Recommend Autophagy to your librarian for 2008. Download form here.

Sign up for Table of Contents Alerts!

home subscribe search archive forthcoming

Email this page Print this page

Research Paper

Altered Regulation of Phosphatidylinositol 3-kinase Signaling in Cathepsin D-Deficient Brain

Ken C. Walls, Barbara J. Klocke, Paul Saftig, Masahiro Shibata, Yasuo Uchiyama, Kevin A. Roth and John J. Shacka

volume 3 | issue 3

 May/June 2007
Pages: 222 - 229

We now provide open access to journal articles published online for one year or more. This article may be downloaded at the following link:
 Download PDF

If the document does not open, please right-click on the link (control-click on a Macintosh) and select the option to save the file to disk.

Cathepsin D (CD) is an essential lysosomal protease and mice lacking this enzyme exhibit neuropathology similar to that observed in brains of patients with neuronal ceroid lipofuscinosces (NCL/Batten disease), a group of autosomal recessive pediatric neurodegenerative diseases. CD-deficient (CD-/-) brains exhibit a dramatic induction of autophagic stress as defined by the aberrant accumulation of autophagosomes, which is concomitant with markers of apoptosis. However, the signaling abnormalities which lead to CD deficiency-induced neurodegeneration are poorly defined. Since phosphatidylinositol-3 kinase (PI3-K) is known to regulate both apoptosis and autophagy, PI3-K-mediated signaling events were assessed in CD-/- brain at P14 and P25-26. Compared to WT littermate controls, CD-/- cortical neurons exhibited a widespread decrease in phosphorylation of Akt (inactivation) and GSK3beta (disinhibition) at P25-26, while levels of total Akt and GSK3beta remained unchanged. This P25-26-specific decrease in phosphorylation of Akt and GSK-3beta in CD-/- brain coincided temporally with markers of apoptosis but followed the induction of autophagic stress observed at both P14 and P25-26. In addition, levels and/or activation of mTOR and Beclin were not affected by CD deficiency, suggesting that the accumulation of autophagosomes is not due to an increased synthesis of autophagosomes but rather from an inhibition of autophagosome recycling, due most likely to a compromise in lysosome function. Together these observations indicate a pronounced decrease in pro-survival PI3-K signaling in CD-/- brain that may contribute to autophagic stress-induced and apoptotic neuropathology.

Authors

Ken C. Walls

University of Alabama at Birmingham

Barbara J. Klocke

University of Alabama at Birmingham

Paul Saftig

University of Kich

Masahiro Shibata

Osaka University Graduate School of Medicine

Yasuo Uchiyama

Osaka University Graduate School of Medicine

Kevin A. Roth

University of Alabama at Birmingham

John J. Shacka

University of Alabama at Birmingham


We now provide open access to journal articles published online for one year or more. This article may be downloaded at the following link:
 Download PDF

If the document does not open, please right-click on the link (control-click on a Macintosh) and select the option to save the file to disk.