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New Compounds Effective Against Alzheimer's Disease Onset And
Progression (And Parkinson's?)

Public release date: 8-Nov-2004
Contact: Elizabeth Crown
[log in to unmask]
312-503-8928
Northwestern University

New compounds effective against Alzheimer's disease onset and
progression

CHICAGO --- Drug discovery researchers at Northwestern University
have developed a new class of compounds that have the potential to
reduce the inflammation of brain cells and the neuron loss associated
with Alzheimer's disease.

The new class of compounds are aminopyridazines. The original
compound, called MW01-070C, is used in an injectable form. More
recently developed compounds, such as MW01-2-151WH and MW01-5-188WH,
can be taken by mouth.

The compounds were designed and synthesized in the laboratory of D.
Martin Watterson, J. G. Searle Professor of Molecular Biology and
Biochemistry and professor of molecular pharmacology and biological
chemistry, Northwestern University Feinberg School of Medicine, using
a synthetic chemistry platform developed by the Northwestern Drug
Discovery Program for the rapid discovery of new potential
therapeutic targets.

The aminopyridazines are targeted for the potential treatment of
certain neurodegenerative diseases that are characterized by
neuroinflammation and neuronal loss, such as Alzheimer's disease,
Parkinson's disease, stroke and traumatic brain injury. The compounds
inhibit over-activation of glia, important cells of the central
nervous system that normally help the body mount a response to injury
or developmental change but are overactivated in certain
neurodegenerative diseases.

The efficacy and safety of the compounds in an Alzheimer's disease
animal model was evaluated in collaboration with Linda J. Van Eldik,
professor of cell and molecular biology at Feinberg.

The scientists described their Alzheimer's disease drug discovery
efforts in recent issues of the Journal of Molecular Neuroscience and
the journal Neurobiology of Aging, and a publication that will appear
in early 2005 in the journal Current Alzheimer Research. The studies
have important implications for future drug development because they
provide a proof of concept that targeting neuroinflammation with
aminopyridazines is a viable Alzheimer's disease drug discovery
approach that has the potential to modulate disease onset and
progression, Van Eldik said.

Deposition of the beta-amyloid plaques and neurofibrillary tangles of
Alzheimer's disease is associated with glial activation, loss of
neurons and decline of cognitive function.

Long-term or excessive activation of glia increases production of
chemokines and cytokines, such as interleukin-1 beta (IL-1b), and
oxidative stress-related enzymes, such as a highly active form of
nitric oxide synthase (iNOS).

The excessive production of the inflammation-related substances can,
in turn, contribute to further exacerbation of the disease process.

IL-1b is involved in glial inflammatory and neuronal dysfunction
responses, and variants of the IL-1 gene are associated with
increased risk for Alzheimer's disease. The iNOS induced as a result
of glial activation generates nitric oxide (NO), which can exist in
toxic forms that damage neurons.

Therefore, development of new compounds that can modulate these
disease-linked biological processes may represent alternative
therapeutic approaches and lead to future identification of new drug
discovery targets, Van Eldik said.

Van Eldik and co-researchers found that the aminopyridazines
inhibited both oxidative and inflammatory cytokine pathways and
reduced human amyloid beta (Ab)-induced glial activation in a mouse
specially designed to develop many of the hallmarks of Alzheimer's
disease pathology, including neuroinflammation, neuronal and synaptic
degeneration and amyloid disposition, often called plaques.

Inhibition of neuroinflammation correlated with a decreased neuron
loss, restoration towards control levels of synaptic dysfunction
biomarkers in the hippocampus and diminished amyloid plaque
deposition. Consistent with the pathology changes, treatment with the
aminopyridazines also attenuated behavioral deficits in the mice that
are due to injury in the part of the brain called the hippocampus, a
region that is gradually destroyed in neurodegenerative diseases such
as Alzheimer's. The Northwestern investigators are now seeking to
raise the funding necessary for testing in humans.

Collaborating with Watterson and Van Eldik on this research were
Jeffrey M. Craft, a medical scientist predoctoral student in the Drug
Discovery Training Program, and Wenhui Hu and Hantamalala Ranay
Ranaivo, postdoctoral scholars in the Drug Discovery Training
Program.

###

This research was supported by grants from the Institute for the
Study of Aging; the Alzheimer's Association; and the National
Institutes of Health.

SOURCE: EurekAlert, DC
http://www.eurekalert.org/pub_releases/2004-11/nu-nce110804.php

* * *

New Compounds Effective Against Alzheimer's Disease Onset And
Progression (AND Parkinson's?)
"The aminopyridazines are targeted for the potential treatment of
certain neurodegenerative diseases that are characterized by
neuroinflammation and neuronal loss, such as Alzheimer's disease,
Parkinson's disease, stroke and traumatic brain injury."

09 Nov 2004

Drug discovery researchers at Northwestern University have developed
a new class of compounds that have the potential to reduce the
inflammation of brain cells and the neuron loss associated with
Alzheimer's disease.

The new class of compounds are aminopyridazines. The original
compound, called MW01-070C, is used in an injectable form. More
recently developed compounds, such as MW01-2-151WH and MW01-5-188WH,
can be taken by mouth.

The compounds were designed and synthesized in the laboratory of D.
Martin Watterson, J. G. Searle Professor of Molecular Biology and
Biochemistry and professor of molecular pharmacology and biological
chemistry, Northwestern University Feinberg School of Medicine, using
a synthetic chemistry platform developed by the Northwestern Drug
Discovery Program for the rapid discovery of new potential
therapeutic targets.

The aminopyridazines are targeted for the potential treatment of
certain neurodegenerative diseases that are characterized by
neuroinflammation and neuronal loss, such as Alzheimer's disease,
Parkinson's disease, stroke and traumatic brain injury. The compounds
inhibit over-activation of glia, important cells of the central
nervous system that normally help the body mount a response to injury
or developmental change but are overactivated in certain
neurodegenerative diseases.

The efficacy and safety of the compounds in an Alzheimer's disease
animal model was evaluated in collaboration with Linda J. Van Eldik,
professor of cell and molecular biology at Feinberg.

The scientists described their Alzheimer's disease drug discovery
efforts in recent issues of the Journal of Molecular Neuroscience and
the journal Neurobiology of Aging, and a publication that will appear
in early 2005 in the journal Current Alzheimer Research. The studies
have important implications for future drug development because they
provide a proof of concept that targeting neuroinflammation with
aminopyridazines is a viable Alzheimer's disease drug discovery
approach that has the potential to modulate disease onset and
progression, Van Eldik said.

Deposition of the beta-amyloid plaques and neurofibrillary tangles of
Alzheimer's disease is associated with glial activation, loss of
neurons and decline of cognitive function.

Long-term or excessive activation of glia increases production of
chemokines and cytokines, such as interleukin-1 beta (IL-1b), and
oxidative stress-related enzymes, such as a highly active form of
nitric oxide synthase (iNOS).

The excessive production of the inflammation-related substances can,
in turn, contribute to further exacerbation of the disease process.

IL-1b is involved in glial inflammatory and neuronal dysfunction
responses, and variants of the IL-1 gene are associated with
increased risk for Alzheimer's disease. The iNOS induced as a result
of glial activation generates nitric oxide (NO), which can exist in
toxic forms that damage neurons.

Therefore, development of new compounds that can modulate these
disease-linked biological processes may represent alternative
therapeutic approaches and lead to future identification of new drug
discovery targets, Van Eldik said.

Van Eldik and co-researchers found that the aminopyridazines
inhibited both oxidative and inflammatory cytokine pathways and
reduced human amyloid beta (Ab)-induced glial activation in a mouse
specially designed to develop many of the hallmarks of Alzheimer's
disease pathology, including neuroinflammation, neuronal and synaptic
degeneration and amyloid disposition, often called plaques.

Inhibition of neuroinflammation correlated with a decreased neuron
loss, restoration towards control levels of synaptic dysfunction
biomarkers in the hippocampus and diminished amyloid plaque
deposition. Consistent with the pathology changes, treatment with the
aminopyridazines also attenuated behavioral deficits in the mice that
are due to injury in the part of the brain called the hippocampus, a
region that is gradually destroyed in neurodegenerative diseases such
as Alzheimer's. The Northwestern investigators are now seeking to
raise the funding necessary for testing in humans.

Collaborating with Watterson and Van Eldik on this research were
Jeffrey M. Craft, a medical scientist predoctoral student in the Drug
Discovery Training Program, and Wenhui Hu and Hantamalala Ranay
Ranaivo, postdoctoral scholars in the Drug Discovery Training
Program.

This research was supported by grants from the Institute for the
Study of Aging; the Alzheimer's Association; and the National
Institutes of Health.

Contact: Elizabeth Crown
[log in to unmask]
312-503-8928
Northwestern University
http://www.northwestern.edu/

SOURCE: Medical News Today, UK
http://tinyurl.com/52se9

* * *Murray Charters <[log in to unmask]>
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Web site: Parkinsons Resources on the WWWeb
http://www.geocities.com/murraycharters

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