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25 April 2012

Advances in the Discovery of Protein-Protein Interaction Modulators published by Informa’s Scrip Insights

By |2012-04-25T00:00:00+00:00April 25, 2012|Cancer, Cardiovascular Disease, Chemistry, Drug Development, Drug Discovery, Epigenetics, Haberman Associates, Immunology, Strategy and Consulting|

 

Eltrombopag

On April 13, 2012, Informa’s Scrip Insights the publication of a new book-length report, Advances in the Discovery of Protein-Protein Interaction Modulators, by Allan B. Haberman, Ph.D.

Protein-protein interactions (PPIs) are of central importance in biochemical pathways, including pathways involved in disease processes. However, PPIs have been considered the prototypical “undruggable” or “challenging” targets. The discovery of small-molecule drugs that can serve as antagonists or agonists of PPIs, and which are capable of being successfully taken into human clinical trials, has been extremely difficult. Among the theoretical reasons for this is that contact surfaces involved in PPIs are usually large and flat, and lack the types of cavities present in the surfaces of proteins that bind to small-molecule ligands.

Nevertheless, over the last twenty years, researchers have developed a set of technologies and strategies that have enabled them, in a several cases, to discover developable small-molecule PPI modulators. One direct PPI agonist, the thrombopoietin mimetic eltrombopag (Ligand/GlaxoSmithKline’s Promacta/Revolade), has reached the market. The chemical structure of this compound is illustrated in the figure above. Several other small-molecule PPI modulators are in clinical trials. Despite this progress, the discovery and development of small-molecule PPI modulators has been one-at-a-time, slow and laborious.

The new strategic importance of protein-protein interactions as drug targets

Meanwhile, PPIs as potential drug targets have acquired a key strategic importance for the success of the pharmaceutical industry. Over at least the last decade, pharmaceutical R&D has failed to develop enough high-valued new drugs to make up for or exceed revenues from blockbusters that are losing patent protection. As we have discussed in previous publications and in , this low productivity is mainly due to pipeline attrition. There are several factors (ranging from target selection through drug design, preclinical studies, identification and use of biomarkers, and design of clinical trials) that can influence pipeline attrition.

However, increasing numbers of industry leaders and analysts identify target selection as the key factor that is limiting the productivity of pharmaceutical R&D. For example, I served as a workshop leader at Hanson Wade’s   last summer, which took that point of view. There are at least several such conferences throughout the year, which are organized at the request of industry leaders.

Industry experts who identify poor target selection as a major cause of pharma R&D’s productivity woes conclude that the main issue is that companies are running out of “druggable” targets that have not already been addressed by marketed drugs. As of 2011, only 2% of human proteins have been targeted with drugs. Most of the remaining disease-relevant proteins, including transcription factors and many other types of signaling proteins, work via interacting with other proteins in PPIs. Therefore, in order to reverse its R&D slump, the pharmaceutical industry needs to develop technologies and strategies to address PPIs and other hitherto “undruggable” targets.

Contents of the report

Our report discusses technologies and strategies that enable the discovery of drugs targeting PPIs, including both small-molecule and synthetic peptidic modulators. It includes case studies on the discovery of compounds that address specific target classes, with emphasis on agents that have reached human clinical studies. This includes addressing the issue of the need to produce PPI modulatory agents that have pharmacological properties that will enable them to be good clinical candidates.

The report also includes discussions of second-generation technologies for the discovery of small-molecule and peptidic PPI modulators, which have been developed by such companies as Forma, Ensemble, and Aileron, and by academic laboratories. The field of PPI modulator discovery has represented a “premature technology”, i.e., a field of biomedical science in which consistent practicable therapeutic applications are in the indefinite future, due to difficult technological hurdles. We have discussed premature technologies on earlier on this blog. The second-generation technologies are designed to overcome the hurdles and to thus enable a more accelerated and systematic approach to PPI drug discovery and development.

In part as the result of the development of these technologies, and of the increasing strategic importance of PPI modulator development, companies have been moving into the field. Examples include Bristol-Myers Squibb, Pfizer, Novartis, and Roche. A key issue is to what extent the new technologies for PPI modulator R&D will enable this area to be commercially successful, and to meet the strategic needs of the industry for expanding the universe of targets for which drugs can be developed.

To see the report Advances in the Discovery of Protein-Protein Interaction Modulators, please click here.

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As the producers of this blog, and as consultants to the biotechnology and pharmaceutical industry, Haberman Associates would like to hear from you. If you are in a biotech or pharmaceutical company, and would like a 15-20-minute, no-obligation telephone discussion of issues raised by this or other blog articles, or of other issues that are important to  your company, please click here. We also welcome your comments on this or any other article on this blog.

30 March 2012

“It’s not junk”–RaNA Therapeutics emerges from stealth mode with $20.7 million in venture funding-Part 2

By |2012-03-30T00:00:00+00:00March 30, 2012|Drug Development, Drug Discovery, Epigenetics, Oligonucleotide Therapeutics, Regulatory RNAs, RNAi, Stem Cells, Strategy and Consulting|

 

Atlas!

This is Part 2 of the article on RaNA Therapeutics that we began on March 29, 2012.

Jeannie Lee’s research and RaNA’s technology platform

Jeannie Lee’s laboratory focuses on the study of the mechanism of X-chromosome inactivation in mammals. In X-chromosome inactivation, one of the two copies of the X chromosome present in the cells of female mammals is inactivated. The inactive X chromosome is silenced by packaging into transcriptionally inactive heterochromatin.  X-chromosome inactivation results in dosage compensation, the process by which cells of males and females have the same level of expression of X-chromosome genes, even though female cells have two X chromosomes and male cells have only one. In placental mammals such as mice and humans, the choice of which X chromosome will be inactivated is random, but once an X chromosome is inactivated it will remain inactive throughout the lifetime of the cell and its descendants.

The Lee laboratory has focused on genes encoded by the X-chromosome whose actions coordinate X-chromosome inactivation. These genes  are contained in the 100 kilobase long X-inactivation center (Xic). One of these genes, Xist, encodes the lncRNA XIST, which as discussed in Part 1 of this article inactivates an X-chromosome by spreading along the X chromosome and recruiting the silencing factor PRC2. XIST is regulated in cis by TSIX, an antisense version of XIST which works to keep the active X-chromosome active. Tsix is in turn regulated by Xite (X-Inactivation intergenic transcription element), an upstream locus that harbors an enhancer that enables the persistence of TSIX expression on the active X chromosome. The mechanism by which Xite acts (including whether it acts via its RNA transcripts) is not clear. Xite and Tsix appear to regulate pairing between the two X chromosomes in a female cell, and determine which X chromosome will be chosen for inactivation. Several other recently discovered genes in the region of the Xic, which work via lncRNAs, also serve as regulators of XIST function. For example, the Rep A and Jpx genes, work via lncRNA transcripts to induce Xist. Thus Xist is controlled by positive and negative lncRNA-based switches–TSIX for the active X chromosome and JPX and REPA for the inactive X. Of these lncRNAs, REPA, XIST, and TSIX bind to and control PRC2.

In late 2010, the Lee laboratory published an article in Molecular Cell in which the researchers identified a genome-wide pool of over 9000 lncRNA transcripts that interact with PRC2 in mouse ES cells. Many of these transcripts have sequences that correspond to potentially medically-important loci, including dozens of imprinted loci (i.e., loci that are epigenetically modified such that only the paternal or maternal allele is expressed), hundreds of oncogene and tumor suppressor loci, and multiple genes that are important in development and show differential chromatin regulation in stem cells and in differentiated cells. The researchers obtained evidence that at least in one case, an RNAs works to recruit PRC2 to a disease-relevant genes, similar to PRC2 recruitment by XIST and HOTAIR. This case of specific PRC2 recruitment has not been previously known, suggesting that the researchers’ methodology could be used to discover new examples of PRC2 recruitment by lncRNAs.

Some of the PRC2-associated lncRNAs identified in the Molecular Cell report may be potential therapeutic targets and/or biomarkers. Overexpression of PCR2 proteins have been linked to various types of cancer, including metastatic prostate and breast cancer, and cancers  of the colon, breast, and liver. Pharmacological inhibition of PRC2-mediated gene repression was found to induce apoptosis in several cancer cell lines in vitro, but not in various types of normal cells. Induction of apoptosis in this system is dependent on reactivation of genes that had been repressed by PRC2. There is also evidence that PRC2-mediated gene repression may be linked to the maintenance of the stem-cell properties of cancer stem cells. These results suggest that at least in some cases, inhibition of PRC2-mediated gene repression–including via targeting lncRNAs that recruit PRC2 to critical genes–is a potential strategy for treating various types of cancer.

RaNA’s R&D strategy

Not much information is available about RaNA’s strategy.  However, according to the January 2012 Mass High Tech article, RaNA Therapeutics has licensed technology from Mass General Hospital based on Dr. Lee’s research. The company has also filed several patent applications, some of which are described as being very broad. This includes patent applications on the existence and method of use of thousands of lncRNA targets. However, Dr. Lee’s currently include only three items involving the X-chromosome inactivation system or TERC. Presumably, the patent applications mentioned in the Mass High Tech article will be published at the end of the 18-month publication period for U.S. patent applications.

According to the Mass High Tech article, RaNA is in the process of narrowing down the diseases it will initially focus on. Likely areas will include genetic diseases, including diseases that result from haploinsufficiency. In haploinsufficiency, one allele of a gene is nonfunctional, so all of the protein coded by the gene is made from the other allele. However, this results in insufficient levels of the protein to produce a normal phenotype. RaNA intends to use its technology to increase expression of the functional gene, resulting in a adequate dosage of the protein for a normal phenotype.

RaNA intends to choose one indication out of a short list of 20 diseases for internal R&D, and to seek collaborations for other indications. Dr. Krieg says that he hopes to have a collaboration by the end of 2012, and also to have Investigational New Drug (IND)-enabling safety studies on its internal drug candidate by the end of the year as well.

As one might expect, RaNA will target the appropriate lncRNAs using oligonucleotides, similar to how RNAi companies target mRNAs. Dr. Krieg, an oligonucleotide therapeutic development veteran, recruited some of his old oligonucleotide team from Pfizer into RaNA, according to a Fierce Biotech article. Thus Dr. Krieg and his team can quickly get up and running in designing and testing oligonucleotide therapeutics, once RaNA selects the targets for its initial focus.

In the Mass High Tech article, Dr. Krieg says that he believes that “oligonucleotides are on the cusp of being recognized as the third leg of drug development,” along with small-molecule and protein therapeutics. However, as we discussed in our August 22, 2011 article on this blog, oligonucleotide drug development, as exemplified by RNAi and microRNA-based therapeutics, has run into several technological hurdles, especially those involving drug delivery. The August 2011 article cites an editorial by Dr. Krieg, in which he voices his optimism despite these hurdles.

Nevertheless, large pharmaceutical companies and investors have been moving away from the oligonucleotide field. This is exemplified by Alnylam’s January 20, 2012 restructuring, which cut one-third of its work force and focused the company on two of its Phase 1 programs. Having exhausted its ability to capture major Big Phama licensing and R&D deals, Alnylam has had to become a normal early-2012 biotech company and focus its strategy. (However, Alnylam did a $86.9 million public offering in February 2012.)

The emergence of RaNA, and its $20.7 million funding, thus swims against the tide of the general pessimism about oligonucleotide therapeutics of Big Pharmas, investors, and stock analysts. However, at least some oligonucleotide therapeutics will eventually emerge onto the market, and lncRNA regulation is likely to be crucial to many disease pathways. RaNA is thus the pioneering company in this field.

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As the producers of this blog, and as consultants to the biotechnology and pharmaceutical industry, Haberman Associates would like to hear from you. If you are in a biotech or pharmaceutical company, and would like a 15-20-minute, no-obligation telephone discussion of issues raised by this or other blog articles, or of other issues that are important to  your company, please click here. We also welcome your comments on this or any other article on this blog.

29 March 2012

“It’s not junk”–RaNA Therapeutics emerges from stealth mode with $20.7 million in venture funding-Part 1

By |2012-03-29T00:00:00+00:00March 29, 2012|Drug Discovery, Epigenetics, Oligonucleotide Therapeutics, Regulatory RNAs, RNAi, Stem Cells, Strategy and Consulting|

 

XIST Source: Alexbateman http://bit.ly/GZNTZg

 

On January 18, 2012, start-up company RaNA Therapeutics (Cambridge, MA) emerged from stealth mode with 20.7 million in cash. The Series A venture funding was co-led by Atlas Venture, SR One, and Monsanto, with participation of Partners Innovation Fund.

RaNA will work on developing a technology platform that involves targeting long noncoding RNA (lncRNA), in order to selectively upregulate gene expression.

Arthur Krieg, M.D. will serve as RaNA’s President and CEO. He is the former Chief Scientific Officer of the now-closed Pfizer Oligonucleotide Therapeutics Unit, who later became an Entrepreneur in Residence at Atlas Venture (Cambridge, MA). Dr. Krieg was mentioned in two of our previous Biopharmconsortium Blog articles, dated February 15, 2011 and August 22, 2011.

Atlas quietly nurtured RaNA while working to complete the Series A venture round. According to a January 18, 2012 article in Mass High Tech, the company plans to move into about 9,000 square feet of space “somewhere in Cambridge” in early 2012.  RaNA has approximately a dozen employees.

According to the Mass High Tech article, RaNA’s platform is based on technology developed by scientific founder Dr. Jeannie Lee (Massachusetts General Hospital/Howard Hughes Medical Institute, Boston MA).  Drs. Lee and Krieg and Atlas Ventures are cofounders of RaNA.

This is Part 1 of our discussion of RaNA Therapeutics.

RaNA and “junk DNA”

RaNA’s focus is related to what has traditionally been called “junk DNA”. As shown by work on the Human Genome Project and other genomics studies, only about 2-3 percent of the human genome consists of protein-encoding genes. Genomics researchers had not been able to identify a function for most of the remaining 97-98% of the human genome. This gave rise to the idea that these sequences consisted of parasitic DNA sequences that had no function whatsoever. Most researchers thus called these sequences “junk DNA”. Some of the leading lights of the genomics field gave presentations in which they dismissed this DNA as “junk”, and they even proposed models for how this “junk DNA” might accumulate during evolution. Then they would go on to discuss the “interesting” 2-3 percent.

However, the “junk DNA” concept was not really established science, but a hypothesis. I–among a few others–would call these sequences “DNA of unknown function”.

In more recent years, many researchers showed that at least the vast majority of DNA of unknown function was transcribed. Then researchers found a function for a relatively small percentage of these sequences–they are precursors of microRNAs and other small regulatory RNAs. These RNAs are related to the phenomenon of RNA interference (RNAi), which has been the subject of much basic research, including the Nobel Prize-winning research of Drs. Andrew Fire and Craig Mello. RNAi is the basis for various therapeutic RNAi drug discovery and development efforts at such companies as Alnylam, Silence Therapeutics, Quark Phamaceuticals, Dicerna, and Santaris, as well as several large pharmaceutical companies.

The majority of DNA sequences of unknown function, however, are transcribed into lncRNA. As exemplified by the first article [“Quantity or quality?”, by Monika S. Kowalczyk and Douglas R. Higgs (University of Oxford)] in a point/counterpoint Forum published in the 16 February 2012 issue of Nature, many researchers postulate that at least most of these transcripts are nonfunctional. Transcription of these sequences might be, for example, at a low level, as the result of experimental artifacts or of exposure of sequences to the transcriptional machinery due to changes in chromatin during such processes as cell division or expression of nearby genes. This point of view moves the “junk DNA” hypothesis to the RNA level–now one might speak of “junk RNA”.

However, in the second article in the Nature Forum [“Patience is a virtue”, by Thomas R. Gingeras (Cold Spring Harbor Laboratory)], the author counsels “patience” in carefully unraveling the function, one by one, of each noncoding RNA (ncRNA) transcript. According to Dr. Gingeras’ article, there are currently some 161,000 human transcripts, 53% of which are ncRNAs. About 2% of these ncRNAs are precursors to microRNAs. Approximately 10% of the transcripts are lncRNAs that map to intergenic and intronic regions, and many of these transcripts have been implicated in regulation — both of locally and at a distance— of developmentally important genes. Another 16% of the ncRNAs are transcripts of pseudogenes — genes that appear to have lost their original functions during evolution. Some of the pseudogene transcripts have been shown to regulate gene expression by acting as decoys for microRNAs. Despite this progress in assigning functions to ncRNAs, no function has yet been found for the majority of these transcripts. However, these are early days in the ncRNA field, so patience and openness to new discoveries is advisable.

The same 16 February 2012 issue of Nature contains a “Nature Insight” supplement on “Regulatory RNA”. Of particular interest with respect to the functions of lncRNAs is the review by Mitchell Guttman (Broad Institute and MIT, Cambridge MA) and John Rinn (Broad Institute and Harvard, Cambridge MA), entitled “Modular regulatory principles of large non-coding RNAs”. Among the lncRNAs discussed in that review are the X-inactive specific transcript (XIST) (see the figure above) and the telomerase RNA component (TERC). Both of these lncRNAs were identified and their functions determined in the 1990s–XIST in 1991  and TERC in 1995. XIST is expressed exclusively from inactive X chromosomes and is required for X inactivation in mammals. TERC is an essential RNA component of telomerase, the enzyme that replicates chromosome ends (telomeres). At the same time as the functions of XIST and TERC were beginning to be unraveled, most researchers were continuing to dismiss ncDNA as “junk”. Should they have known better?

The Guttman and Rinn review discusses several other lncRNAs with known, important functions, all of which were discovered since the pioneering work on XIST and TERC. Among the genes that encode these lncRNAs are HOTAIR and HOTTIP, which affect expression of the HOXD and HOXA gene family, respectively. HOX genes are a superfamily of evolutionarily conserved genes that are involved the determination of the basic structure of an organism. They encode transcription factors that regulate target genes by binding to specific DNA sequences in enhancers. The large intergenic non-coding RNA-RoR (lincRNA-RoR) modulates reprogramming of human induced pluripotent stem cells (iPS cells, which were discussed in earlier articles on this blog). The lncRNA NRON regulates transcription factors of the NFAT (nuclear factor of activated T-cells) family, which are involved in regulating the immune response, as well as in the development of cardiac and skeletal muscle, and of the nervous system. These genes have also been implicated in breast cancer, especially in tumor cell invasion and metastasis.

A common theme in the function of several lncRNAs, as highlighted in the Guttman and Rinn review, is association of the lncRNA with a chromatin-regulatory protein complex. The lncRNA serves to guide the regulatory protein complex to specific regions of chromatin. The protein complex then modifies specific histones in the chromatin regions, resulting in silencing of target genes.

In particular, HOTAIR serves as a molecular scaffold that binds to two protein complexes. A 5′ domain of HOTAIR binds polycomb repressive complex 2 (PRC2), and a 3′ domain of HOTAIR binds the CoREST–LSD1 complex. This enables the targeting of PRC2 and LSD1 to chromatin for coupled histone H3 lysine 27 methylation by PRC2 and histone H3 lysine 4 demethylation by LSD1. Both are required for proper repression of HOX genes.

XIST has at least two discrete domains, one involved in silencing (RepA) and the other in localization (RepC) of the XIST molecule on the X chromosome. The silencing domain RepA binds to PRC2, and the localization domain RepC binds to the YY1 protein and heterogeneous nuclear ribonucleoprotein U (hnRNP U).

The cases of HOTAIR and XIST are examples of how lncRNAs may function as molecular scaffolds of regulatory protein complexes. This may be general phenomenon, since a recent study by Drs. Guttman and Rinn and their colleagues indicates that about 30% of lincRNAs in mouse embryonic stem (ES) cells are associated with multiple regulatory complexes. In this study, the researchers found that RNAi knockdown of dozens of lincRNAs causes either exit from the pluripotent state or upregulation of specific differentiation programs. Thus lincRNAs appear to have important roles in the circuitry controlling the pluripotent state of ES cells, and in commitment to differentiation into specific lineages.

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As the producers of this blog, and as consultants to the biotechnology and pharmaceutical industry, Haberman Associates would like to hear from you. If you are in a biotech or pharmaceutical company, and would like a 15-20-minute, no-obligation telephone discussion of issues raised by this or other blog articles, or of other issues that are important to  your company, please click here. We also welcome your comments on this or any other article on this blog.

5 March 2012

The Biopharmconsortium Blog hiatus to end soon!

By |2012-03-05T00:00:00+00:00March 5, 2012|About Our Blog|

 

As you all may have noticed, we have not had a post on the Biopharmconsortium Blog during the entire month of February, 2012.

This unintended hiatus happened because of the need to finish up other work.

We’re almost finished with these projects, and have several ideas for blog articles (including some articles that we had already started) in the hopper. So the Biopharmconsortium Blog hiatus will end soon.

Thank you very much for your patience, and for your continuing interest in our blog.

1 February 2012

Preclinical-stage biotech Verastem goes public. Really‽

By |2018-09-14T22:19:23+00:00February 1, 2012|Biomarkers, Cancer, Drug Development, Drug Discovery, Personalized Medicine, Stem Cells, Strategy and Consulting, Translational Medicine|

 

Salinomycin

On November 3, 2011, Cambridge MA biotech firm Verastem announced that it was filing a prospectus for an initial public offering (IPO). At that time, the company was 15 months old.

Verastem is led by Christoph Westphal, MD, PhD, a founder and the former CEO of Sirtris and a veteran entrepreneur and venture capitalist. The IPO has been underwritten by UBS, Leerink Swann, Lazard Capital Markets, Oppenheimer & Co., and Rodman & Renshaw.

On January 27, 2012, Fierce Biotech reported that Verastem had announced the previous night that its IPO raised $55 million from the sale of 5.5 million shares at $10 apiece. This price fell exactly in the middle of its expected $9 to $11 price range, and the company had even increased the offering by a million shares over what had originally been planned.

On the same day, Verastem’s stock opened at $11 a share on the NASDAQ, up from its initial public offering price of $10.

Verastem not only has Christoph Westphal as its Chairman and CEO, but is also based on science from eminent MIT researchers Robert Weinberg, Ph.D. and Eric Lander, Ph.D., and has several other well-respected academic researchers (including Nobelist Phillip Sharp, Ph.D.) plus biotech industry drug discoverers Julian Adams, Ph.D. (MIllennium’s Velcade) and Roger Tung, Ph.D. (Vertex’ Lexiva and Agenerase) on its Scientific Advisory Board. The company has had considerable fundraising success prior to its IPO, including raising $32 million in venture capital  in July 2011.

However, Verastem has not one lone drug in human clinical trials, its most advanced compounds are in the preclinical stage, and the company does not plan to file an IND until 2013! Thus Verastem has successfully gone public, in an era in which even most private biotech companies with drugs in late-stage clinical trials are finding it very difficult to do so, despite its lack of any clinical-stage drugs.

As noted in the Fierce Biotech article, Dr. Westphal as well as other venture capital funders of Verastem agreed to buy up to $16.3 million of the IPO. This in part explains the success of the IPO. As also noted by Fierce Biotech, with over 19 million common shares outstanding, the offering valued Verastem at $192 million.

We discussed Verastem in our August 2, 2011 Biopharmonsortium Blog article entitled “Development of personalized therapies for deadly women’s cancers”. Verastem focuses on discovery and development of drugs to target cancer stem cells. Its technology is based on a strategy for screening for compounds that specifically target cancer stem cells, developed by Drs. Weinberg, Lander, Piyush Gupta (MIT and Broad Institute) and their colleagues.

Cancer stem cells are best known in acute myeloid leukemia (AML), but their existence in other cancers (especially solid tumors) is controversial, as discussed in our article. Whether cancer stem cells are involved in the pathobiology of solid tumors (or a particular type of solid tumor) or not, the biology of the putative cancer stem cell phenotype can be important in certain subtypes of cancer. Cancer stem cells are characterized by the epithelial-mesenchymal transition (EMT). In the Cell paper, the researchers screened for compounds that specifically targeted breast cancer cells that had been experimentally induced into an EMT, and which as a result exhibited an increased resistance to standard chemotherapy drugs.   They identified the compound salinomycin (now being marketed as a generic veterinary antibiotic) as a drug that specifically targeted these cells, as well as putative cancer stem cells from patients.

As we discussed in our article, triple-negative (TN) breast cancer cannot be treated with standard receptor-targeting breast cancer therapeutics (e.g., tamoxifen, aromatase inhibitors, trastuzumab) but must be treated with cytotoxic chemotherapy. It is generally more aggressive than other types of breast cancer, and even treatment with aggressive chemotherapy typically results in early relapse and metastasis. However, TN breast cancer includes two experimentally defined subtypes that have gene expression signatures related to the EMT. One or both of these subtypes might therefore be expected to be sensitive to compounds that specifically target putative breast cancer stem cells. This may be true whether the cancer stem cell hypothesis applies to TN breast cancer or not. Verastem is focusing on TN breast cancer as its first therapeutic target.

Verastem’s VS-507, a proprietary formulation of salinomycin, is being developed to treat TN breast cancer. The company is also screening for additional compounds, including New Chemical Entities (NCE) that can achieve stronger intellectual property protection than a salinomycin formulation. Verastem had not chosen a lead compound as of the middle of 2011. The company is now reported to be doing preclinical studies on three of its compounds, and also plans to create diagnostic tests to identify patients that could benefit from its treatments. (As we discussed in our article, biomarker-based tests will be critical in making such therapies work.)

As one can discern from our blog article, we are intrigued by Verastem’s approach to cancer treatment, and especially its approach to TN breast cancer. The science behind Verastem’s drug discovery strategy, developed by 2011 ASCO award-winning oncogene and cancer stem-cell pioneer Bob Weinberg, is very compelling. We would love to see Verastem’s therapeutic strategy succeed.

However, as virtually all pharmaceutical and biotechnology R&D researchers well know, it is difficult to translate even the most compelling science developed by the most brilliant researchers into the clinic. Even therapeutic strategies with an excellent scientific rationale that have achieved proof of principle in the best animal models can result in clinical failure, especially with the first compound tested in proof-of-concept studies in human patients. The cancer stem cell hypothesis remains controversial. Moreover, diseases such as TN breast cancer are complicated, they may have mechanisms of resistance to a new experiential therapy that no one knows about, and our understanding of disease biology is limited.

Thus at least until Verastem’s therapies achieve proof of concept in human studies, purchase of Verastem stock is risky indeed. Moreover, there are other risks involved other than technical and clinical risk–especially competition for developing cancer stem cell-based therapies by other biotech/pharma companies. Venture capitalists (and certain knowledgeable individual investors and funds) are in the business of taking on high-risk investments for the sake of potential large rewards, but ordinary retail investors in the public markets are not. Therefore, it seems too early for Verastem to go public, even if it has founders and investors with enough clout to make an IPO successful.

Expert analysts in the IPO field, as stated in the Fierce Biotech article, are puzzled by the rationale for Verastem going public at this time. The financial news and services website “TheStreet.com” agrees. Our own sense of puzzlement is symbolized by the interobang (‽) in the title of this article.

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As the producers of this blog, and as consultants to the biotechnology and pharmaceutical industry, Haberman Associates would like to hear from you. If you are in a biotech or pharmaceutical company, and would like a 15-20-minute, no-obligation telephone discussion of issues raised by this or other blog articles, or of other issues that are important to  your company, please click here. We also welcome your comments on this or any other article on this blog.

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