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Drug candidate stabilizes essential transport mechanism in nerve cells

NAP blocks formation of 'tangles' that contribute to Alzheimer's disease

Date:
January 31, 2017
Source:
American Friends of Tel Aviv University
Summary:
New research has discovered how a drug candidate works to possibly alleviate Alzheimer's disease and autism spectrum disorders.
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Tau is a key brain protein involved in Alzheimer's disease and other brain diseases. Aggregates of Tau known as "neurofibrillary tangles" have been associated with nerve cell death and cognitive decline.

An important new Tel Aviv University study published in Molecular Psychiatry pinpoints the mechanism harnessed by the drug candidate NAP to block the formation of these harmful neurofibrillary tangles. It facilitates the interaction of Tau with microtubules, the minitubes that serve as "train tracks" for essential movement of biological material in nerve cells.

"Abnormal Tau proteins form tangles that contribute to the progression of Alzheimer's disease," said Prof. Illana Gozes, who led the research for the study. "We showed here, for the first time, that the drug candidate NAP augmented microtubule movement in nerve cells. At the molecular level, NAP, a fragment of activity-dependent neuroprotective protein (ADNP), enhanced Tau-microtubule interactions that block the recruitment of Tau to the tangles observed in Alzheimer's disease and related disorders."

Prof. Gozes is the incumbent of the Lily and Avraham Gildor Chair for the Investigation of Growth Factors, Head of the Elton Laboratory for Molecular Neuroendocrinology at TAU's Sackler Faculty of Medicine and a member of TAU's Adams Super Center for Brain Studies and the Sagol School of Neuroscience.

Stabilizing a neurobiological process

Prof. Gozes is responsible for discovering ADNP, a gene that is dysregulated in Alzheimer's. Mutations in ADNP that occur in pregnancy are a major cause of autism with intellectual disability.

"ADNP and NAP operate through the stabilization of microtubules -- tubes within the cell that maintain cellular shape," Prof. Gozes said. "They transport biological material. These microtubules break down in in Alzheimer's disease and may be dysfunctional in autism. NAP works to protect the microtubules, thereby protecting the cell."

"We now discovered that ADNP dramatically enhances Tau binding to the microtubules, protecting them against destruction and against Tau pathology. We further discovered that this action of ADNP is through its NAP fragment, which is now intended for further clinical development."

"Knowing the precise mechanism of its action, it will be much easier to bring NAP to the clinic and to patients," said Prof. Gozes. "Furthermore, the precise mechanism defines a new drug target for autism spectrum disorders, Alzheimer's disease and many other neurodegenerative and neuropsychiatric diseases."


Story Source:

Materials provided by American Friends of Tel Aviv University. Note: Content may be edited for style and length.


Journal Reference:

  1. Y Ivashko-Pachima, C Laura Sayas, A Malishkevich, I Gozes. ADNP/NAP dramatically increase microtubule end-binding protein–Tau interaction: a novel avenue for protection against tauopathy. Molecular Psychiatry, 2017; DOI: 10.1038/mp.2016.255

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American Friends of Tel Aviv University. "Drug candidate stabilizes essential transport mechanism in nerve cells: NAP blocks formation of 'tangles' that contribute to Alzheimer's disease." ScienceDaily. ScienceDaily, 31 January 2017. <www.sciencedaily.com/releases/2017/01/170131104418.htm>.
American Friends of Tel Aviv University. (2017, January 31). Drug candidate stabilizes essential transport mechanism in nerve cells: NAP blocks formation of 'tangles' that contribute to Alzheimer's disease. ScienceDaily. Retrieved May 29, 2017 from www.sciencedaily.com/releases/2017/01/170131104418.htm
American Friends of Tel Aviv University. "Drug candidate stabilizes essential transport mechanism in nerve cells: NAP blocks formation of 'tangles' that contribute to Alzheimer's disease." ScienceDaily. www.sciencedaily.com/releases/2017/01/170131104418.htm (accessed May 29, 2017).

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