The BET Bromodomain market is a meaty epigenetics topic we have followed for several years now, including a look at the space back in 2013 on the old Pharma Strategy Blog (Link). The last update on this was ironically at AACR last year when we discussed MYC and bromodomains (Link).
In a remarkable tale of two cities in real life, two companies we discussed in those posts – Constellation Pharma and Tensha Therapeutics – have had markedly different fortunes since then. Roche decided to end their collaboration with the former and went on to acquire the latter instead.
Since we first wrote about bromodomains and BET inhibitors, the niche has exploded in a wildly stunning way… More drugs in the pipeline, more tumour targets being explored, and even novel combinations being evaluated preclinically for synergistic or additive effects. Even I was surprised by how competitive this niche has become based on the offerings at AACR this year.
With all the wealth of new data at the AACR annual meeting and also some other recent presentations I’ve attended elsewhere, it’s time for a more in-depth look at the BET/Bromodomain landscape.
Who are the new players, which tumour targets are now being evaluated, which combinations might be useful?
A word to the wise – this is neither a nerdy science post nor a comprehensive literature review – instead we take a look at the emerging landscape from a new product development perspective.
Science has been absolutely critical to success in all of the cancer therapeutics from targeted therapies to immunotherapies that have emerged in the last decade.
It really doesn’t matter whether you come from a marketing and commercial organisation or the investment community – if you want to make great decisions, you need to understand the basics of the science underpinning the R&D, where the strengths and weaknesses are. The alternative is play Roulette and put everything on Black 11 as a euphemism for whichever company/product/target you have an interest in.
To learn more about this burgeoning niche in epigenetics, subscribers can log-in or you can sign-up via the Blue Box below:
Have you ever sat in a freezing cold scientific session and been so engrossed in the compelling presentations that followed, you simply forgot to take notes? Not one. That actually happened to me at the American Association for Cancer Research (AACR) in Philadelphia this year in one of the many fringe sessions that I attended.
Reading Terminal Clock, Philadelphia
Granted, the hot topic of the conference was undoubtedly checkpoint inhibition, but I was anxious to escape to the comfort of some meaty and familiar basic and translational science, namely MYC. MYC is largely thought to be a difficult to target, even undruggable protein, and along with RAS and p53, represents a formidable challenge for cancer researchers. These three oncogenic proteins alone are probably responsible for more drug resistance developing and even death from cancer than any other proteins in a patient with advanced disease.
For cancer patients with advanced disease, the clock is ticking on time they have left.
Solve these three problems (MYC, RAS and p53) and we may have a shot at dramatically improving outcomes. As Dr Gerard Evans (Cambridge) noted:
“I think it’s fair to say that we don’t really know why interruption of any oncogenic signal actually kills cancer cells, but one of the reasons that we’re interested in MYC is because it seems to be a common downstream effector of many, maybe all cancers.”
Sure, the road to success is paved with an enormous graveyard of failures, just as metastatic melanoma was before checkpoint blockade came along, ironically. What I heard at AACR both inspired and filled me with greater confidence… we’re finally getting somewhere.
To learn more about these intriguing new developments, you can login or sign-up in the box below.
San Francisco – Acute Myeloid Leukemia (AML) is largely a disease of the elderly since it is uncommon before the age of 45. It generally has a much poorer prognosis compared to other leukemias such as CML and even ALL. There are two main treatment options – high chemotherapy (ara-C is the main bedrock) or a stem cell transplant in those patients who are considered eligible. With the average age at diagnosis being ~66yo, many patients may be elderly and frail, making a SCT not a viable option.
Ara-C (cytarabine) has been around for many years and despite numerous clinical trials, it has yet to be displaced. There’s plenty of room for improvement though, and a high unmet medical need still exists. The good news is that despite the challenge of finding a highly effective yet well tolerated therapy, there’s a lot of R&D activity in this space.
In this preview of the data to be presented at the American Society of Hematology (ASH) annual meeting in San Francisco, I highlight my top 10 AML abstracts that are worth checking out.
To learn more, you can sign in or sign up in the box below.
For the third part of the series on the AACR Previews, I wanted to switch directions and take a broad look at five completely different approaches in cancer research that we haven’t discussed on Biotech Strategy before and look at how they are doing and which ones might be promising going forward. Some of these scientific developments could potentially impact existing compounds in development.
Companies mentioned: Exelixis, Roche/Genentech, GSK, Clovis, AstraZeneca, Oncoethix
Compounds discussed: cobimetinib, DEDN6526A, ipatasertib, dabrafenib, trametinib, OTX015, JQ1, CO–1686, AZD9291
To read more about these developments, you can sign in or sign up below.