Biopharmconsortium Blog

Pittsburgh compound B staining in AD. Source: National Institute on Aging/NIH.

In our February 28, 2013 article on the Biopharmconsortium Blog, we discussed the FDA’s February 7, 2013 Draft Guidance for Industry entitled “Alzheimer’s Disease: Developing Drugs for the Treatment of Early Stage Disease”.

This document had been distributed for comment purposes only, and the FDA has been seeking public comment on the draft guidance for 60 days following publication.

As we discussed, by issuing this Draft Guidance, the FDA added its voice to that of an ever-increasing segment of the scientific community that calls for a new focus on conducting clinical trials in early-stage Alzheimer’s disease (AD). This is in order to  focus industry R&D on developing treatments for patients whose disease is in a stage prior to the development of extensive irreversible brain damage. It is in this early stage of disease in which researchers believe that new drugs have the best chance of providing benefits to patients, by preventing further damage to the brain.

In our February 28, 2013 article, we also discussed several clinical trials being carried out by industry and academic researchers in early-stage AD. These trials should allow the scientific and medical community to answer the question as to whether treating patients with pre-AD or very early-stage AD with anti-amyloid MAb drugs can have a positive effect on the course of the disease, and slow or prevent cognitive decline.

Readers of our article may have noticed that the February 7, 2013 Draft Guidance was somewhat vague or confused. That is because there is currently no evidence-based consensus as to which biomarkers might be appropriate to support clinical findings in trials in early AD. Moreover, in “pre-AD” or very early-stage AD (i.e., before the onset of overt dementia) disease-related impairments are extremely challenging to assess accurately. Thus both measuring clinical outcomes and assessment via biomarkers in very early-stage AD are fraught with difficulty, making determination of drug efficacy very difficult.

In issuing the Draft Guidance, The FDA appeared to be seeking guidance from industry and from the academic community on how these issues might be resolved. As we said in our article, the early-stage AD trials now in progress might help the scientific and medical community, and the FDA, with issues of evaluation of biomarkers and clinical outcome measures in determining disease prognosis and the efficacy of drug treatments.

More recently–on March 13, 2013–the FDA proposed a further modification of its proposed guidelines for regulation of early-stage AD therapeutics. This was published online in an article in the New England Journal of Medicine (NEJM), entitled “Regulatory Innovation and Drug Development for Early-Stage Alzheimer’s Disease”, by Nicholas Kozauer, M.D. and Russell Katz, M.D. (As we stated in our earlier article, Dr.Katz is the director of the Division of Neurology Products in the FDA’s Center for Drug Evaluation and Research. Dr. Kozauer is a Clinical Team Lead in the same division of the FDA.)

The new proposal attempts to deal with some of the apparent confusion in the February 7, 2013 Draft Guidance, and to facilitate the development and approval of new drugs for early-stage AD. The NEJM article notes that traditional measures of AD drug efficacy at the FDA had included assessment both of improved cognition and improvements in function. Specifically, as stated by a New York Times article discussing the new FDA proposal, “cognition” refers to such mental processes as memory and reasoning (as assessed by various tests), and “function” refers to performing such day-to-day activities as cooking, dressing or bathing.

In the FDA’s March 13, 2013 NEJM article, the authors note that researchers and regulatory agencies “simply do not yet have drug-development tools that are validated to provide measures of function in patients with Alzheimer’s disease before the onset of overt dementia”. Thus, although one can test early-stage AD patients for improvements in cognition with the appropriate tests, testing for deficits and improvements in function is extremely difficult.

The authors of the NEJM article therefore suggest that it might be feasible that a drug for treating early-stage AD be approved via the FDA’s accelerated approval pathway, on the basis of assessment of cognitive outcome alone. The agency’s accelerated-approval pathway allows drugs that address an unmet medical need to be approved on the basis of a surrogate or an intermediate clinical endpoint–in this case, a sensitive measure of improvement in cognition. Drugs approved via “accelerated approval” must be subjected to postmarketing studies to verify the clinical benefit. This regulatory pathway might facilitate the approval of treatments that appear to be effective in early AD, when patients might be expected to derive a greatest benefit than after the development of overt dementia.

With respect to selection of patients for trials in early-stage AD, the authors of the NEJM article suggest that (based on “the consensus emerging within the AD research community”) clinical diagnosis of early cognitive impairment be combined with appropriate biomarkers. These biomarkers might include brain amyloid load [as measured by positron-emission tomography (PET)] and cerebrospinal fluid levels of β-amyloid and tau proteins. The FDA places a high priority on efforts by the researchers to qualify such biomarkers in clinical trial design in early-stage AD.

The author of the New York Times article, veteran science and medicine reporter Gina Kolata, says that the FDA’s new proposal could “help millions of people at risk of developing [AD] by speeding the development and approval of drugs that might slow or prevent it.”

She also says that the proposal could be a boon for the pharmaceutical industry and AD researchers. They have often been hampered by regulations that left them uncertain of how to get drugs tested and approved for early-stage AD. Not only might anti-AD therapies provide greater benefit to patients with early-stage AD than with later stage disease, but clinical trials in early-stage AD would have a greater potential for success–provided that researchers had appropriate means of determining efficacy in early-stage AD. The new FDA proposal may increase the likelihood of identifying such appropriate means.

As pointed out in the Times article, several leading AD researchers agree, with some important caveats. For example, AD researcher P. Murali Doraiswamy, M.D. (Duke University School of Medicine) said that the new proposed regulations would lead to more clinical trials, and more motivation now to invest in the AD field. However, many companies never manage to do postmarking studies required for drugs given accelerated approval, and such studies might not be randomized clinical trials as required in gaining approval of the drugs in the first place.

Sean Bohen, M.D., Ph.D. (Senior Vice President for Early Development at Genentech) was very positive about the proposed new FDA policy, but wondered how researchers could develop appropriate tests to identify subtle cognitive changes in early AD or pre-AD. Nevertheless, he said, “We have to start somewhere.”

Thus clinical trials in early-stage AD, and development of regulatory frameworks for approval and postmarketing studies of agents that emerge from these trials, remain a work in progress.

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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 an initial one-to-one consultation on an issue that is key to your company’s success, please contact us by phone or e-mail. We also welcome your comments on this or any other article on this blog.

Normal and Alzheimer’s brains compared.

Once again, approaches to improving clinical trials for candidate disease-modifying drugs for Alzheimer’s disease (AD) are in the news. On February 7, 2013, the FDA issued a Draft Guidance for Industry entitled “Alzheimer’s Disease: Developing Drugs for the Treatment of Early Stage Disease”.

This document has been distributed for comment purposes only, and the FDA is seeking public comment on the draft guidance for 60 days.

The wording of the Draft Guidance illustrates the extreme difficulty of defining populations with pre-AD or very early-stage AD, and of demonstrating the efficacy of a drug in ameliorating early-stage disease, and/or in preventing its progression to later-stage disease. The document states that the FDA is “open to considering the argument that a positive biomarker result (generally included as a secondary outcome measure in a trial) in combination with a positive finding on a primary clinical outcome measure may support a claim of disease modification in AD.”

However,  there is currently no evidence-based consensus as to which biomarkers might be appropriate to support clinical findings in trials in early AD. Moreover, in “pre-AD” or very early-stage AD (i.e., before the onset of overt dementia) mild disease-related impairments are extremely challenging to assess accurately. Thus both measuring clinical outcomes and assessment via biomarkers in very early-stage AD are fraught with difficulty, making determination of drug efficacy extremely difficult. The FDA thus appears to be seeking guidance from industry and from the academic community on how these knotty problems might be solved.

The move toward conducting clinical trials in early-stage AD patients

By issuing the Draft Guidance, the FDA adds its voice to that of an ever-increasing segment of the scientific community that calls for a new focus on conducting clinical trials in early-stage AD. We discussed this trend in our August 19, 2012 and August 28, 2012 articles on the Biopharmconsortium Blog.

As we discussed, this trend is driven in part by the Phase 3 failures of Pfizer/Janssen’s bapineuzumab and Lilly’s solanezumab in 2012. Now–in February 2013–Russell Katz, M.D. (director of the Division of Neurology Products in the FDA’s Center for Drug Evaluation and Research) says, “The scientific community and the FDA believe that it is critical to identify and study patients with very early Alzheimer’s disease before there is too much irreversible injury to the brain. It is in this population that most researchers believe that new drugs have the best chance of providing meaningful benefit to patients.”  In line with this statement, the FDA refused to entertain Lilly’s  secondary analysis of early stage patients in the solanezumab study that we discussed in our August 28, 2012 blog article. Instead, the FDA mandated that Lilly conduct a new Phase 3 trial that will exclude the moderate-stage patients who hadn’t responded, and focus only on early-stage patients.

Recent news on clinical trials in early-stage AD

Despite the difficulties highlighted in the Draft Guidance in conducting clinical trials in early-stage AD patients, three research groups are actually conducting such trials. We outlined these studies in our August 28, 2012 blog article, and discussed one of these studies, the one begin carried out by Genentech, in greater detail in our August 19 2012 article.

The three studies are:

• Roche/Genentech’s Phase 2a trial of its its anti-amyloid MAb crenezumab, in presymptomatic members of a large Colombian kindred who harbor a mutation in presenilin 1 (PS1) that causes dominant early−onset familial AD.

• Studies conducted in conjunction with the Dominantly Inherited Alzheimer Network (DIAN), a consortium led by researchers at Washington University School of Medicine (St. Louis, MO). This study will include people with mutations in any of the three genes linked to early-stage, dominantly-inherited AD–PS1, PS2, and amyloid precursor protein (APP). Initial studies focused on changes in biomarkers and in cognitive ability as a function of expected age of AD onset in people with these mutations. These included changes in concentrations of amyloid-β1–42 (Aβ42) in cerebrospinal fluid (CSF), and amyloid accumulation in the brain. In the first stage of the actual trial, three drugs (which have not yet been selected) will be tested in this population, and changes in biomarkers and cognitive performance will be followed.

• The Anti-Amyloid Treatment of Asymptomatic Alzheimer’s (A4) trial, will involve treating adults without mutations in any of the above three genes, whose brain scans show signs of amyloid accumulation. A4 is thus designed to study prevention of sporadic AD (by far the most common form of the disease). It will enroll 500 people age 70 or older who test positive on a scan of amyloid accumulation in the brain. (This is in contrast to the two trials in subjects with gene mutations, who are typically in their 30s or 40s.) A4 will also have a control arm of 500 amyloid-negative subjects. Amyloid-positive and control subjects will be entered into a three-year double-blind clinical trial that will look at changes in cognition with drug treatment. The A4 researchers [led by Reisa Sperling, Brigham and Women’s Hospital/Harvard University (Boston, MA), and Paul Aisen, University of California, San Diego] planned to select a drug for testing by December 2012.

Now there is more recent news on two of these trials.

1. On December 13, 2012, the Los Angeles Times reported that Genentech and its collaborators [affiliated with the University of Antioquia medical school (Medellin, Colombia), the University of California at Los Angeles (UCLA), and the Banner Alzheimer's Institute (Phoenix, AZ)] will begin their $100 million clinical trial of crenezumab with 100 Colombians who carry the PS1 mutation in the spring of 2013. Genentech is contributing $65 million of the study’s $100-million cost. The NIH and the Banner Alzheimer’s Institute (Phoenix, AZ) are financing the remainder.

This story was also reported on December 14, 2012 by Fierce Biotech.

The design of the trial calls for 100 additional patients in Colombia with the same Alzheimer’s-related gene to receive a placebo, and an equal number of other at-risk patients without the gene to take crenezumab.  A branch of the trial will include U.S. patients as well. A “branch study” will also be conducted at UCLA, where researchers have discovered a similar genetic disposition among members of an extended family from Jalisco, Mexico. Some 30 individuals from this family who have immigrated to Southern California could participate. Around 150 other U.S. patients with similar mutations will also participate in the trial.

The trial is designed to provide evidence that targeting amyloid with crenezumab at an early stage or even before patients show signs of dementia can have a positive effect on the course of disease.

2. On January 18, 2013, Fierce Biotech reported that the researchers conducting the A4 study have chosen Lilly’s solanezumab as as the first therapeutic drug candidate to be evaluated in the trial. The A4 trial’s principal investigator, Reisa Sperling said that the researchers chose solanezumab (after considering a number of anti-amyloid drugs) because the compound has a good safety profile, and appeared to show a modest clinical benefit in the mild AD patients in Lilly’s Phase 3 trial. The A4 researchers’ confidence in solanezumab grew when this was confirmed via an independent academic analysis by the Alzheimer’s Disease Cooperative Study (ADCS), a consortium of academic Alzheimer’s disease clinical trial centers. The ADCS, which was established by NIH, will help facilitate the A4 trial.

The A4 researchers hope that starting treatment with solanezumab before symptoms are present, as well as treating for a longer period of time, will slow cognitive decline and ultimately prevent AD dementia.

After the failure of solanezumab in Lilly’s own Phase 3 studies, and the FDA’s rebuff of the company’s secondary analysis of early stage patients, the A4 study’s choice of solanezumab gives the drug a new lease on life. Meanwhile, Lilly will be continuing its own clinical trial program for solanezumab.

Conclusions

The three clinical trials discussed in this article should allow the scientific and medical community to answer the question as to whether treating patients with pre-AD or very early-stage AD with anti-amyloid MAb drugs can have a positive effect on the course of the disease, and slow or prevent cognitive decline. The studies may also help the scientific and medical community, and the FDA, with issues of evaluation of biomarkers and clinical outcome measures in determining disease prognosis and the efficacy of drug treatments. Given the large size and rapid growth of the at-risk population, finding safe and efficacious disease-modifying preventives and treatments for AD is of increasing urgency.

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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 an initial one-to-one consultation on an issue that is key to your company’s success, please contact us by phone or e-mail. We also welcome your comments on this or any other article on this blog.

Neurofibrillary tangle.

In August and September of 2012, we published three articles on Alzheimer’s disease on the Biopharmconsortium Blog:

• New genetics study supports the amyloid hypothesis of Alzheimer’s disease–but the drugs still don’t work! (August 19, 2012.)
• Here we go again–Lilly’s Alzheimer’s drug solanezumab fails to show efficacy in Phase 3, but company is “encouraged” by secondary analysis. (August 28, 2012.)
• Alzheimer’s disease–where do we go from here? (September 20, 2012.)

Subsequent to the publication of our articles–on 21 November, 2012–the Wellcome Trust announced the identification of a novel pathway involved in the pathogenesis of Alzheimer’s disease (AD). This research was led by Professor Simon Lovestone and Dr Richard Killick (Kings College, London U.K.), and was published in the online edition of Molecular Psychiatry on 20 November 2012. The Wellcome Trust helped to fund the research.

As we have discussed in earlier articles on this blog, the dominant paradigm among AD researchers and drug developers is that the disease is caused by aberrant metabolism of amyloid-β (Aβ) peptide, resulting in accumulation of neurotoxic Aβ plaques. This paradigm is known as the “amyloid hypothesis”. AD is also associated with neurofibrillary tangles (NFTs) which are intracellular aggregates of hyperphosphorylated tau protein. In contrast to the amyloid hypothesis, some AD researchers have postulated that NFT formation is the true cause of AD. The new research links amyloid toxicity to the formation of NFTs, and identifies potential new drug targets.

The new study is based on the discovery of the role of clusterin–an extracellular chaperone protein–in sporadic (i.e., late-onset, non-familial) AD. The gene for clusterin, CLU, has been identified as a genetic risk factor for sporadic AD via a genome-wide association study published in 2009. Clusterin protein levels are also increased in the brains of transgenic mouse models of AD that express mutant forms of amyloid precursor protein (APP), as well as in the serum of humans with early stage AD.

The researchers first studied the relationship between Aβ and clusterin in mouse neuronal cells in culture. Aβ rapidly increases intracellular concentrations of clusterin in these cells. Aβ-induced increases in clusterin drives transcription of a set of genes that are involved in the induction of tau phosphorylation and of Aβ-mediated neurotoxicity. This pathway is dependent on the action of a protein known as Dickkopf-1 (Dkk1), which is an antagonist of the cell-surface signaling protein wnt. The transcriptional effects of Aβ, clusterin, and Dkk1 are mediated by activation of the wnt-planar cell polarity (PCP) pathway. Among the target genes in the clusterin-induced DKK1-WNT pathway that were identified by the researchers are EGR1 (early growth response-1), KLF10 (Krüppel-like factor-10) and NAB2 (Ngfi-A-binding protein-2)–all of these are transcriptional regulators. These genes are necessary mediators of Aβ-driven neurotoxicity and tau phosphorylation.

The researchers went on to show that transgenic mice that express mutant amyloid display the transcriptional signature of the DKK1-WNT pathway, in an age-dependent manner, as do postmortem human AD and Down syndrome hippocampus. (Most people with Down syndrome who survive into their 40s or 50s suffer from AD.) However, animal models of non-AD tauopathies (non-AD neurodegenerative diseases associated with pathological aggregation of tau, and formation of NFTs, but no amyloid plaques) do not display upregulation of transcription of genes involved in the DKK1-WNT pathway, nor does postmortem brain tissue of humans with these diseases.

The Kings College London researchers concluded that the clusterin-induced DKK1-WNT pathway may be involved in the pathogenesis of AD in humans. They also hypothesize that such strategies as blocking the effect of Aβ on clusterin or blocking the ability of Dkk1 to drive Wnt–PCP signaling might be fruitful avenues for AD drug discovery. According to the Wellcome Trust’s 21 November 2012 press release, Professor Lovestone and his colleagues have shown that they can block the toxic effects of amyloid by inhibiting DKK1-WNT signaling in cultured neuronal cells. Based on these studies, the researchers have begun a drug discovery program, and are at a stage where potential compounds are coming back to them for further testing.

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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 an initial one-to-one consultation on an issue that is key to your company’s success, please contact us by phone or e-mail. We also welcome your comments on this or any other article on this blog.

New Alzheimer’s disease model, the CVN mouse

Our August 19, 2012 and our August 28, 2012 articles on this blog focused on the latest developments in Alzheimer’s disease (AD) drug development. To summarize the conclusions of the articles:

• The results of a new genetic study by DeCode Genetics and its collaborators strongly support the amyloid hypothesis of AD, and especially the hypothesis that reducing the β-cleavage of APP [e.g., by use of an inhibitor of β-secretase (also known as the β-site APP cleaving enzyme 1, or BACE1)] may protect against the disease.

• Nevertheless, in Phase 3 trials of two anti-amyloid monoclonal antibody (MAb) drugs in patients with mild to moderate AD–Pfizer/Janssen’s bapineuzumab (often called “bapi” for short) and Lilly’s solanezumab–the drugs failed their primary cognitive and functional endpoints.

• Roche/Genentech, as well as two academic consortia, have begun clinical trials of anti-amyloid MAb drugs in asymptomatic patients with mutations that predispose them to develop AD, or in asymptomatic patients with amyloid accumulation. These studies are based on the hypothesis that the reason for the failure of anti-amyloid MAb drugs in clinical trials has been that the patients being treated had suffered extensive, irreversible brain damage. Treating patients at a much earlier stage of disease with these agents might therefore be expected to be more successful.

Analyses of the data from the Phase 3 studies of both bapi and solanezumab will be presented in scientific meetings in October 2012. An academic research consortium will present its independent analysis of the data from the EXPEDITION studies of solanezumab at the American Neurological Association (ANA) meeting in Boston on October 8, 2012, and at the Clinical Trials on Alzheimer’s Disease (CTAD) meeting in Monte Carlo, Monaco, on October 30, 2012.

According to a September 11, 2012 news article in Drug Discovery & Development, researchers who conducted the Phase 3 trials of bapi found evidence that the drug stabilized amyloid plaque in the brain and may have ameliorated further nerve damage in patients treated with the drug. This finding is among the results to be presented in the October meetings.

Development of BACE1 inhibitors

Strictly speaking, the results of the DeCode Genetics study most strongly support the development of BACE1 inhibitors. In our August 28, 2012 article, we link to a 2010 review that includes a discussion of companies developing BACE1 inhibitors. However, we also note that the development of BACE1 inhibitors has been elusive. This is because of medicinal chemistry considerations. Specifically, it has been difficult to design a specific, high-affinity inhibitor of the BACE1 active site that can cross the blood-brain barrier and which has good drug-like ADME (absorption, distribution, metabolism and excretion) properties. Nevertheless, recently progress has been made in developing such compounds, and several companies are developing BACE1 inhibitors and have entered them into early-stage clinical trials.

Among the companies developing BACE1 inhibitors, as listed in a recent post on Derek Lowe’s In The Pipeline blog are CoMentis/Astellas, Merck, Lilly, and Takeda.

Satori Pharmaceuticals is developing γ-secretase inhibitors

Developing γ-secretase inhibitors has been abandoned by the vast majority of companies, because of the essential role of these enzymes in the Notch pathway and other pathways involved in normal physiology. As a result, development of γ-secretase inhibitors for AD has not progressed beyond the preclinical stage.

Nevertheless, Satori Pharmaceuticals, a Cambridge, MA venture capital-backed biotech company, is now actively involved in developing γ-secretase inhibitors. Satori’s γ-secretase inhibitors are based on a proprietary scaffold derived from a compound isolated from the black cohosh plant (Actaea racemosa). The company utilized modern synthetic and medicinal chemistry to derive compounds based on this scaffold that they believe are suitable for long-term oral therapy for AD in humans. Satori’s lead compound, SPI-1865, is a potent γ-secretase modulator that decreases levels of the amyloidogenic Aβ42 peptide as well as Aβ38, increases levels of Aβ37 and Aβ39, but does not affect Aβ40. Researchers believe that decreasing Aβ42 levels in favor of shorter, less amyloidgenic A-beta forms is beneficial in treatment of AD. SPI-1865 is also selective for Aβ42 lowering over the inhibition of Notch processing, and appears to be free of any other off-target activities.

In animal models [e.g., wild type mice and rats, and transgenic mice (Tg2576) that overexpress APP and thus have high levels of Aβ peptides] orally-administered SPI-1865 has been found to lower brain Aβ42. SPI-1865 has good brain penetration in these models, and a long half-life that should permit once a day dosing in humans.

SPI-1865 is now in the preclinical stage. Satori plans to file an Investigational New Drug (IND) Application with the FDA in late 2012 with the goal of enabling initial human testing to begin in the early part of 2013.

The overall strategy of Satori Pharmaceuticals is to develop novel and proprietary oral small-molecule drugs that are designed for chronic dosing, and can be used to treat patients with early-stage (or presymptomatic) AD for years or decades. Such a strategy will require compounds that are efficacious and exceptionally safe. Satori expects that its unique γ-secretase inhibitors will have these properties. However, this needs to be shown in human clinical trials. Moreover, this strategy–as with all strategies that involve treating AD in its earliest stages–will involve the development of reliable biomarkers and companion diagnostics.

A new mouse model for AD

As Derek Lowe says in an August 31, 2012 post on “In the Pipeline” with respect to Lilly’s AD drugs, anti-amyloid MAbs, BACE1 inhibitors, and γ-secretase inhibitors are “some of the best ideas that anyone has for Alzheimer’s therapy”. Given the APP processing pathway as illustrated in the figure at the top of our August 28, 2012 article, these are the “sensible” and “logical” alternatives.

Nevertheless, there is the nagging feeling among many AD researchers that we do not understand the causes of AD, especially sporadic AD, which represents around 95% of all cases of the disease. Sporadic AD occurs in aging individuals who have normal genes for the components of the APP processing pathway. Not only do we not understand the pathobiology of sporadic AD, but we have little understanding of the normal physiological function of APP and of APP processing. Processes that may be involved in the initiation of sporadic AD may include not only those involved in Aβ production, but also those involved in Aβ clearance.

An important tool in understanding the pathobiology of AD, and potentially in developing novel therapies for the disease, would be an animal model that recapitulates the human disease as closely as possible. We published an article on AD mouse models that were designed to more closely recapitulate human AD than the most commonly used models in the September 15, 2004 issue of Genetic Engineering News. However, since the publication of our article, Carol A Colton, Ph.D. (Duke University Medical Center, Durham, NC) and her colleagues have published on their research aimed at producing an even better mouse model, known as the CVN mouse. They published their research in two articles, one in PNAS in 2006 and the other in the Journal of Neuroscience in 2008.

Charles River Laboratories (CRL) (Wilmington, MA) now offers the CVN mouse to researchers who might wish to employ it in their AD research. CRL has also recently produced a webinar (with the participation of Dr. Colton) on the CVN mouse, entitled “CVN Mouse: A More Translatable Alzheimer’s Efficacy Model”. You may access this webinar by registering at http://www.criver.com/thesource.

Genome-wide association studies (GWAS) in humans, as well as various functional studies, have implicated variants in genes involved in inflammation and immune responses in susceptibility to late-onset, sporadic AD in humans. The Colton group, noting that commonly-used mouse models of AD recapitulated human disease very poorly, looked for differences between mice and humans in innate immunity. The biggest difference they found was that expression of nitric oxide synthase 2 (NOS2) the inducible form of nitric oxide synthase, is high in mice and low in humans. NOS2 is an enzyme that produces nitric oxide (NO), a highly reactive oxidant that can serve in signal transduction, neurotransmission and in cell killing by macrophages. Microglia, the macrophages of the brain, express NOS2 and NO. The Colton group has been studying the role of microglia and oxidants and antioxidants in microglia that can produce oxidative stress in the brain in normal aging and in AD.

Because of the striking difference in NOS2 expression between mice and humans, the Colton group created a transgenic mouse AD model by crossing mice that  expressed a mutant form of human APP known as APPSwDI (APP Swedish Dutch Iowa) with NOS2 knockout (NOS2 -/-) mice. The APPSwDI transgenic mouse, a well-characterized standard AD mouse model, was chosen because it expresses low levels of APP and high levels of Aβ peptides in the brain. The APPSwDI/NOS2 -/- mouse is the CVN mouse that is available from CRL.

Unlike APPSwDI mice and other standard AD mouse models, the CVN mouse recapitulates many features of human AD as the animals age, including AD-like amyloid pathology (starting at 6 weeks of age, which is early), perivascular deposition of amyloid, AD-like tau pathology (including aggregated hyperphosphoryated tau), AD-like neuronal loss, and reduction in interneuron numbers (including NPY interneurons). Age-related cognitive (learning and memory) loss (as assessed by the radial arm water maze test) was also seen. The researchers also saw increases in immune activation and inflammation (e.g., microglial activation) over the course of the disease; this appeared to be dependent on increases in Aβ and in tau.

The researchers also used the mouse to study changes in immune-related proteins over the course of the disease. Several protein that are encoded by genes that have been associated with sporadic AD via GWAS change over time in this mouse model, including APOE (which has been known to be important in AD for a long time) and BIN1. Other proteins that change over the course of disease include the complement component C1QB, and the centrosomal protein ninein. Immune activation genes such as those that encode IL-1α and TGF-β also show changes over the course of disease in these mice. The Colton group will soon publish their work on changes in these proteins and genes in the CVN mouse in a peer-reviewed journal.

In summary, the CVN mouse more faithfully models AD-like progression than other mouse models that have been used to study AD, including those that have been used in preclinical studies of such failed drug candidates as solanezumab, bapineuzumab, Flurizan (tarenflurbil), and Alzhemed (3-amino-1-propanesulfonic acid). It also allows researchers to study the role of genes and proteins such as those identified in GWAS studies in AD, and especially in sporadic AD. (However since the CVN mouse expresses a mutant form of APP, it can not be used to study all aspects of the pathophysiology of sporadic AD, especially the initiation of the disease process.) The CVN mouse can also be used in drug discovery and preclinical studies.

One example of such drug discovery studies is being carried out by the Colton group. They have recently been studying small APOE mimetic peptides in CVN mice. The subcutaneously administered APOE mimetics were reported to significantly improve behavior, while decreasing the inflammatory cytokine IL-6, as well as decreasing neurofibrillary tangle-like and amyloid plaque-like structures. These improvements are associated with apoE mimetic-mediated increases in protein phosphatase 2A (PP2A) activity. [Decreased PP2A levels in AD may be involved in formation of neurofibrillary tangles (NFTs) which are aggregates of hyperphosphorylated tau; PP2A may also be involved in the production of Aβ peptides. The APOE mimetic are thus potential AD therapeutics.

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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.

Amyloid precursor protein (APP)

As we mentioned in our August 19, 2012 article on Alzheimer’s disease (AD), the results of Phase 3 trials of Lilly’s amyloid-targeting monoclonal antibody (MAb) drug solanezumab, had been expected soon.

On August 24 2012, Lilly announced the top-line results of the two Phase 3, double-blind, placebo-controlled EXPEDITION trials of solanezumab in patients with mild-to-moderate Alzheimer’s disease. The primary endpoints, both cognitive and functional, were not met in either of these trials.

However, a pre-specified secondary analysis of pooled data across both trials showed statistically significant slowing of cognitive decline in the overall study population, and pre-specified secondary subgroup analyses of pooled data across both studies showed a statistically significant slowing of cognitive decline in patients with mild Alzheimer’s disease, but not in patients with moderate Alzheimer’s disease.

These results were reported in a press release.  What was absent was data from the trials. However, the Alzheimer’s Disease Cooperative Study (ADCS), (an academic national research consortium) will present its independent analysis of the data from the EXPEDITION studies at the American Neurological Association (ANA) meeting in Boston on October 8, 2012, and at the Clinical Trials on Alzheimer’s Disease (CTAD) meeting in Monte Carlo, Monaco, on October 30, 2012.

Once again, an amyloid pathway-targeting drug for Alzheimer’s disease that was taken into Phase 3 trials despite Phase 2 results that showed no statistically significant efficacy has failed in Phase 3. Solanezumab joins a list of such failed drugs that includes Myriad Pharmaceuticals’ Flurizan (tarenflurbil), Neurochem’s (now Bellus Health) Alzhemed (3-amino-1-propanesulfonic acid), and as of July 2012, Pfizer/Janssen’s bapineuzumab (“bapi”). Nevertheless, as in the Phase 2 results with bapi, Lilly sees hope for the drug in the results of secondary analyses.

On the day of the Lilly announcement, August 24 2012, Lilly executives and stock analysts turned the results of these trials into something “positive”, as the result of the secondary analysis. This resulted in a one-day 3.4 percent increase in the price of Lilly stock. However, the results of the secondary analysis do not give Lilly any basis for going to the FDA with a New Drug Application (NDA) for solanezumab. Nor do they provide any realistic hope for AD patients, the physicians who treat them, or caregivers of AD patients.

At best, Lilly’s secondary analysis gives rise to a hypothesis–that solanezumab–and presumably other anti-amyloid MAbs–will be effective in treating earlier-stage AD patients, especially those who have not suffered extensive, irreversible brain damage. This is the very same hypothesis that is now being tested by Roche/Genentech in its clinical trials of its anti-amyloid MAb crenezumab, as we discussed in our August 19, 2012 article. Genentech is testing its drug candidate in a Phase 2a trial in a very special population–members of a large Colombian kindred who harbor a mutation in presenilin 1 (PS1) that causes dominant early−onset familial AD.

A News Focus article in the 17 August 2012 issue of Science, written by science writer Greg Miller, PhD, discusses three upcoming clinical trials designed to test the “treat early-stage or presymptomatic AD with anti-amyloid MAbs” hypothesis. One of these studies is the Genentech trial of crenezumab in the extended family in Colombia.

Another of these studies is being conducted in conjunction with the Dominantly Inherited Alzheimer Network (DIAN), a consortium led by researchers at Washington University School of Medicine (St. Louis, MO). This study will include people with mutations in any of the three genes linked to early-stage, dominantly-inherited AD–PS1, PS2, and amyloid precursor protein (APP).

Initial studies, published ahead of print in the July 11 issue of the New England Journal of Medicine (NEJM) looked at changes in biomarkers and in cognitive ability as a function of expected age of AD onset in people with these mutations. Concentrations of amyloid-β1–42 (Aβ42) in the cerebrospinal fluid (CSF) appeared to decline 25 years before expected symptom onset. This decrease may reflect impaired clearance of Aβ42 from the brain, which may be a factor in the amyloid plaque increase that is associated with AD. Amyloid accumulation in the brain was detected 15 years before expected symptom onset. Other biomarkers, as well as cognitive impairment, were also followed in the study published in the NEJM. In the first stage of the actual trial, three drugs (which have not yet been selected) will be tested in this population, and changes in biomarkers and cognitive performance will be followed.

The third study, known as the Anti-Amyloid Treatment of Asymptomatic Alzheimer’s (A4) trial, will involve treating adults without mutations in any of the above three genes, whose brain scans show signs of amyloid accumulation. A4 is thus designed to study prevention of sporadic AD (by far the most common form of the disease). It will enroll 500 people age 70 or older who test positive on a scan of amyloid accumulation in the brain. (This is in contrast to the two trials in subjects with gene mutations, who are typically in their 30s or 40s.) A4 will also have a control arm of 500 amyloid-negative subjects. Amyloid-positive and control subjects will be entered into a three-year double-blind clinical trial that will look at changes in cognition with drug treatment. The A4 researchers [led by  Reisa Sperling, Brigham and Women’s Hospital/Harvard University (Boston, MA), and Paul Aisen, University of California, San Diego] plan to select a drug for testing by December 2012.

If Lilly wishes to test solanezumab in early-stage (or presymptomatic) sporadic AD, it will need to follow a similar methodology to the studies outlined in the new Science article, especially with respect to the use of biomarkers to define “early-stage” AD and to track the effects of the drug. Studies such as the DIAN biomarker study published in the NEJM used the positron emission tomography (PET) ligand Pittsburgh Compound-B (PiB-C11), to image amyloid plaques. However, the use of this compound is limited by the short half-life of carbon-11 (20.4 minutes). A new PET amyloid imaging agent, Amyvid (florbetapir F18 Injection) was developed by Lilly and approved by the FDA in April 2012. This compound contains fluorine-18, which has a half-life of 109.8 minutes. A recent study indicates that Amyvid provides comparable information to PiB-C11. If Lilly wishes to conduct new studies of solanezumab in early-stage or presymptomatic sporadic AD, it may wish to use Amyvid, as suggested in a comment to an August 24, 2012 solanezumab post in Derek Lowe’s blog “In the Pipeline”. However, the FDA, in its press release announcing the approval of Amyvid, warns that increased amyloid plaque content (as detected by Amyvid or Pittsburgh Compound-B) may be present in the brains of patients with non-AD neurologic conditions, and in older people with normal cognition. Thus defining or detecting “early-stage (or presymptomatic) sporadic AD” is difficult.

In any case, for Lilly to follow up on its secondary analyses of the Phase 3 clinical trials of solanezumab will necessitate additional long and expensive clinical trials, with no assurance of success. Lilly executives will need to determine if such a course is worth the risk, or whether it should invest in other R&D efforts that might have a higher probability of success.

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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.

The APP processing pathway

An exciting new study on Alzheimer’s disease (AD) was published in the 2 August issue of Nature. The study was carried out by researchers at deCode Genetics (Reykjavik Iceland) and their collaborators at Genentech and several academic institutions. A News and Views article by leading AD researcher Bart De Strooper and genomics researcher Thierry Voet (both at KU Leuven, Leuven, Belgium) analyzes this study and its implications.

Amyloid plaques are a central feature of AD.  They largely consist of amyloid-β (Aβ) peptides. Aβ peptides are formed via sequential proteolytic processing of the amyloid precursor protein (APP), catalyzed by two aspartyl protease enzymes–β-secretase and γ-secretase.  The β-site APP cleaving enzyme 1 (BACE1) cleaves APP predominantly at a unique site. However, γ-secretase cleaves the resulting carboxy-terminal fragment at several sites, with preference for positions 40 and 42. This leads to formation of amyloid-β1–40 (Aβ40) and Aβ1–42 (Aβ42) peptides. APP processing to yield Aβ peptides is illustrated by the figure at the top of this article.

By studying rare, familial cases of early-onset AD, human geneticists have identified three disease genes in these conditions— genes for APP, and for two presenilins, PS1 and PS2. The presenilins are components of γ-secretase, which exists as an intramembrane protease complex. Mainly because of these genetic studies, as well as studies in animal models and postmortem studies of AD brains, the majority of AD researchers have focused on the APP processing pathway and/or on aggregation of Aβ to form plaques as intervention points for therapeutic strategies. The hypothesis that this is the central AD disease pathway is called the “amyloid hypothesis”.

Up until the publication of the new deCode report, of the 30-odd coding mutations in APP that have been found, around 25 are pathogenic, usually resulting in autosomal dominant early-onset Alzheimer’s disease. Coding mutations at or near the β- or γ-proteolytic sites have appeared to result in overproduction of either total Aβ or a shift in the Aβ40:Aβ42 ratio towards formation of Aβ42, which is the more toxic of the two Aβ peptide. Until now, mutations in APP have not been implicated in the common, late-onset form of Alzheimer’s disease.

In the new deCode study, the researchers studied coding variants in APP in a set of whole-genome sequence data from 1,795 Icelanders. They identified a single nucleotide polymorphism (SNP), designated as rs63750847. The A allele of this SNP (rs63750847-A) results in an alanine to threonine substitution at position 673 in APP (A673T). The A673T mutation was found to be significantly more common in the elderly (age 85-100) control group (i.e., those without AD) than in the AD group. The researchers therefore concluded that the mutation is protective against AD.

The researchers also found that in a cohort of individuals over 80, those who were heterozygous for the A673T mutation performed better in a test of mental capacity than did control subjects. The authors concluded that the A673T mutation not only protects against AD, but also against the mild cognitive decline that is normally associated with old age.

In cellular studies (i.e., studies in cultured cells transfected with genes coding for wild type or mutant APP) and in biochemical studies, the researchers found that APP carrying the A673T mutation undergoes about 40% less cleavage by BACE1 than does wild-type APP, resulting in 40% less production of both Aβ40 and Aβ42.

The researchers conclude that the strong protective effect of the A673T mutation against AD provides proof of principle for the hypothesis that reducing the β-cleavage of APP (e.g., by use of BACE1 inhibitors, such as those being  developed by some pharmaceutical companies) may protect against the disease. (However, success in developing BACE1 inhibitors has been elusive.) Moreover, since the A673T allele also protects against cognitive decline in elderly individuals who do not have AD, AD and age-related mild cognitive decline may be mediated through the same or similar mechanisms.

Despite this compelling genetic finding, amyloid pathway-targeting drugs have not shown efficacy in Phase 3 trials

In our January 26, 2010 blog article, we discussed Phase 2 clinical trials of bapineuzumab, a monoclonal antibody (MAb) drug that is specific for Aβ, in mild to moderate AD. In that article, we referred to the drug as “Elan/Wyeth’s bapineuzumab”, after the original developers of the drug. As the result of mergers and acquisitions, the drug is now referred to as “Pfizer/Janssen’s bapineuzumab”. Many commentators call it “bapi” for short.

As we discussed in that article, the overall result of the Phase 2 trial was that there was no difference in cognitive function between patients in the bapi-treated and the placebo groups. However, the study did not have sufficient statistical power to exclude the possibility that there was such a difference. Retrospective analysis of the data from the trial suggested that bapi-treated patients who were not carriers of the apolipoprotein E epsilon4 allele (ApoE4) showed improved cognitive function as compared to placebo treatment. Given that this conclusion was reached via retrospective analysis, the idea that the bapi was efficacious in ApoE4 noncarriers was only a hypothesis, which would require prospective clinical trials to confirm. Janssen and Pfizer had been conducted large Phase 3 trials of bapi, which they prospectively segregated into ApoE4 carrier and noncarrier groups in order to test this hypothesis.

As of the past several weeks, the results of these Phase 3 trials have come in. On July 23rd, 2012, Pfizer announced the top-line results of an 18-month Janssen-led Phase 3 study of intravenous bapi in approximately 1,100 patients with mild to moderate Alzheimer’s disease who carry at least one ApoE4 allele. The drug failed to meet its co-primary endpoints (change in cognitive and functional performance compared to placebo) in that study. On August 6, 2012, Pfizer announced the top-line results of the corresponding Phase 3 study of intravenous bapi in patients with mild-to-moderate Alzheimer’s disease who do not carry the ApoE4 genotype. Once again, the co-primary clinical endpoints were not met. Based on these results, the companies decided to discontinue all other intravenous bapi studies in patients with mild-to-moderate Alzheimer’s disease.

The bapi development program continues a history of amyloid pathway-targeting drugs that were taken into Phase 3 trials despite Phase 2 results that showed no statistically significant efficacy. For example, we cited the cases of Myriad Pharmaceuticals’ Flurizan (tarenflurbil) and Neurochem’s (now Bellus Health) Alzhemed (3-amino-1-propanesulfonic acid) in our January 26, 2010 blog article.

Leading industry commentator Matthew Herper of Forbes referred to the failure of bapi as “the latest piece of evidence of the drug industry’s strange gambling problem.” Johnson & Johnson (the parent company of Janssen) spent more than $1 billion to invest in Elan and get one-quarter of bapi, and Wyeth (later Pfizer) and Elan put the drug into Phase 3, despite the Phase 2 failure of bapi.

The temptation for pharmaceutical companies to take a chance on an AD drug such as bapi, Flurizan, and Alzhemed is driven by the complete lack of disease-modifying AD drugs, and the thinking that even a not-very-effective drug that receives FDA approval might generate billions of dollars in annual sales. In the case of bapi there was also that tantalizing suggestion that bapi might show efficacy in the subset of patients who lacked ApoE4.

In an August 16, 2012 article in Forbes, Dr. John LaMattina (the former President of Pfizer Global R&D) engages in informed speculation as to why bapi was moved into Phase 3. Dr. LaMattina (in contrast to critics like Mr. Herper, who discounted the ApoE4 retrospective analysis as “data-dredging” that was “likely to be due to chance”) referred to the efficacy signal of the Phase 2 trials as “mixed” due to the ApoE4 analysis. He stated that such “mixed results” present an “agonizing” dilemma for a pharmaceutical company.

In deciding whether to go forward Phase 3 trials of bapi, Dr. LaMattina further speculates that the decision might have been influenced by stakeholders such as AD patient advocates, and scientists who strongly believed in the science behind bapi, especially the amyloid hypothesis. Moreover, bapi had been shown to be relatively safe. In addition, dropping bapi would have caused public relations damage. Dr. LaMattina concludes, based on this analysis, “…this was a situation where these companies were in possession of a relatively safe drug, with a modest chance of success in being efficacious in what may be the biggest scourge that society will face.  How can you not make this investment?” He reminds us that pharmaceutical R&D “is a high risk, high reward business”.

Nevertheless, bapi joined Flurizan and Alzhemed on the list of high-profile amyloid-pathway failures. Now a Phase 3 trial of Lilly’s solanezumab, another MAb drug that targets Aβ, is nearing completion, with the results expected in September. Published Phase 2 results were designed to test safety, not efficacy, and 12 weeks of drug treatment gave no change in cognitive function. Although the results of the Phase 3 trial will not be known until they are reported, analysts expect the drug to fail because of its similarity to bapi.

Why don’t amyloid pathway-targeting drugs show efficacy in clinical trials, despite the compelling genetic evidence for the amyloid hypothesis?

The almost standard answer to that question given by scientists and clinicians who support the amyloid hypothesis is that we have been testing the drugs too late in the course of AD progression, after the damage to the brain has become irreversible. Roche/Genentech is testing this idea in its clinical trials of its drug candidate crenezumab (licensed from AC Immune), which is yet another MAb drug that targets Aβ. In a 5-year Phase 2a clinical trial, Genentech is testing intravenous crenezumab in 300 cognitively healthy individuals from a large Colombian kindred who harbor the Glu280Ala (codon 280 Glu to Ala substitution) PS1 mutation. This mutation causes dominant early−onset familial AD, and is associated with increased levels of Aβ42 in plasma, skin fibroblasts, and the brain. Family members with this mutation begin showing cognitive impairment around age 45, and full dementia around age 51.

Genentech is conducting this trial in collaboration with the Banner Alzheimer’s Institute and the National Institutes of Health. The company says that this trial is the first-ever AD prevention study in cognitively healthy individuals. Genentech further says that the trial may help to determine if the amyloid hypothesis is correct–more specifically, it may help to determine if a drug that works by depleting amyloid plaques can be effective in preventing and/or treating AD.

Moreover, Genentech states that there is significant unmet medical need within this Colombian population. This large extended family may have as many as 5,000 living members, and no other population in the world offers a sufficiently large number of mutation carriers close to the age of potential disease onset for a study to determine whether a prevention treatment may work. This effort by Genentech thus represents an application of a rare disease strategy to AD.

It is also possible, however that drugs that work by lowering levels of Aβ will not be efficacious in treating AD, even if administered early in the disease process. This may be true despite the findings of the new genetic study by the deCode Genetics group. For example, in their Nature News and Views article, Drs. De Strooper and Voet remind us that if the A673T mutation indeed works via lowering of Aβ levels, it works via lifelong lowering of Aβ, not lowering of Aβ in patients who already have AD, as in all clinical trials so far of anti-Aβ antibodies. (Even Genentech’s Colombian trial may involve lowering of Aβ levels relatively late in the course of exposure of patients to a disease process that will result in AD.)

Moreover, as these authors speculate on the basis of work on another mutation at the same site in the APP protein, it is possible that the protective effect of the A673T mutation may be due to changing the aggregation properties of Aβ peptides, resulting in a less-toxic form of Aβ. If true, this would mean that the protective effect of the A673T mutation is due to qualitative, rather than quantitative changes in Aβ. In that case, the finding of protection from AD by the A673T mutation might not be as predictive of the efficacy of such Aβ-lowering treatments as the use of anti-Aβ MAb drugs as drug developers might like.
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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.

Huntington's disease. Dr. Steven Finkbeiner. http://bit.ly/q48xdX

In the June 10, 2011 edition of Cell, there is a Leading Edge Preview (short review) and a research Article on a surprising new potential therapeutic strategy for neurodegenerative disease. The Preview is by Peter H Reinhart (Proteostasis Therapeutics, Cambridge MA) and Jeffery W Kelly (Skaggs Institute and Scripps Research Institute, La Jolla CA), and the the Article (Zwilling et al.) is by Paul J Muchowski (Gladstone Institute of Neurological Disease, University of California at San Francisco) and his colleagues. In addition to Dr. Muchowski’s academic collaborators, researchers from the Novartis Institutes for BioMedical Research in Basel, Switzerland participated in that work.

In previous studies, the kynurenine pathway (KP) of tryptophan degradation has been linked to such neurodegenerative diseases as Huntington’s disease (HD) and Alzheimer’s disease (AD). The kynurenine pathway (KP) is the most important pathway for degradation of the amino acid tryptophan in humans. Patients with HD and AD have elevated levels of two metabolites in the KP–quinolinic acid (QUIN) and 3-hydroxykynurenine (3-HK)–in their blood and brains. Studies in rodents have implicated both of these metabolites in pathophysiological processes in the brain. QUIN, which is a selective N-methyl-D-aspartate (NMDA) agonist, has been implicated in excitotoxicity, which is a mechanism by which excessive stimulation of glutamate receptors causes neuronal dysfunction and cell death. (NMDA receptors constitute a major type of glutamate receptor.) 3-HK is a free radical generator that can mediate neuronal cell death. Intrastriatal injection of QUIN in experimental animals duplicated many of the pathological features of HD. Administration of QUIN to other areas of the brain of experimental animals also duplicated features of AD, such as destruction of  basal forebrain cholinergic neurons projecting to the cortex and memory deficits.

In contrast, kynurenic acid (KYNA), which is formed in a side arm of the KP by conversion of kynurenine by the enzyme kynurenine aminotransferase, appears to be neuroprotective. KYNA is an antagonist of ionotropic excitatory amino acid receptors. In particular, KYNA blocks the neuropathological effects of QUIN. Kynurenine aminotransferase is found in the brain, and is thus capable of transforming kynurenine (which is actively transported into the brain by a neutral amino acid transporter) to KYNA in that organ. The concentration of brain KYNA is often decreased in HD and AD.

All of these studies in rodents were done in the 1980s or 1990s. However, no therapies based on that research have yet been advanced into the clinic.

Studies with JM6, a prodrug small-molecule inhibitor of kynurenine 3-monooxygenase, in wild type mice

In the Zwilling et al. study, researchers studied inhibition of  kynurenine 3-monooxygenase (KMO) as a strategy for inducing a more favorable ratio of KYNA to QUIN in vivo. KMO is the enzyme in the KP that converts kynurenine to 3-hydroxykynurenine, which is further converted in three steps to QUIN. KMO is found at high levels in peripheral blood macrophages and other immune cells in the blood. Inhibition of  KMO results in elevation of kynurenine levels in the blood. This kynurenine can then enter the CNS, where it is converted to the neuroprotective metabolite KYNA.

In 1996, researchers at Roche published the synthesis and characterization of a KMO inhibitor, 3,4-dimethoxy-N-[4-(3-nitrophenyl)thiazol-2-yl]benzenesulfonamide, known as Ro 61-8048. Subsequent studies showed that Ro 61-8048 was neuroprotective in rodent models of brain ischemia and cerebral malaria, and in a model of levodopa-induced dyskinesias (movement disorders) in parkinsonian monkeys.

However, Zwilling et al found that Ro 61-8048 was metabolically unstable. They therefore developed an orally bioavailable “slow-release” prodrug of Ro 61-8048, 2-(3,4-dimethoxybenzenesulfonylamino)-4-(3-nitrophenyl)-5-(piperidin-1-yl)methylthiazole (JM6). JM6 was designed to be converted to Ro 61-8048 in the gut. However, when JM6 was administered orally to wild type mice, the researchers found high levels of both JM6 and Ro 61-8048 in the blood. However, neither JM6 nor Ro 61-8048 accumulated to any great extent in the brain, and the brain concentration of both drugs was insufficient to inhibit KMO. Thus neither JM6 nor Ro 61-8048 appeared to cross the blood-brain barrier.

Despite the failure of JM6 and Ro 61-8048 to cross the blood-brain barrier, oral administration of JM6 results in increased brain levels of KYNA. Administration of an inhibitor of kynurenine aminotransferase to the brain inhibits the increase in levels of KYNA in that organ. This is consistent with the hypothesis that Ro 61-8048 inhibition of KMO in the blood results in elevated blood levels of kynurenine, which is transported into the brain. Kynurenine aminotransferase in the brain converts the kynurenine to KYNA. In addition, elevation of KNYA levels in the brain coincides with a decrease in extracellular concentrations of brain glutamate. This is consistent with earlier studies that showed that increases in brain KYNA, via inhibition of presynaptic α7 nicotinic receptors, reduce extracellular brain glutamate levels. Blocking of presynaptic α7 nicotinic receptors results in inhibition of glutamate release from neurons that bear these receptors. Reduction in extracellular brain glutamate levels may be responsible for KYNA’s neuroprotective effects, via reduction of excitotoxicity. However, at high local concentrations of KYNA, this metabolite may also block glutamate receptors directly.

Studies with JM6 in mouse models of Alzheimer’s and Huntington’s disease

After performing these studies in wild type mice, the researchers then tested the effects of JM6 in mouse models of AD and HD. Transgenic J20 mice that express a mutant form of the human amyloid precursor protein (hAPP) develop spatial memory deficits and synaptic loss starting at 4-5 months of age. Oral administration of JM6 starting at 2 months of age gave significant improvement in spatial memory in mice tested at 6 months of age, as compared to untreated J20 APPtg (transgenic APP) mice. JM6 treatment also prevented synaptic loss in J20 APPtg mice. However, JM6 treatment had no effect on beta amyloid (Aβ) plaque load, which was increased in the hippocampus and cortex of JM6-treated and untreated J20 mice. Under the amyloid hypothesis of AD pathogenesis, Aβ plaques are central to the causation of AD.

J20 APPtg mice had lower brain KYNA levels than wild type littermate controls, consistent with findings in AD patients. Treatment of J20 APPtg mice with oral JM6 (over a 120 day period) increased brain and plasma levels of KYNA. KMO activity, and 3-HK and QUIN levels in the brains and QUIN levels in the plasma of J20 APPtg mice treated with JM6 were not significantly different from levels in wild type controls.

The researchers also tested the effects of oral JM6 administration in R6/2 mice, the best characterized mouse model of HD. HD is a trinucleotide repeat disorder in which a cytosine-adenine-guanine (CAG) repeat segment in exon one of the huntingtin gene (HTT) (encoded in the germline of the individual) exceeds a normal range. The HD CAG repeat region encodes 36 or greater repeated glutamines in the polyQ region of the huntingtin protein (Htt); people without the disease have fewer than 36 glutamines. The disease-associated huntingtin protein is neurotoxic.

In the R6/2 mouse model, mice are transgenic for the 5′ end of the human HD gene carrying a large CAG repeat expansion. These mice develop a progressive neurologic disease, including motor deficits, weight loss, and premature death. The researchers started oral JM6 administration at 4 weeks of age, which is an early symptomatic stage in R6/2 mice. JM6 administration had a dramatic dose-dependent effect on survival. JM6 treatment did not affect the weight of the mice, but it did modestly improve performance on an accelerating rotarod (a measure of motor performance). JM6 treatment also prevented synaptic loss and reduced CNS inflammation in R6/2 mice.

JM6 treatment of R6/2 mice did not influence the size or abundance of neuronal inclusion bodies in these mice. These inclusion bodes are related to those seen in HD in humans. Thus in mouse models of both AD and HD, JM6 treatment did not affect the aggregated proteins (Aβ plaques and mutated Htt inclusion bodies, respectively) that are thought to cause the diseases; nevertheless, they ameliorated disease symptoms.

In chronically JM6-treated J20 APPtg (AD model) and R6/2 (HD model) mice, although JM6 and Ro 61-8048 accumulated in plasma, brain levels of these compounds were nil. Thus JM6 treatment of both neurodegenerative disease models resulted in increased brain levels of KYNA and neurodegenerative disease amelioration, despite the inability of JM6 and R0 61-8048 to cross the blood-brain barrier.

JM6 treatment is a surprising therapeutic strategy for neurodegenerative diseases for three reasons.

• JM6 cannot cross the blood-brain barrier, which is almost always a sine qua non of CNS disease therapy.
• JM6 ameliorates disease without affecting the protein aggregates that are usually thought to cause the diseases.
• JM6 ameliorates multiple neurodegenerative diseases.

How might this novel therapeutic strategy be moved into the clinic?

Clinical trials in AD are notoriously long and expensive. Therefore, Drs. Reinhart and Kelly in their Preview suggest that it might be best to first conduct clinical trials in HD, since the cause of HD is much better understood than for AD, and disease progression in placebo controls is better characterized than for AD.

The results of the mouse model studies suggest that JM6 will ameliorate, but not cure, HD and AD. However, since there are no disease-modifying therapies for either disease, demonstrating amelioration of HD comparable to that seen in the mouse models (provided the drug is proven to be safe in humans) will almost certainly gain approval for the drug. However, in the long run JM6 would need to be combined with other disease-modifying drugs to more effectively treat diseases such as HD and AD. Since other drugs  developed for neurodegenerative diseases will almost always act directly in the brain, combining them with JM6, which does not enter the brain, may help maximize the clinical benefit of a combination therapy. It may also aid in minimizing the toxicity of combination therapies (since the two drugs would not interact in the brain).

Lennart Mucke, MD, the director of the Gladstone Institute, suggested that Dr. Muchowski and his colleagues might begin testing JM6 in patients within the next two years.

The ability of JM6/Ro 61-8048 to ameliorate neurodegenerative diseases in animal models also raises questions as to the mechanisms by which it does so, and how these mechanisms might interact with mechanisms thought to be central to the pathobiology of neurodegenerative diseases (e.g., the amyloid and Tau pathways in AD, huntingtin inclusions, inflammatory pathways, apoptotic pathways, etc.). What are the molecular mechanisms downstream from KYNA elevation? Is JM6 treatment prophylactic, or is it efficacious in animals (and in humans) that are already suffering disease symptoms and that have pathogenic protein aggregates?

Research to answer these questions may lead to still newer therapeutic strategies, including potentially more effective combination therapies for neurodegenerative diseases that include JM6.

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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.

I will lead a workshop entitled “Developing Improved Animal Models in Oncology and CNS Diseases to Increase Drug Discovery and Development Capabilities” at the World Drug Targets Summit in Cambridge MA in July 2011.

Workshops will be held on July 19, and the main conference on July 20-21. I am planning to attend the entire conference.

Our workshop will be a discussion of 2-3 case studies involving development of novel animal models in oncology and CNS diseases, aimed at more closely modeling human disease than current models. Drug discovery and development in these therapeutic areas has been severely hampered by animal models that are  poorly predictive of efficacy. This is a major cause of clinical attrition in these areas.

We shall discuss the implications of these case studies for developing novel therapeutic strategies, target identification and validation, drug discovery, preclinical studies, and reducing clinical attrition. We shall also discuss hurdles to industry adoption of novel animal models developed in academic laboratories.

The main conference will focus on ways of building successful target strategies to minimize drug attrition in the clinic, and specifically how to identify and validate targets that can lead to commercially differentiated products. Speakers will include target discovery and validation leaders from such companies as Pfizer, Merck, NeurAxon, Gilead Sciences, Boehringer Ingelheim, Merrimack Pharmaceuticals, Bayer Schering Pharma AG, FORMA Therapeutics, Roche, Novartis, Tempero Pharmaceuticals, UCB Pharma, Infinity Pharmaceuticals, and from such academic institutions as Harvard Medical School.

The conference agenda and brochure, as well as online registration, are available on the conference website.

Source: Mnolf http://bit.ly/gEg5yo

In our November 11, 2010 blog post, we discussed the September 2010 acquisition of Seattle biotech firm ZymoGenetics by Bristol-Myers Squibb (BMS). Also in November 2010, Nature Biotechnology published an article about this acquisition, in which I was quoted.

As our blog post states, most commentators believe that BMS’ main motivation for acquiring ZymoGenetics was to gain full ownership of ZymoGenetics’ pegylated interferon-lambda (Peg-IFN-λ) program for treatment of hepatitis C (HepC). The two companies had been been collaborating to develop Peg-IFN-λ since January 2009. However, ZymoGenetics was much more than a one-product company. Its other pipeline drugs included interleukin-21 (denenicokin) for treatment of metastatic melanoma, which is now in Phase 2b development.  And over the years, ZymoGenetics has proven to be an important drug discovery engine, from the days in which it was a division of Novo Nordisk, and continuing on into 2010.

Now–as of the first week of January 2011–we learn that former ZymoGenetics CEO Douglas E. Williams Ph.D. has been named as Executive Vice President, R&D., at Biogen Idec (Weston, MA).

Dr. Williams has over 20 years of biotech R&D and senior leadership experience. He was the chief technology officer at Seattle biotech firm Immunex, and played a significant role in the discovery and development of the blockbuster tumor necrosis factor (TNF) inhibitor etanercept (Enbrel). After Amgen’s 2002 acquisition of Immunex, Dr. Williams resigned from Amgen later in 2002, and moved on to Seattle Genetics in 2003 as chief scientific officer (CSO). In 2004, he joined ZymoGenetics as chief scientific officer (CSO). On January 1, 2009, he became ZymoGenetics’ CEO.

During his tenure as CSO and then CEO of ZymoGenetics, the company achieved considerable success in the development of its pipeline products, especially Peg-IFN-λ and  interleukin-21. And the company entered into its $1.1 billion agreement with BMS to codevelop Peg-IFN-λ. However, during Dr. Williams’ tenure as CEO, ZymoGenetics had some financial rough spots, mainly caused by the lack of commercial success of the company’s first self-marketed product, recombinant thrombin (Recothrom). This was compounded by failed clinical trials of the company’s immunomodulatory drug atacicept, which is now being developed by Merck Serono. After a series of downsizing moves, ZymoGenetics agreed to be acquired by BMS in October 2010. In November 2010, Dr. Williams left ZymoGenetics and became a “free agent”, followed by his joining Biogen Idec in January 2011.

Biogen Idec, which was founded as Biogen in 1978 and merged to form Biogen Idec in 2003, is one of the world’s major biotech companies, and has long been a major fixture of the Boston-Cambridge biotech scene. The company had 2009 revenue of $4.38 billion. However, Biogen Idec had some ups and downs of its own in recent years. It has been targeted for reorganization, breakup, or sale by activist investor Carl Icahn, who currently owns 5.4% of the company’s shares, and who controls three seats on Biogen Idec’s board as the result of  series of proxy fights.

During 2010, long-time CEO (and Icahn target) James Mullen retired from the company, and was succeeded by former Exelixis (South San Francisco, CA) CEO George Scangos, Ph.D. In January 2011, at the same time as Dr. Williams joined Biogen Idec, the company announced that Steven H Holtzman (who was formerly the CEO of Cambridge MA biotech Infinity Pharmaceuticals) would be executive vice president of corporate development.

Biogen Idec derives most of its revenues from three drugs–multiple sclerosis (MS) treatments Avonex (interferon beta-1a) and Tysabri (natalizumab), and Rituxan (rituximab), a treatment for non-Hodgkin’s lymphoma. Tysabri is also approved for treatment of Crohn’s disease and is co-marketed with Élan, and Rituxan is also approved for rheumatoid arthritis and is co-marketed with Roche/Genentech.

Among these products, Avonex (which was introduced in 1996, and is Biogen Idec’s largest selling drug) and Rituxan are maturing. In particular, Avonex faces increased competition from newer products. Growth in sales and revenues from these two products is slowing.

Tysabri is intended to be Biogen Idec’s growth driver. However, Tysabri has had major issues. Soon after its launch in 2004, Biogen Idec withdrew Tysabri from the market, after it was linked with three cases of the rare neurological condition progressive multifocal leukoencephalopathy (PML), when co-administered with Avonex.  PML is caused by the JC virus, which is normally controlled by he immune system, but which can rarely cause disease in patients under immunosuppresive therapies such as the Tisabri/Avonex combination. After a safety review and no further deaths, the drug was returned to the US market in 2006 under a special prescription program, in part as the result of pleas by MS patients. However, since then additional cases of PML–including fatalities–have occurred.

In December 2010, Biogen Idec and Elan submitted a supplemental Biologics License Application (sBLA) to the FDA and a Type II Variation to the European Medicines Agency (EMA), proposing updated product labeling to include anti-JC virus antibody status. The companies propose using this test to help stratify the risk of developing PML in patients treated with Tysabri. Biogen Idec expects that a commercial anti-JC virus antibody test will be available later in 2011. It is expected that this test will help to lower the risk of Tysabri-associated PML, which is low to begin with.

In addition, Tysabri faces potential strong competition from the first approved oral treatment for MS, fingolimod (Novartis’ Gilenya), which the FDA approved in September 2010. The day that Gilenya was approved, Biogen Idec issued a press release acknowledging the desire of MS patients for an oral treatment, and noting that it also has an oral MS treatment in Phase 3 trials, BG-12.

Biogen Idec estimated that as of the end of 2010, approximately 56,600 MS patients were using Tysabri worldwide. That represented an increase of 1,700 patients in the fourth quarter and 8,200 patients over the course of 2010.

In November 2010, Dr. Scangos announced a reorganization of Biogen Idec. As of that date, the company would focus on neurology, and leverage its strengths in biologics research and development (R&D) and manufacturing to pursue select, high-impact biologic therapies and to be a leading collaborator in the biotechnology industry. (Biogen Idec’s efforts in biologics might, for example, include entering the biosimilars market.) Biogen Idec also terminated its efforts in cardiovascular medicine, and is seeking to spin out or outlicense its oncology programs.

The restructuring also involved consolidating its sites, and reducing its work force by 13%, or 650 full-time positions. As a result of the restructuring, the company expected to save approximately $300 million annually. Dr. Scangos said that the restructuring would enable Biogen Idec to gain focus and to become more nimble.

The company intends to become a global leader in neurological diseases. This will involve not only maximizing the potential of its two marketed MS drugs, but also bringing forward its MS pipeline products. Biogen Idec will also pursue programs in amyotrophic lateral sclerosis (ALS)/Lou Gehrig’s disease and Parkinson’s disease.

Biogen Idec’s late-stage products in neurology are shown in the table. (Please click on the table to read it clearly.) The company intends to launch five new products by 2015.

Source: Haberman Associates

Although Biogen Idec now has several late-stage products moving toward commercialization, the company’s R&D productivity has lagged in recent years. The company has not launched a new drug since Tysabri was approved in 2004. Dr. Williams says that he is planning a review of he company’s R&D organization and its pipeline. He intends especially to focus on Biogen Idec’s early- and mid-stage programs. Dr. Williams intends to boost these programs both via internal R&D and via licensing and acquisition to bring in externally developed compounds.

Overall, Dr. Williams hopes to return Biogen Idec to the culture of a biotech start-up. “We don’t have the luxury of sitting back. We have to push hard like we are a scrappy, hungry, cash-starved biotech,” he says. Dr. Williams’ statement is in accord with that of Dr. Scangos, who speaking at the J.P. Morgan 29th Annual Healthcare Conference in January 2011, said that Biogen Idec had the choice of being either a small pharma or a big biotech. The company has chosen to be a big biotech.

We wish Dr. Williams–working together with George Scangos and Steven Holtzman–well as they work to return Biogen Idec to productive and innovative R&D.

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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.

In Chapter 7 of our March 2010 book-length report, Animal Models for Therapeutic Strategies (published by Cambridge Healthtech Institute), we discussed recently-developed methods for producing knockout rats. These methods included zinc-finger nuclease (ZFN) genome editing and transposon mutagenesis in cultured spermatogonial stem cells. Our most extensive discussion was of the ZFN editing technology, which was developed by Sangamo BioSciences (Richmond, CA), and is the basis of the knockout rat models marketed by Sigma-Aldrich Advanced Genetic Engineering (SAGE). We also mentioned the SAGE knockout rat platform in an earlier blog post.

In Chapter 7 of our report, we also mentioned that it would now also be possible to construct knockout rats “the good old way”–using the same homologous recombination technology that researchers use to create knockout mice. Drs. Mario R. Capecchi, Martin J. Evans and Oliver Smithies were awarded the Nobel Prize in Physiology or Medicine for 2007 for having developed this technology in the late 1980s. To construct knockout mice, researchers isolate and culture mouse embryonic stem (ES) cells. These are derived from the inner cell masses of preimplantation mouse blastocyst embryos, and grown under particular culture conditions. These cells are subjected to homologous recombination with a vector containing a truncated version of the gene to be targeted, to eventually yield knockout mouse strains.

It has not been possible to develop knockout rats because the conditions for culturing ES cells worked only for a few inbred mouse strains, and not at all for either most mouse strains or for the rat. Conditions for culturing mouse ES cells are complex. They involve the use of feeder fibroblasts and/or the cytokine leukemia inhibitory factor (LIF), together with selected batches of fetal calf serum or bone morphogenetic protein (BMP). These culture conditions had been determined empirically.

In 2008, Dr. Austin Smith (Director of the Wellcome Trust Centre for Stem Cell Research, University of Cambridge [Cambridge, UK]) and his colleagues developed culture conditions that allowed them to culture rat ES cells that were capable of transmitting their genomes to offspring. These ES cells could also be used to produce knockout rats.

Dr. Smith and his colleagues realized that the standard conditions for culturing mouse ES cells expose the cells to inductive stimuli (e.g., fibroblast growth factor 4 [FGF4]), which can activate ES cell commitment and differentiation. The aim of ES cell culture is to expand the cell population while maintaining pluripotency.  The researchers therefore cultured rat ES cells with leukemia inhibitory factor (LIF)-expressing mouse fibroblast feeder cells, in a medium containing two or three small-molecule inhibitors of pathways involved in ES cell commitment and differentiation, plus human LIF. (LIF supports proliferation of ES cells in an undifferentiated state.) This medium is known as 2i (for 2-inhibitors) or 3i medium.

Rat ES cells cultured in this manner expressed key molecular markers found in mouse ES cells. They also, when injected into blastocysts, can give rise to chimeric rats; i.e., they transmute their genomes into offspring. Such cultured rat ES cells thus are capable of being used to construct knockout rats.

In the 9 September 2010 issue of Nature, Dr. Qi-Long Ying (University of Southern California, Los Angeles CA) and his colleagues published the first study describing construction of a knockout rat strain via homologous recombination. (Dr. Ying, then at the University of Edinburgh, had been on the team led by Austin Smith that developed culture methods for rat ES cells.) This rat strain is a p53 gene knockout. The researchers designed a targeting vector to disrupt the p53 tumor suppressor gene via homologous recombination; the vector allowed for antibiotic selection for cells that had been successfully targeted. They transfected this vector into rat ES cells cultured in 2i medium, performed the antibiotic selection, and cultured the resistant cells. These cells were shown to have one of their two (since they were diploid) p53 genes disrupted. The researchers were able to routinely generate p53-targeted rat ES cells by this method. They also injected p53-targeted rat ES cells into rat blastocysts, transferred the blastocysts into pseudo-pregnant female rats, and obtained chimeric offspring. However, in the first studies, the p53-targeted rat ES cells exhibited low germline transmission efficiency.

In the mouse system, the failure of cultured ES cells to contribute to the germline is often caused by chromosomal abnormalities in the ES cells. This was also the case with the rat ES cells. In the case of mouse ES cell culture, cells with chromosomal abnormalities have a selective growth advantage over those with normal karyotypes. The smaller, slower-growing mouse ES cell clones tend to have normal karyotypes, and to give improved germline transmission. The researchers therefore subcloned their p53 gene-targeted rat ES cells, and selected for small, slower-growing subclones. These rat ES cell subclones were euploid. When injected into blastocysts, these rat ES cell clones gave rise to chimeric rats that the researchers further bred to generate homozygous p53 gene-targeted (i.e., p53 knockout, or p53 homozygous null) rats.

Using these methods, it should be possible to generate knockout rats for other genes routinely, including sophisticated knockouts such as tissue-specific gene knockouts.

Meanwhile, SAGE has generated p53 knockout rats, using its ZFN technology. As with the original p53 knockout mice, these rats develop normally, but are prone to development of spontaneous tumors. p53 knockout rats generated via homologous recombination should also be susceptible to spontaneous generation of tumors. However, as yet no data has been published. It remains to be seen which of these systems–p53 knockout mice or p53-knockout rats generated via either homologous recombination or ZFN editing, will be most useful in basic cancer research, or in such applications as carcinogenicity screening of compounds.

Why is the ability of researchers to generate knockout rats, as opposed to knockout mice, so important? The anatomy and physiology of the rat is closer to humans than is the mouse. There are also many rat models of complex human diseases (especially cardiovascular and metabolic diseases) that are better disease models than those based on inbred mouse strains. In addition, the larger size of the rat facilitates experimental procedures that involve surgery, getting blood samples for analysis, or isolation of specific cell populations. Researchers usually prefer rats over mice for physiological and nutritional studies, studies of psychiatric diseases, and in cases when a particular rat disease model is more applicable to a project than mouse strains. The rat is also widely used in preclinical efficacy and safety studies.

With respect to models for central nervous system (CNS) diseases, gene-targeted and transgenic rat models may be expected to be better than mouse models. The rat is more intelligent than the mouse, and has a bigger brain. Unlike mice, rats are sociable and easily trained. Moreover, there are some new rat models of cognition, which enable researchers to perform studies that they previously thought could only be done in nonhuman primates. And optogenetics technology, which allows researchers to engineer specific neurons so that their activity can be switched on or off with laser light, in order to dissect the role of these neurons in behavior, is being implemented in rats. These new developments, together with knockout and transgenic technologies, should allow researchers to develop new rat models of psychiatric diseases, as well as of neurodegenerative diseases such as Alzheimer’s and Parkinson’s diseases. The lack of good animal models is a major factor in the high clinical attrition rate of CNS drugs, so new models are needed. There are of course no guarantees that novel rat models will help lower CNS drug attrition rates, but it is well worth trying these new approaches.

As we also discussed in Chapter 7 of Animal Models for Therapeutic Strategies, researchers are also interested in developing animal models based on mammalian species other than the mouse and the rat. We discussed methods for gene targeting by recombinant adeno-associated virus (rAAV) in pigs and ferrets in that chapter. In principle, ZFN editing technology could be also used to generate gene knockouts in mammalian species other than rodents. Moreover, the type of research done in the rat by Austin Smith, Qi-Long Ying, and their colleagues might be applied to developing culture conditions for ES cells of other mammalian species, which could set the stage for developing gene knockouts in these species via homologous recombination.