Pharma Strategy Blog

Commentary on Pharma & Biotech Oncology / Hematology New Product Development

The 2012 American Association for Cancer Research (AACR) meeting in Chicago was interesting for several reasons.  While there were no truly ground breaking data such as in previous years as with, for example:

  • vemurafenib in BRAFV600E melanoma
  • vismodegib in basal cell carcinoma (BCC)
  • crizotinib in ALK+ lung cancer

there were a lot of encouraging signs for the future.

What made the meeting exciting for me was the sheer number of new compounds emerging from late preclinical to early phase I – clearly companies are looking to restock their pipelines with the threat of major patent cliffs imminent.  Not everyone is chasing new compounds to license in!  The sheer breadth and depth of the pathways targeted by the new compounds took me a little by surprise.

It was clear from discussions with numerous new product people that while pipeline boards are starting to look a little healthier than of late, many of the new compounds are not yet public, but effort are being made to expedite these into the clinic too. Roche and Novartis have dominated the oncology landscape of the last few years but there were signs of resurgence from old stalwarts such as GSK, Lilly, Pfizer, Amgen and Merck. Such fierce competition is good to see.

Posters from Day 2 at AACR...

The small biotechs were also showcasing some interesting data and over the rest of this week, I’ll be highlighting some of the ones I liked and also explaining some of the new targets and biomarkers that caught my eye.

There was, however, a noticeable dearth of handouts and QR codes (for the PDFs) in the poster sessions this year, necessitating more requests for copies by email, hence the delay in covering the highlights post conference.

I’m pleased to say, however, that many presenters generously shared their poster offline and some of these will be discussed later this week.

Here are some of the topics I’m going to be covering in more detail:

  • Update on the PI3K-AKT-mTOR and RAS-RAF-MEK pathways
  • New targeted agents in late preclinical and phase I development
  • Review of the Science Policy session on regulatory and clinical challenges in new drug approvals
  • Update on new approaches in colorectal, prostate and lung cancers

Check back PSB daily this week for more detailed analyses and insights…

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Today marks the kick off for one of my favourite conferences on the oncology-hematology calendar, with the annual meeting of the American Association for Cancer Research (AACR) being held in Chicago.  It’s all about the science and basic research here, although there are clinical sessions, usually on strategy and early emerging phase I/II data.

Wifi is usually pretty good at the AACR annual meeting, although it can be more variable at the smaller meetings.  Like many attendees, wifi permitting, I’ll be tweeting from the conference and blogging some of the interesting highlights over the next few days.

For those interested, you can follow the Twitter chatter using the conference hashtag #aacr from attendees and non-attendees alike, by clicking on the widget below:

AACR have a strong web and social media presence as well as webcasts of sessions (some free, some paid), thanks to the sterling efforts of Ron Vitale and his web team, who do a fantastic job.

They also have iPad/iPhone or Android apps for those interested in looking at the program on the go and an abstract app as well.  After all, what use is a CD-rom of the abstracts if you’re running around McCormick place with a mobile device?  These days, most conferences, I don’t even take a laptop anymore, so a CD is pretty useless with an iPad or tablet!

One of my favourite tools last year was the video app, which offers selections of short interview of some of the presenters giving the highlights of their talks or findings.  This is a great idea for getting key points out on topics of interest.

Huge doorstop abstract/reference books, CD-Roms and flash keys/memory sticks will soon be a thing of the past.  I confess to being a huge big fan of reading the program as a PDF, so that it can be easily read and bookmarked in iBooks, on a plane, bus, or while running round the poster halls.

All of these digital tools are much more practical and user-friendly – tailored towards the typical on-the-go use by attendees and I sincerely wish more conferences would follow AACR’s lead and move over to the web 2.0 world in this fashion.

The conference runs through Wednesday, so do check back daily for the Twitter updates and we’ll be blogging anything interesting either here on PSB (follow @maverickny) or on Biotech Strategy Blog (follow Pieter Droppert, @3NT).

 

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One of the biggest challenges facing cancer research was aptly summarised by Levi Garraway and Pasi Jänne in this month’s Cancer Discovery journal:

“All successful cancer therapies are limited by the development of drug resistance. The increase in the understanding of the molecular and biochemical bases of drug efficacy has also facilitated studies elucidating the mechanism(s) of drug resistance.”

It will therefore come as no surprise to PSB readers that resistance occurs with two drugs approved by the FDA only last year; vemurafenib (BRAFV600E melanoma) and crizotinib (ALK+ lung cancer). We’ve discussed the development of resistance in melanoma here via several potential mechanisms in the past and potential strategies for overcoming them (eg MEK inhibitors), but what about lung cancer?

Two recently published papers have shed some new light on this topic. Doebele et al., (2012) and Katayama et al., (2012) both looked at mechanisms of resistance associated with ALK-rearranged lung cancers.

What did the research show?

Both of these papers were published in March, but in separate journals.

Doebele et al., (2012) examined mechanisms of ALK resistance in EML4-ALK–positive non-small cell lung cancer (NSCLC) patients who had progressed while on crizotinib patients (n=11). The essence of their findings were as follows:

  • Four patients (36%) developed secondary mutations in the tyrosine kinase domain of ALK. Two of the patients exhibited a novel mutation in the ALK domain, encoding a G1269A amino acid substitution that confers resistance to crizotinib in vitro.
  • Two patients, including one with a resistance mutation, exhibited new onset ALK copy number gain (CNG).
  • One patient showed epidermal growth factor receptor (EGFR) mutant activity, without evidence of a persistent ALK gene rearrangement.
  • Two patients had a KRAS mutation, one of which occurred without evidence of persisting ALK gene rearrangement.
  • One patient showed the emergence of an ALK gene fusion–negative tumour with no identifiable alternate driver.
  • Two patients retained ALK positivity, with no identifiable resistance mechanism.

Meanwhile, Katayama et al., (2012) attempted to characterise acquired resistance, i.e. the adaptive resistance that occurs in response to treatment with a TKI. They also took biopsies from patients (n=18) with EML4-ALK–positive (NSCLC) patients who had progressed while on crizotinib. They found that in approximately a a quarter to a third of patients (22% to 36%) multiple mutations were found after sequencing of the ALK kinase domain exons. This resulted in amino-acid substitutions or insertions that are predicted to impair crizotinib binding. When this happens, the drug stops working and patients will relapse on therapy.

More specifically, there were:

  • Five patients (28%) had tumours with alterations in the ALK gene that were the underlying cause of the resistance.
  • There were four different somatic mutations within the ALK gene.
  • One case where the ALK gene was amplified.
  • One ALK mutation was highly resistant to all of the inhibitors examined.

In addition, they observed evidence of alternative mechanisms of resistance evolving, including activation of EGFR and KIT.

What do these results mean?

Firstly, it is striking that there are so many potential escape routes and mechanisms of adaptive resistance to crizotinib therapy.

Secondly, as Garraway and Jänne noted:

“Increased knowledge of drug resistance mechanisms will aid in the development of effective therapies for patients with cancer.”

However, while this is a true and accurate statement, I am left wondering how this might play out in clinical practice? By that, I mean how does a community medical oncologist, who sees the bulk of NSCLC patients go about incorporating this information? For now they can’t, as we are awaiting the results of numerous clinical trial readouts – hopefully there will be some at the annual ASCO meeting in June.

The sheer breadth of the heterogeneity also raises the issue of how will community doctors be able to process all this complex information and select patients for appropriate combination therapies based on numerous potential mechanisms of resistance. Biopsies aren’t always practical in these situations, but perhaps we may see the development of alternative methods of detection evolve in the future.

References:

ResearchBlogging.orgGarraway, L., & Janne, P. (2012). Circumventing Cancer Drug Resistance in the Era of Personalized Medicine Cancer Discovery, 2 (3), 214–226 DOI: 10.1158/2159–8290.CD–12–0012

Doebele, R., Pilling, A., Aisner, D., Kutateladze, T., Le, A., Weickhardt, A., Kondo, K., Linderman, D., Heasley, L., Franklin, W., Varella-Garcia, M., & Camidge, D. (2012). Mechanisms of Resistance to Crizotinib in Patients with ALK Gene Rearranged Non-Small Cell Lung Cancer Clinical Cancer Research, 18 (5), 1472–1482 DOI: 10.1158/1078–0432.CCR–11–2906

Katayama, R., Shaw, A., Khan, T., Mino-Kenudson, M., Solomon, B., Halmos, B., Jessop, N., Wain, J., Yeo, A., Benes, C., Drew, L., Saeh, J., Crosby, K., Sequist, L., Iafrate, A., & Engelman, J. (2012). Mechanisms of Acquired Crizotinib Resistance in ALK-Rearranged Lung Cancers Science Translational Medicine, 4 (120), 120–120 DOI: 10.1126/scitranslmed.3003316

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The big cancer news that hit the news wires this morning was not entirely surprising:

“Janssen Research & Development, LLC today announced that it has unblinded the Phase 3 study of ZYTIGA (abiraterone acetate) plus prednisone for the treatment of asymptomatic or mildly symptomatic patients with metastatic castration-resistant prostate cancer (CRPC) who have not received chemotherapy.”

Source: Press Release

Given the accelerated approval of abiraterone in the post-chemotherapy setting last year, the results in the pre-chemotherapy setting were widely expected to:

  1. Be even better in earlier stage than the 3.9 months OS advantage already seen
  2. Likely to have an early study halt

Zytiga already has Compendia listing through mention in the NCCN Guidelines with level 2a evidence in the pre-chemotherapy setting, essentially listed with ketoconazole.  Several industry friends with access to market data have mentioned that the pre-chemotherapy share for abiraterone is already around 20-25%, not bad at all given it doesn’t have full approval prior to docetaxel use and has been on the US market less than a year.

No clinical details were provided by the Data Science Monitoring Committee (DSMC), but the data are expected to be presented at a clinical meeting later this year (Adam Feuerstein of The Street speculated that ASCO was a likely target).  I do hope so, but that would suppose an abstract was sent in with no data by the late breaking deadline of Feb 1st.

The company did state that:

“The company plans to submit for regulatory approval in the United States and around the world beginning in the second half of 2012.”

At this rate, J&J should receive the new indication in the first half of 2013, based on the 302 trial data, depending on whether the filing is accepted as an accelerated, priority or regular review.  No doubt this information will be apparent after filing has taken place.

One challenge with early stoppage of trials based on progression-free survival (PFS) is that determining whether patients truly live longer, as judge by overall survival (OS), becomes much more difficult, if not impossible.  Once patients on placebo are offered the active drug, there is a crossover effect confounding any subsequent data analysis.

The news today will impact several other companies in the advanced prostate cancer landscape

Medivation and Astellas are expected to file MDV3100 in the post chemotherapy setting soon based on the phase 3 AFFIRM study.  This agent has several attractive advantages over abiraterone in that:

  • no concomitant prednisone or steroid administration is required (hence less puffiness and related side effects) and
  • it targets splice variants as well as the AR, which may lead to less drug resistance.

Based on the post-chemotherapy data we’ve seen so far (MDV3100 saw a slightly longer improvement in OS, which may be related to the above), we can expect that the phase III PREVAIL trial prior to docetaxel to also show a similar trend to the Zytiga study.  It won’t surprise me at all if the interim analysis also leads to the DSMC recommending early unblinding.  Based on the Zytiga data, it wouldn’t surprise me if the interim analysis for MDV3100 came up as early as mid next year, which would be earlier than expected.

Two drugs that will be impacted by these developments with hormonal agents are Dendreon’s Provenge, which is approved prior to docetaxel and Sanofi’s Jevtana (cabazitaxel), which is approved after docetaxel.

The immunotherapy sipuleucel-T (Provenge) is an unlikely partner for combination with abiraterone given that steroids suppress the immune system, while many older men with metastatic would much rather take a pill than undergo the debilitating side effects of myelosuppressive cytotoxics such as the taxanes.  Certainly my Dad was in that category, as are many men in their 70’s.  Once approved, Alpharadin (radium-223) may well offer a useful option for that subset of patients, especially of they have already tried ADT and seen biochemical relapse with rapidly rising PSA levels.  Provenge is likely to be negatively impacted by Zytiga approval pre-chemotherapy.

Approval of Zytiga in the pre-chemotherapy setting will likely increase its share there, since many oncologists are somewhat sceptical about Provenge in terms of how it works, how effective it is, how to monitor patient progress on it (it doesn’t seem to affect pain, PSA or any of the usual markers of disease) and the hefty price tag ($93K for 3 infusions) doesn’t help either.  MDV3100 would likely have an even stronger impact, since urologists dislike using steroids and managing the complications, plus Astellas have a solid franchise in urology already.

At this rate, Jevtana will be pushed further out down the treatment paradigm and reserved for salvage therapy in the younger, fitter patients.  Its biggest challenge is competing with it’s fellow taxane, docetaxel, since many oncologists will re-challenge with the generic if the patient previously did well on it.  Any delay (through improved survival with newer, earlier treatments) will delay time to cabazitaxel uptake.  This will likely get worse once MDV3100 is approved, and oncologists can sequence them.

At what point will we see placebo trials go away?

I’m not a big fan of placebo-controlled trials, except where there are no standard of care or alternative clinical options for patients.  Until recently, the advanced prostate cancer market was relatively immature with few approved therapies, so placebo trials were de rigeur.  Going forward though, new entrants to the market will face the ethical dilemma of how can placebo-controlled trials be justified in a market where drugs such as abiraterone (or MDV3100 and Alpharadin, if approved) have a proven survival advantage?  It will push the bar for new market entries higher (and more costly).  Millennium’s TAK-700 (orteronel), which is similar to abiraterone but may or may not need steroids, may well have just made it into clinical trials in time before that window shuts off.

And finally…

The good thing is that after a decade of not much happening in the advanced prostate cancer market, we are seeing a lot if new therapies, often with different mechanisms of action, being developed for this disease.  There are others I haven’t mentioned here, including custirsen (Oncogenex) and cabozantinib (Exelixis) which are also undergoing clinical trials and we await those results too.

As more drugs for castrate-resistant prostate cancer (CRPC) are approved, sequencing and combinations will also come to the fore to determine optimal strategies for improving outcomes for men with prostate cancer.  It’s an exciting market to be following given the rapid progress over the last year or so, but hopefully, this is just the beginning and there will be much more yet to come.

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Cancer metabolism is fast becoming an area to watch out for in R&D.  Last month I tweeted that I was attending a one day meeting at NY Academy of Sciences on Cancer Metabolism with keynote speakers Drs Lou Cantley and Craig Thompson. Jonathan Mandelbaum (@biotechbaumer) responded saying it looked like a dress rehearsal of another related meeting he was attending the following week. That was too good an opportunity to miss, so I invited Jonathan to consider guest posting a summary of the Keystone event he attended here on Pharma Strategy. I’m delighted to say he kindly took me up on the offer and what follows is Jonathan’s synopsis, including some references he chose to illustrate the key points, most of which are open access.

Jonathan has the honour of being the first formal guest post from an industry scientist, although the first informal one went to Al Lalani, Ph.D of Regeneron, who sent in an excellent and very amusing summary of last year’s ASCO abstracts.  The original guest post was from an industry analyst, Adam Bristol, Ph.D.

I hope to post more guest blogs here from scientists going forward, as they add variety and different perspectives on the evolution of the cancer R&D process.

Jonathan Mandelbaum

To give you all some brief background, Jonathan is currently a postdoctoral fellow at Millennium Pharmaceuticals, Inc. based in Cambridge, MA. He received his Ph.D. in Cellular, Molecular and Biophysical Studies from Columbia University. His thesis focused on understanding the functional consequences of recurrent genetic lesions in human diffuse large B-cell lymphoma. Prior to Columbia University, he obtained his Bachelor of Science from McGill University in Montreal, Canada and spent his summers as a research student at the Campbell Family Institute for Breast Cancer Research within the Ontario Cancer Institute.


The 2012 Keystone Symposia on Cancer and Metabolism was a hot meeting, albeit in the cold mountains of Banff, Canada. Research into how cancer cells rewire their metabolism to cope with increased energetic and biosynthetic demands has been reinvigorated in recent years, in large part due to several prominent researchers that were featured at the meeting, such as Craig Thompson, Lou Cantley, Reuben Shaw and David Sabatini.

Talks and posters from Agios Pharmaceuticals, Inc., Novartis, Pfizer and Millennium Pharmaceuticals, Inc., provided additional insight into how industry is thinking of translating these latest findings into novel therapeutics. Without getting into much detail (since much of the data remains unpublished), I will summarize some main themes of the conference and takeaway thoughts on future directions for drug discovery.

Central to the conference is the observation known as the Warburg effect, identified by Otto Warbug in 1924. Essentially, Warburg saw that cancer cells, despite being flush with oxygen, rely on aerobic glycolysis for their energy needs, resulting in an excess production of lactate. This phenomenon is common to normal proliferating cells, however, cancer cells have deregulated this process in part through activation of various oncogenic pathways (eg. PI3K, RAS-MAPK) and reliance on the M2 isoform of Pyruvate Kinase (PKM2) (see review by Vander Heiden et al., 2009). Many talks focused on how oncogenic activation of these pathways regulates the activity of different metabolic pathways (eg. glycolysis, the pentose phosphate pathway shunt, amino acid metabolism). For example, it’s known that cells transformed with MYC are dependent on glutamine metabolism for their survival (see Wise et al., 2008).

Is this metabolic rewiring simply an epiphenomenon of oncogene activation or is it truly important for tumorigenesis? Interestingly, mutations in several different metabolic enzymes have been found in certain cancers.  Fumarate Hydratase (FH) and Succinate Dehydrogenase (SDH), enzymes important for the TCA cycle, are inactivated by mutations in rare forms of cancer, implicating mitochondrial dysfunction in these tumors.  Additionally, recurrent gain-of-function mutations in isocitrate dehydrogenase (IDH1/2) have been found in a variety of tumor types, such as glioma and AML.  Most recently, PHGDH, an enzyme important for serine metabolism, was suggested to be the target of a locus recurrently amplified in melanoma (Locasale et al., 2011).

Several talks discussed how these mutations might be important for tumorigenesis. For example, FH-deficient renal tumors have a deregulated anti-oxidant response through activation of the Nrf2 transcription factor (Adam et al., 2011).  The authors suggest that increased fumarate in these cancer cells can promote a post-translational modification of proteins called succination, which can affect protein function.  Gain-of-function mutations in IDH1/2 result in excessive production of the metabolite 2-HG (Dang et al., 2009), which can inhibit the activity of histone demethylases, thus affecting the epigenetic regulation of gene expression (Figueroa et al., 2010).  At least for FH and IDH driven tumors, the common thread appears to be that metabolites can play critical roles in regulating a multitude of cellular processes outside of metabolism itself.

How might this basic research be translated into novel therapeutics?

Two obvious drug targets I mentioned, IDH1/2 and PKM2, are in fact drug programs being pursued by Agios Pharmaceuticals, Inc.  IDH1/2 presents an intriguing opportunity as the mutations are gain-of-function; drugs that can specifically target the mutant protein, akin to imatinib and vemurafinib, might be effective cancer therapeutics.

Although I did not discuss this topic, the autophagy pathway was another focus for several talks at the meeting. As this pathway is important for cells to cope with metabolic stress, and cancer cells face challenges such as hypoxia and nutrient deprivation, targeting autophagy might be a beneficial therapeutic strategy for cancer treatment.

Ultimately, understanding how different genetic dependencies in cancer reprograms cells to be specifically reliant on certain metabolic pathways, might provide synthetic lethal opportunities for drugs that target metabolic enzymes in those pathways.

From a drug discovery perspective, the conference highlighted for me two critical challenges going forward:

  1. What therapeutic window might exist for drugs targeting metabolic pathways? Jeff Rathmell emphasized an important observation that activated lymphocytes are dependent on glycolysis, similar to cancer cells, for their survival. Thus, agents targeting glycolysis might very well have immunological side effects.
  2. Many talks highlighted the plastic and redundant nature of metabolic pathways. Inhibiting one pathway can lead to adaptive flux through another pathway, or even drive metabolic enzymatic reactions in reverse, in order to compensate for that initial block. Understanding and overcoming these pathway redundancies (somewhat similar to the current state of signal transduction drug discovery) will be a key challenge going forward for cancer metabolism translational research.

Jonathan Mandelbaum is currently employed at Millennium Pharmaceuticals, Inc. The views expressed in this article are his own opinion and are not shared by his employer.

References:

ResearchBlogging.orgVander Heiden MG, Cantley LC, & Thompson CB (2009). Understanding the Warburg effect: the metabolic requirements of cell proliferation. Science (New York, N.Y.), 324 (5930), 1029-33 PMID: 19460998

Wise DR, DeBerardinis RJ, Mancuso A, Sayed N, Zhang XY, Pfeiffer HK, Nissim I, Daikhin E, Yudkoff M, McMahon SB, & Thompson CB (2008). Myc regulates a transcriptional program that stimulates mitochondrial glutaminolysis and leads to glutamine addiction. Proceedings of the National Academy of Sciences of the United States of America, 105 (48), 18782-7 PMID: 19033189

Locasale JW, Grassian AR, Melman T, Lyssiotis CA, Mattaini KR, Bass AJ, Heffron G, Metallo CM, Muranen T, Sharfi H, Sasaki AT, Anastasiou D, Mullarky E, Vokes NI, Sasaki M, Beroukhim R, Stephanopoulos G, Ligon AH, Meyerson M, Richardson AL, Chin L, Wagner G, Asara JM, Brugge JS, Cantley LC, & Vander Heiden MG (2011). Phosphoglycerate dehydrogenase diverts glycolytic flux and contributes to oncogenesis. Nature genetics, 43 (9), 869-74 PMID: 21804546

Adam J, Hatipoglu E, O’Flaherty L, Ternette N, Sahgal N, Lockstone H, Baban D, Nye E, Stamp GW, Wolhuter K, Stevens M, Fischer R, Carmeliet P, Maxwell PH, Pugh CW, Frizzell N, Soga T, Kessler BM, El-Bahrawy M, Ratcliffe PJ, & Pollard PJ (2011). Renal cyst formation in Fh1-deficient mice is independent of the Hif/Phd pathway: roles for fumarate in KEAP1 succination and Nrf2 signaling. Cancer cell, 20 (4), 524-37 PMID: 22014577

Dang L, White DW, Gross S, Bennett BD, Bittinger MA, Driggers EM, Fantin VR, Jang HG, Jin S, Keenan MC, Marks KM, Prins RM, Ward PS, Yen KE, Liau LM, Rabinowitz JD, Cantley LC, Thompson CB, Vander Heiden MG, & Su SM (2009). Cancer-associated IDH1 mutations produce 2-hydroxyglutarate. Nature, 462 (7274), 739-44 PMID: 19935646

Figueroa ME, Abdel-Wahab O, Lu C, Ward PS, Patel J, Shih A, Li Y, Bhagwat N, Vasanthakumar A, Fernandez HF, Tallman MS, Sun Z, Wolniak K, Peeters JK, Liu W, Choe SE, Fantin VR, Paietta E, Löwenberg B, Licht JD, Godley LA, Delwel R, Valk PJ, Thompson CB, Levine RL, & Melnick A (2010). Leukemic IDH1 and IDH2 mutations result in a hypermethylation phenotype, disrupt TET2 function, and impair hematopoietic differentiation. Cancer cell, 18 (6), 553-67 PMID: 21130701

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Back in 2009 at the American Association for Cancer Research (AACR) Molecular Targets meeting, a researcher (Anirban Maitra) from Boston had a most interesting poster about the use of nanotechnology to deliver nab-paclitaxel (Abraxane) to pancreatic adenocarcinomas in a more targeted fashion.  You can read about it in more detail from the meeting coverage at that time.

Essentially, one of the things that stops chemotherapy being more effective in advanced pancreatic cancer is that the stromal layer forms a physical, almost impenetrable layer, that slows drugs from getting through to the tumour.

Using nanotechnology, the MIT researchers were able to direct nab-paclitaxel to the stromal layer more effectively, wiping it out and allowing subsequent gemcitabine to be more effective in their animal models.

Fast forward two years and there has been a new paper in Cancer Discovery by a different group (see Frese et al., (2012) from the University of Cambridge in the references) looking at the mechanistic role of nab-paclitaxel in pancreatic adenocarcinomas.

Their findings were as follows:

  • Combination of nab-Paclitaxel and gemcitabine causes tumour regression and reduces metastasis
  • Treatment with nab-Paclitaxel targets tumour epithelial cells
  • nab-Paclitaxel promotes elevated intratumoural gemcitabine levels
  • nab-Paclitaxel decreases cytidine deaminase protein levels

Taken together, the authors concluded that, mechanistically:

“Paclitaxel reduced the levels of cytidine deaminase protein in cultured cells through reactive oxygen species–mediated degradation, resulting in the increased stabilization of gemcitabine.

Our findings support the concept that suboptimal intratumoral concentrations of gemcitabine represent a crucial mechanism of therapeutic resistance in PDA (pancreatic ductal adenocarcinoma) and highlight the advantages of genetically engineered mouse models in preclinical therapeutic trials.”

In an AACR press release, the leader author, David Tuveson, was quoted as saying:

“We predict from this mechanistic study that nab-paclitaxel may be most effective if we administer it first, and delay administration of the gemcitabine. The next step is to test this prediction, since it could help a great deal with patient treatment.”

Based on the earlier Boston research in 2009, I think that this sequencing approach makes logical sense, because the nab-paclitaxel will wipe out the stromal layer and create an opportunity for the subsequent gemcitabine infusion (or other therapy) to be more effective.

What are significance of these findings?

Firstly, there are a number of trials ongoing in pancreatic cancer, including a phase III trial of gemcitabine plus nab-paclitaxel, which is expected to mature next year. Based on the promising interim data, I’m hopeful that this combination may move the needle in terms of improved survival (as measured by OS) for patients with this devastating cancer.

More recently, Infinity reported that their phase II trial with their Hedgehog inhibitor (saridegib) plus gemcitabine was stopped for futlity. I wasn’t surprised to hear this based on the 2009 data mentioned above, because without blasting out the stromal layer, neither the TKI nor gemcitabine can impact the tumour cells effectively. Another Hedgehog inhibitor, vismodegib (Genentech/Roche) is being evaluated in a triple combination trial with gemcitabine and nab-paclitaxel. I like this trial design a lot better, but we will have to see whether sequencing is also important, as shown in this latest research, ie nab-paclitaxel first, followed by gemcitabine (plus the Hedgehog inhibitor).

All in all, Frese et al., (2012) provide novel insights into the antitumour activity of nab-paclitaxel. They also offer a potential mechanism for improving gemcitabine delivery to pancreatic tumours that deserves research in the clinical setting. This more targeted smart approach to trial design may well yield improved results in the clinic, rather than the old method of throwing random doublets and triplets at the (tumour) wall hoping something will stick.

References:

ResearchBlogging.orgFrese, K., Neesse, A., Cook, N., Bapiro, T., Lolkema, M., Jodrell, D., & Tuveson, D. (2012). nab-Paclitaxel Potentiates Gemcitabine Activity by Reducing Cytidine Deaminase Levels in a Mouse Model of Pancreatic Cancer Cancer Discovery DOI: 10.1158/2159-8290.CD-11-0242

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Amazingly, it’s been a year since I started doing conference highlight videos, with the first one rolling out at EAU meeting in Vienna last March. They’ve proven to be much more popular than expected! The good news is that the video recording, production and presentation skills have improved along the way.

Unlike last year, the 2012 EAU Congress wasn’t lit up with excitement about new data (abiraterone and MDV3100 dominated last year).  Instead, there were more reflective discussions about how to consider sequencing and combinations in a more crowded castrate resistant prostate cancer market going forward as well as some mention of new up and coming targets outside the androgen receptor (AR) such as ERG and Src.

Here’s the short (under 5 mins) video update:

If you can’t see the video, click here.

Meanwhile, the next conference update will be from the annual American Association for Cancer Research (AACR) meeting from March 31st-April 4th.

I don’t do this very often, but here’s a worthy cause for scientists and cancer researchers to rally around – Dr Steven Meltzer at Johns Hopkins established an online petition to the White House to increase funding to the NIH – the current proposal is to maintain the budget at a flat $30.7 billion.

Supporting the petition taught me something interesting – NIH funding created 350,000 jobs and contributed $50 Billion to the national economy in 2007 alone.

The problem, though, with flat budgets is that every 7 years the value of money halves, so the NIH budget has essentially been decimated over the last decade. This is sad for science, for progress and also for patients.

I was signature 7K odd, but this week has already seen an influx in new supporters that now rank nearly 10.5k strong, which is great progress.  Please take a moment to help support science and research – every vote counts!

Here’s the link to the White House NIH petition.

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Arc de Triomphe, Paris

Scenes from EAU - Arc de Triomphe

Here at the European Association of Urology (EAU) congress in Paris, there are some interesting debates amongst delegates attending the meeting regarding new therapies either recently – or about to be approved – for castrate-resistant prostate cancer (CRPC).

For example:

  1. How should abiraterone and MDV3100 be sequenced pre or post chemotherapy?
  2. Would combining the two drugs post chemo be a better strategy that leads to superior outcomes?
  3. Where does chemotherapy fit into this emerging paradigm?  Do we need chemotherapy in an new era of oral therapies?  If yes, which patients should be considered eligible?
  4. How will immunotherapies such as Provenge be used once approved – before or after abiraterone in the pre-chemo setting, but likely not together given the steroid component?

Reimbursement remains a challenge in Europe

Now, these are all valid clinical questions, but there is an elephant in the room that isn’t being discussed so far (Dendreon got a lot of stick over the US price last year, which was publicly considered ‘very expensive’ or ‘too expensive’ by many thought leaders for Europe), namely, reimbursement.

Consider that the US wholesale price for Provenge is $93K and abiraterone is ~$48K, depending on how many months are needed (likely more in the pre-chemotherapy setting), you can already see that both sequencing and combinations are going to take the economic costs much higher for European health care systems.  That’s without figuring in the price for MDV3100 and Alpharadin, which have not been filed yet or cabazitaxel, which costs around $42K in the US depending on the number of cycles taken (from memory).

However, with Taxotere now generically available, it’s not hard to imagine many centres repeating docetaxel in second-line if the patient had a good response rather than administer the more expensive cabazitaxel.  In general, though, there is little doubt that the impact of either sequencing therapies, or using in combination, will add to the cumulative cost of treatment in an upwards manner.

The bigger questions for Europe in this scenario then become:

  • How to best manage available resources from the allocated healthcare pot?
  • The majority of money in cancer care is spent on the last 6 months of people’s lives – how should that be addressed ethically, economically and medically?

By the way, for American readers of this blog, please don’t call European provision ‘socialist healthcare’ – this is a silly misnomer, because:

  • It isn’t free – people pay for it – it’s deducted at source from wages in most countries
  • Several EU members such as the UK have a conservative, not socialist, Government in power
  • In Germany, a model of private providers similar to the US exists, and even in the UK additional private care can be bought through an employers offering, proving that not all European countries provide healthcare in the same way.

Abiraterone will likely be reimbursed at a discount in the UK

Meanwhile, J&J’s abiraterone is an interesting case study in point.  While approved by the EMA/CHMP, it isn’t available in all EU countries yet, as it wenders its way through the reimbursement approval process.  As I understand from delegates here, it is available in Ireland, for example, but was rejected by NICE in the UK as ‘too expensive’.

What was interesting here at EAU was learning from some EU thought leaders and competitor manufacturers that Janssen have apparently negotiated a discount of 40% of the list price in order for it to be available in the UK, although nothing official has been announced yet.

Will UK pricing have a broader impact on continental Europe?

Given the severe pan Europe economic hardship at present, one wonders how low this pricing strategy might go given that Greece is usually the lowest priced country.  If the 40% discount being bandied about here at EAU is correct, will other other EU countries look at the UK price and demand a similar discount?  It’s one thing the UK and say, Spain and Greece being 10-20% lower than Germany, but nearly half the price might upset the natural basket negotiations and wheeler dealing that usually occur.

You can almost imagine a satirical cartoon in Private Eye or The Economist, whereby jaundiced eye balls loom eerily out of a map of Europe, as each country warily looks at its usual reference baskets.

It will be interesting to watch what happens in the near future, because what happens in the advanced prostate cancer arena may have broader implications, not only for all EU countries, but also other manufacturers in the cancer marketplace.  Everyone involved is going to be following this evolution carefully.

 

EAU-2012-Congress-Paris-View-of-Eiffel-Tower-By-NIght

Sights of 2012 EAU Congress

Greetings from the European Association of Urology (EAU) congress in Paris. Despite the grey drizzle typical of Europe in winter, this is actually quite an interesting meeting with lots of poster presentations.

One poster that caught my eye yesterday was from Martin Gleave’s group on clusterin knockdown synergising MDV3100 activity. Previously, we discussed on this blog how inhibiting clusterin with custirsen (OGX-011) potentiated docetaxel. At the AUA meeting last year, the issue of whether the same would happen with MDV3100 was suggested, as you can see in the short video blog.

Clusterin is also known as testosterone-repressed prostate message-2 or TRMP-2, and has been shown by Miyake et al., (2000) to be important in advanced prostate cancer. This is because the treatment of choice in hormone-sensitive disease, androgen deprivation therapy (ADT), can lead to clusterin upregulation, thereby causing castrate resistance.

The group’s latest study at EAU looked at whether clusterin knockdown sensitised MDV3100 activity and evaluated potential mechanisms for how this might work.

The results showed that:

  1. Neither MDV3100 or custirsen alone affected AR levels, but in combination, the AR protein levels were reduced.
  2. The combination synergistically suppressed LNCaP (human prostate cancer cell lines) in vitro and in vivo compared to monotherapy with either alone.
  3. Inhibition of the AR has been shown to activate the PI3K-Akt pathway, but the combination prevented this from occurring.
  4. Dual treatment also increased AR instability via decreased levels of the AR chaperone, FKBP52.
  5. AR degradation occurred with combination therapy via the proteasome, leading to synergistic repression of AR transcription.

While these data offer a very nice and logical preclinical rationale for considering a combination of MDV3100 and custirsen to overcome castrate resistance in advanced disease, we also need to see clinical evidence in advanced prostate cancer before getting too excited. I like the idea scientifically but Oncogenex, the manufacturers of custirsen, have not exactly been swift at moving their previous trials along, as Luke Timmerman noted his Xconomy article last year.

Ultimately, the proof is always in the (clinical) pudding.

References:

ResearchBlogging.orgMiyake H, Nelson C, Rennie PS, & Gleave ME (2000). Testosterone-repressed prostate message-2 is an antiapoptotic gene involved in progression to androgen independence in prostate cancer. Cancer research, 60 (1), 170-6 PMID: 10646870

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