatics for specificity. Indeed, Alnylam has paid the price for this negligence in that certain RNAi triggers, such as the one for its original alpha-1-antitrypsin program, have caused liver tox most likely due to microRNA-type off-targeting.  It is therefore finally employing chemical strategies such as the incorporation of modified nucleotides in the seed region of the trigger to bias the RNAi apparatus towards RNAi cleavage instead of microRNA-type message destabilization. 

This strategy was first reported by Rosetta Inpharmatics (now Merck) and had then been developed further in the commercial realm by Marina Biotech which then licensed the IP to Roche (then acquired by Arrowhead) and possibly others. 

It will be some time until we have complete certainty that microRNA-type off-targeting won’t rear its ugly head again, but the odds should be getting better and better with the employment of best practices. More generally, Patisiran is only the beginning of a long string of real-world impactful RNAi Therapeutics.

The Wait is Finally Over

For some time now, I’ve been fascinated by how the RNAi Therapeutics sentiment cycle has been progressing in 3-year intervals.  Before I left off for my baby-break, I referred to 2014-17 as The Wait. The Wait was a reference to the ‘market’ having been convinced by early clinical data that RNAi can bring about deep and sustained gene knockdowns in WoMan, but that the ultimate clinical utility and subsequent commercial value remained to be proven.

We are now on the cusp of finding out with results from the registrational phase III study of the TTR-lowering Patisiran in familial amyloidotic polyneuropathy (FAP) imminent.

The wind is clearly in RNAi’s back with supporting developments in the related oligonucleotide therapeutics and, indeed, drug regulatory spaces.  In particular, the successful commercial launches of splice modulators EXONDYS51 (for Duchenne muscular dystrophy) and SPINRAZA (for spinal muscular atrophy) and promising phase III data from the triglyceride-lowering Volanesorsen (gene target: ApoCIII) should have removed the long-held doubt that oligonucleotides can be clinical practice-changing and profitable drugs.  And boy, are EXONDYS51 and SPINRAZA changing the clinical practice of two devastating, previously orphan diseases!

Equally important, drug regulation is strongly moving infavor of patient choice and access.  As a result, we are going to see many more drug candidates benefiting from accelerated approval pathways similar to EXONDYS51.  A number of RNAi Therapeutics programs such as Givosiran by Alnylam (àmetabolite ALA lowering as reasonably predictive endpoint) and DCR-PHXC by Dicerna (àoxalate lowering) are poised to benefit from this development.

But let’s not get ahead of ourselves and await the Patisiran APOLLO study outcome for which sponsor Alnylam has guided a ‘late September/summer’ read-out.  Drug development is full of surprises, so despite all the data* pointing towards a positive outcome, a number of variables (e.g. steroid use, lipid nanoparticle delivery) remain unknown in how they impact overall outcomes.  I for one will breathe a big sigh of relief should Patisiran be able to overcome this Make-or-Break event for RNAi Therapeutics.

 *

à positive open-label extension data from phase II Patisiran;

à positive phase III data from IONS-TTRRx targeting same gene and indication;

à the high roll-over rate into the open-label extension) indicating a positive outcome 

First RNAi Therapeutic Nearing Finish Line

ALN-TTR02 for the treatment of TTR amyloidosis is the most advanced RNAi Therapeutic in clinical development and has been carrying the torch for the field as whole. Expectations are therefore high and a stumble in this program as a result of the therapeutic hypothesis underlying the program not panning out would likely trigger a temporary*, but steep sector-wide sell-off.  

* it should be clear, however, that with the current ability to robustly knock down genes in the liver, RNAi Therapeutics will result in a number of successful treatments.

It therefore came as a relief yesterday when Alnylam presented (press release here, data slides here) 12-month data from an open-label extension phase II study of ALN-TTR02 in the polyneuropathy form of the disease (FAP) showing

a)      continued robust gene knockdowns for more than a year (88-80% reductions peak/trough in 3-week cycle);

b)      disease stabilization (if not improvement) when the Natural History of the disease would have predicted marked deterioration (predicted mNIS+7 at 12 months of +18 in Natural History vs ~-2.5 on ALN-TTR02).

Furthermore, the safety of this liposomal formulation enabled by Tekmira seemed more than sufficient for a disease as severe as FAP TTR amyloidosis (5-15 year survival following diagnosis) with the most significant adverse events being related to the intravenous route of administration meaning that ALN-TTR02 should be given under trained medical surveillance.

There are some questions that remain open, some of which should be answered by the ongoing phase III APOLLO study which should complete sometime in 2016 (with an 18 month primary endpoint).

Firstly, it will be important to show disease stabilization to be strictly related to ALN-TTR02.  In the phase II study, most patients (20 of 27) were on tetramer stabilizers which have previously shown to result in very modest (tafamidis) to moderate (diflusinal) therapeutic benefits.  While neither tafamidis nor diflusinal have shown disease stabilization after 12 months, the concern remains that they could have contributed to the apparent therapeutic benefit seen in the phase II study.

To my surprise, the 7 patients not taking tetramer stabilizers on top of ALN-TTR02 seemed to do even better, at least numerically than those taking them (-6.5+/-9.2 vs -1.1+/2.5).  Although the number was quite small, the fact that this is the opposite result from what one might have expected, it is possible that a slight placebo effect may have played a role in this open-label study: those for which ALN-TTR02 was the only medical intervention might have had a greater ALN-TTR02-driven placebo effect.

Other more complicated explanations based on TTR lowering affecting the PK/PD relationship of tetramer stabilizers are also possible if this phenomenon is for real.

Fortunately, the blinded phase III APOLLO study will compare ALN-TTR02 to patients taking no tetramer stabilizers to treat their FAP.  Finally, it would be of interest to look at the effect of ALN-TTR02 on the spleen in the APOLLO study as spleen toxicity due to lipid stability might be the most important safety parameter with chronic dosing.    

In summary, yesterday’s 12-month data removed important overhangs over the RNAi sector and we are on track for the first commercial RNAi drug in 2017. Seeing is believing.

Big De-Risking of ALN-TTR02 and SNALP Delivery Platform

Today, Alnylam reported (PR here, presentation here) first data from its phase II open-label extension study of ALN-TTR02.  ALN-TTR02 is developed for the treatment of TTR amyloidosis (FAP form) and with a phase III study underway is the industry’s lead blockbuster candidate.  There is no doubt that its results will have a big impact on the perception of the technology.   Importantly, the new data revealed at the International Symposium on Amyloidosis show that ALN-TT02 not only maintains consistent knockdown potency following multiple (>2) administrations, but even more importantly, indicate that the biggest risk, long-term safety, will not be a problem.    

Phase II promising, but with efficacy and safety questions

The new data follow on from a 2-dose phase II study (somewhat euphemistically labeled 'repeat administration) showing that ALN-TTR02 can achieve ~80% TTR knockdown levels not only following a first dose, but also following a second dose.  This was good to see because there was theoretical concern that SNALP LNPs could provoke generation of neutralizing antibodies to the PEG component which might compromise efficacy following repeat dosing.  Indeed, TTR levels seemed to return back to normal more quickly following the second compared to the first dose and was responsible for Alnylam switching from a 3-week to a 4-week dosing interval.

On the safety side, infusion-related hypersensitivity reactions are the major concern with SNALP LNP as with most other infused therapeutics, nucleic acids, protein, or small molecules alike.  While the steroid pre-treatment may have ensured that no major immune reaction was seen in the phase II study, infusion reactions had been recorded in 3 of 20 infusions at the key 0.3mg/kg dose.  Intriguingly, when a micro-dosing pre-treatment strategy was employed (increasing the length of infusion from 60 to 70 minutes) no such reactions were seen in the 18 infusions thus administered.  This is probably related to the fact that infusion reactions in general are essentially restricted to the first dose and are dose-related.

Phase II open-label extension data provide highly positive answers

In thinking about a headline for today’s blog entry ‘spectacular’ was on my mind a lot.  However, I refrained from using this term as the scientific results show very comforting consistency. 'Spectacular consistency' may be too oxymoronic.   In stock market terms, however, this consistency may very well be called ‘spectacular’ both for the much increased likelihood that ALN-TTR02 will make it across the finish line and for the safety demonstration of Tekmira’s SNALP delivery platform in general for which the major concern has always been safety, not efficacy.

Importantly, the results revealed today show that the ~80% knockdown potency is maintained following an aggregate of 119 doses of 0.3mg/kg ALN-TTR02 compared to an aggregate 38 doses before.  In the patient who has been on therapy the longest, this was the case following 9 doses over half a year.  The integrated knockdown level over time may have indeed been slightly higher than 80% since TTR levels were measured at their nadir, just before the next dose.  One can therefore conclude that the enhanced recovery from gene knockdown following the second dose did not intensify over time and that sustained and consistent knockdowns can be achieved over the long-term.

Regarding safety, just 3 instances of mild-moderate adverse events were reported in the extension phase that were deemed possibly treatment-related.  Probably only the 2 instances infusion reactions in a single subject call for attention.  Even so, none of them were deemed severe enough that the infusion rate had to be slowed as it is normally done.  The other mild-to-moderate AEs were an ‘increase of diarrhea’ and an 'impairment of taste'.  Maybe not all that bad in a disease like FAP.

Further indicative of the tolerability of ALN-TTR02, Alnylam projects 27 out of the initial 30 patients to participate in the open-label extension study.  First functional results from this OLE are expected to be reported by the end of 2014.

Disclosure: I could not resist but buy back some TKMR today based on the recognition that today’s data represent a great de-risking of the SNALP LNP delivery platform the company depends on.

Alnylam Comments Suggest SubQ Tech Failed to Achieve Efficacy Goal

At today’s Morgan Stanley Healthcare Conference, the President and COO of Alnylam, Barry Greene, told the audience to assume that it took a dose of 5 to 10mg/kg of ALN-TTRsc to achieve the 80% knockdown that had been reported in July.  This suggests that ALN-TTRsc has failed to meet the stated goal of limiting the subcutaneous injection volume to 1ml or less as this is predicted to correspond to a dose of 2.5mg/kg.

If it holds up, this would have a number of important implications.  Firstly, it would affect the profile of ALN-TTRsc itself.  I don’t believe it to be necessarily terminal in a disease like the FAC form of TTR amyloidosis for which ALN-TTRsc is being developed.  Nevertheless, squeezing 2 or even 4ml into the subcutaneous space, or alternatively administering multiple 1ml shots in one sitting, could put some needle-phobic patients off, especially as TTR amyloidosis is set to become a competitive marketplace.

Secondly, such doses would not bode well for Alnylam’s GalNac delivery platform on which the company has pinned its future.  For example, one of the big draws of the hemophilia drug candidate ALN-AT3 which is about to enter clinical development was supposed to be its subcutaneous, instead of intravenous route of administration. However, as I speculated last week (Alnylam's GalNAcs as Cholesterol-siRNA 2.0), I believe ‘GalNac-siRNAs’ have advanced somewhat since ALN-TTRsc with the addition of lipophilic moieties such as cholesterol and the jury could therefore still be out regarding the capabilities of the GalNac delivery platform.

And finally, a weak potency of ALN-TTRsc would further increase the value of competing delivery technologies, especially SNALP (Tekmira) and the subcutaneous version of DPCs (Arrowhead Research). In fact, if the full results that are to be presented in about a week at the American Heart Failure Meeting confirm the 5-10mg/kg doses, it would explain why Alnylam chose not to have ALN-TTRsc compete with and potentially replace SNALP-based ALN-TTR02. Instead, the intravenous ALN-TTR02 will likely be applied to the earlier onset, more rapidly progressing form of TTR amyloidosis (FAP), whereas the subcutaneous ALN-TTRsc will be used for the more slowly progressing, later onset form of the disease (FAC).

Alnylam Moves to Increased Dosing Frequency as Knockdown Duration Shortens

The ALN-TTR02 phase II results have finally been announced.  The results are consistent with the view that ALN-TTR02 is a strong candidate for becoming RNAi’s first marketed drug.  Having said that, the knockdown efficacy results came short of what one could have expected based on the phase I and non-human primate results and explain why the company has amended the protocol to test increased dosing frequencies.

Non-human primate studies show cumulative dosing

Alnylam had long telegraphed the results for the phase II studies.  They stated that we should expect the clinical results to be essentially the same as what they are seeing with the drug in non-human primates.  I understand that non-human primates are an immensely insightful model system in RNAi Therapeutics development.  Still, making such strong suggestions just weeks before clinical data release seemed a bit odd in that it risked stealing its own thunder.

Anyhow, the non-human primate studies showed the peak and the terminal knockdown (terminal knockdown defined as the knockdown just before repeat dosing) increased with each additional dose administration.  Whereas the peak/terminal knockdown in cycle 1 was ~85%/47% at 0.3mg/kg, they were ~90%/58% in cycle 2 and so on.  This is what Alnylam refers to as with ‘cumulative’ efficacy.

Unfortunately, this was only partially repeated in humans.

Knockdown not as sustained with repeat dosing

The ALN-TTR02 phase II study represented the first opportunity to rigorously test gene knockdown of a SNALP-delivered RNAi Therapeutic following repeat dosing.  Whereas the phase I study in healthy volunteers was a one-dose study, this phase II study was a 2-dose repeat-administration trial in European patients with TTR amyloidosis (FAP form).  In both studies, target gene knockdown could easily be determined by measuring TTR levels in the blood.

In my analysis of the data, I will stick with slide 10 of Alnylam’s slide set which seems to provide the clearest overview of the data.  At the critical 0.3mg/kg dose level, the peak knockdown either remained +/- the same (~80à80% for once-every-4-weeks) or showed evidence of cumulative activity (~80à88% for once-every-3-weeks) when comparing the first with the second dose administration.  While this looks quite good, albeit somewhat less than what was observed in the phase I study, slide 5), the downside surprise comes with the terminal knockdown values.  Here, the knockdown for cycle one (day 28; n=6) was around 75% with tight error bars, but dropped to 60% for cycle two (day 56; n=5) with much more considerable inter-patient variability.  The same was observed for the 0.15mg/kg dose level with ~53% and ~45% reductions after cycle one and two, respectively.

I have no idea where Alnylam is getting the 93% knockdown from that is so prominently mentioned in the press release.  Are they referring to a single patient that achieved such knockdown?    

Once-every-3-weeks to stay on top of competition

You can safely assume that reduced knockdown duration and the fact that the critical phosphorothioate antisense competitor by ISIS/GSK has a ~70% knockdown have driven Alnylam’s decision to amend the ongoing phase II study by including once-every-3-week regimens.

Data for the first such cohort was provided.  As noted above, once-every-3-weeks showed evidence of cumulative peak knockdown activity thus staying on top of the antisense competition.  It is a shame though that the data provided coincidentally ended on day 35, only a week before the important repeat terminal knockdown point.  It is thus not possible to tell whether diminished terminal knockdown is also an issue for the once-every-3-week regimen.

Safety findings largely related to route of administration  

Safety findings were only reported at the 0.3mg/kg level (4 events in 9 patients).  The infusion-related reaction and the 'nuisance' side effect of fever/chills are known for SNALP delivery, but do not appear to be prohibitive.   Unfortunately, there was a serious adverse event due to a misplacing of the infusion needle.  New to me is the finding of polyuria (peeing a lot). 

Based on this profile, Alnylam will try to lower the amount of immune suppression given with the drug.  Immune suppression is given as a precaution to avoid hypersensitivity reactions seen with SNALP-enabled TKM-ApoB.  It seems to me that in introducing the once-every-3-week regimen, Alnylam wants to dial up the product profile by lessening the burden of the immune suppression.

The future of ALN-TTR02

Given the high unmet medical need for FAP patients, ALN-TTR02 should remain on track of making it to the market provided reduced TTR levels indeed translate into a clinical benefit (a low risk at 80% knockdowns).  Some additional warts, however, have been added to the product profile and my main interest as to the future data will be how efficacy and safety is maintained not after just two, but after 3, 4, 5 doses and so on.  

It would also be good to find an explanation for the diminished knockdown duration (e.g. some neutralizing antibodies or a peculiarity of TTR gene regulation?).  Tekmira, the delivery partner which should receive a $5M milestone on the initiation of ALN-TTR02 phase III studies at the end of this year, would be an important ally in answering this question.  This could therefore be an important test of whether the two companies can put aside past differences.

  

The ALN-TTR02 Phase II Results...Abstract Today, Presentation Tomorrow

The abstracts for the Peripheral Nerve Society Meeting in France have been published.  The abstract on ALN-TTR02 does not reveal the results, but I post them anyway as a warm-up for tomorrow.  You can notice though that there is a relative shift towards the once-every-3-week regimen and the dose escalation started at the same point as the phase I study did (0.01mg/kg).  Check back for more tomorrow.

INTERIM RESULTS FROM PHASE II TRIAL OF ALN-TTR02, A NOVEL RNAi THERAPEUTIC FOR THE TREATMENT OF FAMILIAL AMYLOIDOTIC POLYNEUROPATHY

Adams D1, Coelho T 2, Suhr O3, Conceicao I4, Waddington-Cruz M5, Schmidt H 6, Campistol J7, Pouget J8, Buades J9, Falzone R10, Harrop J10, De Frutos R10, But- ler J10, Cehelsky J10, Nochur S10, Vaishnaw A10, Gollob J10. 1Centre Paris-Sud, APHP, Hopital de Bicetre, INSERM U788, Service de Neurologie, and Centre de Reference des Neuropathies Amyloides Familiales Le Kremlin-Bicetre, France; 2Unidade Clinica de Paramiloidose, Hospital de Santo Antonio, Porto, Portugal; 3Department of Public Health and Clinical Medicine, Umea University, Umea, Sweden; 4Centro Hospitalar Lisboa Norte-Hospital de Santa Maria, Lisbon, Por- tugal; 5Hospital Universitario Clementino Fraga Filho, Rio de Janeiro,Brazil; 6TheUniversityHospitalofM¨unster,M¨unster, Germany; 7Hospital Clinic, Barcelona, Spain; 8Centre de Ref- erencedesMaladiesNaueromusculairesetdelaSLA,Hopital de la Timone, Marseille, France; 9Hospital Son Llatzer, Palma de Mallorca, Spain; 10) Alnylam Pharmaceuticals, Cambridge, MA, USA.

Familial amyloidotic polyneuropathy (FAP) is a fatal, autosomal dominant, multi-system disease caused by abnormal tissue deposition of mutant and wild-type transthyretin (TTR). Almost all circulating TTR is synthesized by hepatocytes, and in FAP this liver-derived TTR is responsible for amyloid accumulation in the main target organs, including peripheral nerves, gastrointestinal tract and heart. Treatment approaches have focused on reduction of amyloidogenic TTR monomer either through elimination of hepatic production of mutant TTR (liver transplantation) or stabilization of the TTR tetramer (tafamidis). While both of these approaches have been shown to slow neuropathy progression in a limited subset of FAP patients with the V30M mutation and early disease, there remains a significant unmet need for new therapies that can impact FAP patients with different TTR mutations across a broader range of disease severity. ALN-TTR02 is a systemically administered lipid nanoparticle (LNP) formulation of a small interfering RNA (siRNA) targeting wild-type and all mutant forms of TTR. This formulation predominantly delivers the siRNA to the liver, thereby inhibiting synthesis of TTR at the primary site of production. In non-human primates, repetitive dosing with ALN-TTR02 every 3–4 weeks at doses up to 0.3 mg/kg resulted in an average relative TTR suppression of up to 90% with no tachyphylaxis of the pharmacodynamic effect. In a randomized, placebo-controlled, Phase I dose-escalation trial in healthy volunteers, a single intravenous infusion of ALN-TTR02 administered over 60 minutes was shown to be safe and well-tolerated, and potently suppressed serum TTR levels by 82-94% at doses of 0.15–0.5 mg/kg. TTR reduction of up to 67% was observed out to 28 days post- dose, suggesting that sustained TTR knockdown could be achieved with a monthly dosing schedule. Based on these promising results, a multi-national Phase II trial of ALN-TTR02 in FAP patients was initiated in mid-2012 to evaluate the safety/tolerability and pharmacodynamic effect of multiple doses of ALN-TTR02. Patients receive two doses of ALN- TTR02 administered every 3–4 weeks at dose levels ranging from 0.01 to 0.3 mg/kg, with a total anticipated enrollment of approximately 27 patients. In this presentation, we will provide an update on the results of this ongoing clinical trial.

Phase I Study of ALN-TTR01 in Transthyretin Amyloidosis- A Preview

(For a discussion of the phase I results, see here).

Alnylam is about to reveal results from its phase I study with ALN-TTR01 for the treatment of transthyretin amyloidosis (ATTR) at the Nov20-22 FAP meeting in Kunamoto, Japan. This blog provides a brief overview of the rational for RNAi Therapeutics in this disease and the importance of this particular study for the field of RNAi Therapeutics.

ATTR is an autosomal dominant amyloidotic disease due to point mutations (>100 possible) in the TTR gene. These mutations cause protein misfolding and aggregation into fibrils that, depending on which tissues they accumulate in, can cause various organ dysfunctions, most notably polyneuropathy (FAP), cardiomyopathy (FAC), and gastrointestinal/nutritional defects. For those that develop the disease, death is common 5-15 years following the emergence of disease symptoms (usually between 30 and 50 years of age). Although there is genotype-disease phenotype overlap, the most common mutation, Val30Met, strongly predisposes to FAP, while the Val122 is associated with FAC. About 10,000 patients suffer from FAP and 40,000 from FAC. As a rare genetic disease, it occurs in clusters, with FAP cases for example concentrated in Portugal, Sweden, and Japan.

Until recently, the only accepted treatment has been liver transplantation for FAP where removing the source of the mutant TTR in blood serum can reverse the polyneuropathy. Pfizer just got European approval for FAP with its small molecule TTR conformational stabilizer Vyndaqel based on slowing the rate of peripheral neuropathic impairment.

There exists, however, great need for additional therapies as Vyndaqel actually missed the primary endpoint in its pivotal study (the FDA did not accept the NDA for review earlier this year), and because liver transplantation is ineffective for FAC. The latter seems to be due to wildtype TTR still being able to deposit into pre-existing plaques, for example in heart tissue, at a rate that is higher than the turnover of the amyloidotic plaque. In fact, the amyloidotic potential of wildtype TTR is illustrated by the fact that it frequently causes spontaneous amyloidosis in elderly people (senile ATTR).

RNAi Therapeutics Approach to ATTR

The contribution of both wildtype and mutant to disease pathology, the dynamic turnover of plaques, and the fact that TTR knockout mice have the same life expectancy and fertility as their wildtype littermates and are otherwise essentially asymptomatic, makes RNAi Therapeutics a highly attractive treatment approach for this disease. TTR is involved in the transport of vitamin A and thyroxine in the blood, but it appears that in the absence of TTR these carrier functions are compensated for by other carrier proteins in the serum. What is more, essentially all the life-limiting pathologies are caused by TTR that is expressed in the liver, and with Tekmira’s SNALP delivery technology, RNAi can address the relevant gene expression.

TTR01 vs TTR02

One source of confusion that I expect to affect the financial markets tomorrow stems from Alnylam developing two candidates for ATTR, ALN-TTR01 and ALN-TTR02, the difference between the two candidates being in the SNALP lipid composition. TTR01 is the subject of the present trial and is based on an early DLinDMA lipid-containing formulation. It was shown to be effective in knocking down TTR in non-human primates with an ED50 of around 0.3-0.4mg/kg. As the highest dose in the phase I study was 1mg/kg it is reasonable to expect there to be evidence for TTR knockdown in the ALN-TTR01 trial. I should warn, however, that because of the small patient number in each dose cohort and the natural intra- and inter-patient variability of TTR levels in the serum, the pharmacodynamic outcome measure in this trial, the pooled numbers may not give us a straightforward 'stat-significant' answer.

Because of the rapid developments in improving the efficacy and tolerability of SNALP technology, it is therefore almost assured that Alnylam will drop TTR01 and prioritize TTR02 which takes advantage of these developments and for which the filing of an IND is imminent.

Consequently, the importance of tomorrow’s results for the RNAi Therapeutics field lies in providing proof-of-concept for RNAi knockdown following systemic delivery at OKish tolerability. That’s it. It also sets up the results from the phase I studies with ALN-PCS02, the PCSK9-targeting hypercholesterolemia candidate, which are expected to be reported by the end of this year. As PCS02 uses one of the more recent SNALP formulations, this will be the SNALP candidate that has to shine both in terms of knockdown efficacy and safety/tolerability.

ATTR Economics

If you had any doubts as to the commercial potential of ATTR, it is worth noting that Vyndaqel, Pfizer's just-approved TTR drug, is expected to be priced at more than 100,000 Euros per patient year and that most (known) FAP patients are in healthcare systems that will still bear such costs. Pfizer last year paid $200M in upfront considerations for FoldRx, the original developer of Vyndaqel, with another $200M in contingent milestones. Although FoldRx has a mission of developing other protein folding-based drugs, this price tag was essentially for a drug with results from a pivotal trial that failed to meet the primary endpoint and for which approval was far from certain. Considering Alnylam’s cash position, this one registrational drug candidate valued FoldRx higher than all of Alnylam- although you might justify that with the mounting existential risks stemming from Alnylam's alleged theft and misuse of Tekmira's SNALP technology.

Given these economics, it is not surprising that other companies have similarly recognized the commercial potential of ATTR. Importantly, ISIS Pharmaceuticals will also present progress with its antisense candidate for ATTR (ISIS-TTRRx) at the meeting. This candidate entered clinical development in May and is financed by GSK which retains an option for its exclusive license.

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