Sunday November 22 2009 | Biotechnology feed | All feeds
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Sunday November 22 2009 | Biotechnology feed | All feeds
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Four million Americans
currently suffer from Alzheimer's disease (AD), and experts estimate that 22
million people around the world will be so afflicted by 2025.
Acetylcholinestase inhibitors dominate the current AD market driving value of
this therapeutic class to over US$1.2 billion in 2001. Although current AD
treatments center on treating symptoms, future strategies are more likely to
modify the course of the disease. The most widely accepted hypothesis on the
etiopathogenesis of AD proposes that aggregates of the amyloid protein,
trigger tau hyperphosphorylation and neural degeneration. Neurotoxicity is
thought to be due to altered calcium regulation, mitochondrial damage and/or
immune stimulation. The retinoids play a key role
in differentiation, proliferation and apoptosis and as a result over 30
naturally occurring and synthetic analogs of retinoic acid are now either in
development or on the market. The focus of retinoid attention has been skin
conditions and cancer, however although efficacy has been demonstrated in
acute promyelocytic leukemia and various skin cancers, the extension of
therapeutic benefit to other diseases has been limited. In our recent dossier
"Retinoids: An A-Z guide to their biology, therapeutic opportunities
& pharmaceutical development" (click
here for access) we set out to offer a full and up to date insight into
the complexities of the retinoids. Furthermore we describe how these
complexities relate to the limited therapeutic potential of the retinoids and
strategies for overcoming these limitations. As our understanding of the
retinoids increases so do their therapeutic indications. For example COPD and
obesity have both recently emerged as targets for retinoic acid receptor
ligands. Most recently Boston based researchers have put forward the
hypothesis that late onset AD is influenced by the availability in brain of
retinoic acid. This hypothesis is based on a body of genetic, metabolic, and
environmental/dietary evidence. For example, significant genetic linkages to
AD are demonstrated for markers close to four of the six retinoic acid
receptors; three of the four retinol-binding proteins and the retinoic
acid-degrading cytochrome P450 enzymes (for further information on each of
these proteins and retinoid pathways go to our retinoid dossier).
Retinaldehyde dehydrogenase (RLDH), the enzyme that forms retinoic acid from
retinaldehyde, was present in hippocampus, frontal cortex, and parietal
cortex, and its activity in the hippocampus and parietal cortex of Alzheimer
diseased brains was 1.5- to 2-fold higher compared to controls. In contrast,
the RLDH activity of frontal cortex was the same for both Alzheimer diseased
and control groups. Retinoid responsive transgenes
have been shown to be highly active in the hippocampus and the activation of
such genes has been reported to facilitate neurotrophin-induced maturation of
stem cells into neurons. While retinoic acid may be important in neurogenesis,
defects in the retinoid pathway may lead to impaired neurological function.
This is supported by data showing that retinoid receptor expression is reduced
in aged mice and that this is related to behavioral deficits consistent with
diminished cognitive function. This could be reversed by retinoic acid
treatment. This and the genetic/molecular evidence linking the retinoids to
Alzheimer’s disease suggests that retinoic acid or its mimics may represent
a useful approach to the treatment of cognitive disorders. Of particular
interest to the treatment of Alzheimer’s disease it has been shown that the
reductions in acetylcholine content caused by Abeta42 could be prevented by a
co-treatment with retinoic acid. On the other hand however,
evidence is also available to suggest that retinoic acid can increase secreted
Abeta40 and Abeta42. Of interest the response was biased towards the latter,
more cytotoxic form of beta amyloid. Careful drug design could therefore
conceivably lead to the development of a treatment that both improves
cognition and also limits the suggested underlying cause of Alzheimer’s
disease. With the advent of improved
models of Alzheimer's disease as well as a greater inventory of
pharmacological tools able to probe retinoid biology, further studies designed
to probe this provocative link between the retinoids and AD are eagerly
awaited. Adapted from Goodman & Pardee, Proc Natl Acad Sci U S A 2003 Mar 4;100(5):2901-5 - Interested in collaborating with this group? Contact LeadDiscovery or the authors direct.
Interested in collaborating with this group? Contact leaddiscovery@bioportfolio.co.uk Projects such as these are overviewed in full DiscoveryDossiers. LeadDiscovery and BioPortfolio aims to provide reliable, insightful analysis on the biotechnology industry. However, this information is provided "as is" and no representations or warranties either express or implied of completeness, accuracy, or of any other nature are made with respect to this information. This information is neither an offer to sell nor a solicitation to buy the securities of any company. This information contains forward-looking statements, which involve risks and uncertainties which may not be listed. The biotechnology industry is an emerging industry and the securities of the companies mentioned in this report have a very high degree of risk and volatility. For this reason, this information is supplied on the condition that the reader will make his or her own determination as to its suitability for any purpose prior to any use of this information. The employees and officers of LeadDiscovery and BioPortfolio may hold positions in some or all of the stocks discussed in this report. This abstract has been produced by LeadDiscovery Ltd. Founded by life scientists for life scientists we aim to help industry identify cutting edge drug discovery options and academic/biotech institutions maximize the potential of their research. Abstracts strictly reflect the opinion of LeadDiscovery's editorial panel. While all reasonable efforts are made to ensure the accuracy of information provided LeadDiscovery and the publisher BioPortfolio, takes no responsibility for incorrect or misleading information. LeadDiscovery is designed for educational and drug development purposes only and is not intended or designed to offer medical advice or advice of any sort, and must not be used for such purpose. The information provided through LeadDiscovery and BioPortfolio should not be used for diagnosing or treating a health problem or a disease and no reliance should be placed on any information contained in this abstract or elsewhere on LeadDiscovery's and BioPortfolio's website. It is not intended to be a substitute for professional care. If you have or suspect you may have a health problem, you should consult your physician or other health care provider. |
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