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Specificity in PI3K-PKB/AKT-PTEN Signaling: Subcellular Locus-specific Functions of Pathway Targets

The PI3K-PKB/Akt-PTEN signal transduction pathway orchestrates a variety of fundamental cell processes and its deregulation is implicated in several human diseases, including cancer. While the importance of this pathway to many cellular functions is well established, the mechanisms leading to context-specific physiological outcomes in response to a variety of stimuli remain largely unknown.
Spatial restriction of signaling events is one of the means to coordinate specific cellular responses. To investigate the subcellular locus-specific roles of the major PI3K effector PKB/Akt in various cell processes, I have devised a novel experimental system employing cellular compartment-directed PKB/Akt pseudosubstrate inhibitors. The work herein describes the development and characterization of the localized PKB/Akt pseudosubstrate inhibitor system and its application to investigate potential locus-specific functions in established PKB/Akt-regulated cellular processes. Subcellular compartment-restricted PKB/Akt inhibition in the 3T3L1 adipocyte differentiation model revealed that nuclear and plasma membrane, but not cytoplasmic, PKB/Akt activity is required for terminal adipocyte differentiation. Nuclear and plasma membrane pools of PKB/Akt were found to contribute to distinct stages of adipocyte differentiation, revealing that PKB/Akt activity impacts multiple points of this program.
The localized PKB/Akt pseudosubstrate inhibitor system was also utilized to investigate the importance of distinct subcellular pools of PKB/Akt in breast epithelial cells. MCF-10A human breast epithelial cells can be grown in three-dimensional culture to form acinar structures that recapitulate in vivo mammary glandular architecture. Expression of the plasma membrane PKB/Akt inhibitor during cell growth in three-dimensional culture severely impaired acinar formation. On the other hand, expression of the nuclear PKB/Akt inhibitor during acinar development resulted in the formation of large, misshapen, multi-acinar structures. Assessment of the migratory capacity of MCF-10A cells upon localized PKB/Akt inhibition revealed that nuclear PKB/Akt inhibition promoted, while plasma membrane PKB/Akt inhibition impaired, MCF-10A cell migration.
The development of locus-specific PKB/Akt inhibitors represents the first attempt to prioritize the targets of this kinase based on their subcellular localization. This work and its immediate extensions will further our understanding of the biology of PKB/Akt, a multi-tasking kinase with profound roles in development, cellular and organismal homeostasis and disease.

Identiferoai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/26370
Date23 February 2011
CreatorsMaiuri, Tamara Lise
ContributorsStambolic, Vuk
Source SetsUniversity of Toronto
Languageen_ca
Detected LanguageEnglish
TypeThesis

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