PDK1 Attenuation Fails to Prevent Tumor Formation in PTEN-deficient Transgenic Mouse Models

Overview

Journal Cancer Res

Specialty Oncology

Date 2011 Apr 16

PMID 21493594

Citations 19

Authors

Katharine Ellwood-Yen

Heike Keilhack

Kaiko Kunii

Brian Dolinski

Yamicia Connor

Kun Hu

Kumiko Nagashima

Erin OHare

Yusuf Erkul

Alessandra Di Bacco

Diana Gargano

Nirah H Shomer

Minilik Angagaw

Erica Leccese

Paula Andrade

Melissa Hurd

Myung K Shin

Thomas F Vogt

Alan Northrup

Ekaterina V Bobkova

Shailaja Kasibhatla

Roderick T Bronson

Martin L Scott

Giulio Draetta

Victoria Richon

Nancy Kohl

Peter Blume-Jensen

Jannik N Andersen

Manfred Kraus

Affiliations

Soon will be listed here.

Abstract

PDK1 activates AKT suggesting that PDK1 inhibition might suppress tumor development. However, while PDK1 has been investigated intensively as an oncology target, selective inhibitors suitable for in vivo studies have remained elusive. In this study we present the results of in vivo PDK1 inhibition through a universally applicable RNAi approach for functional drug target validation in oncogenic pathway contexts. This approach, which relies on doxycycline-inducible shRNA expression from the Rosa26 locus, is ideal for functional studies of genes like PDK1 where constitutive mouse models lead to strong developmental phenotypes or embryonic lethality. We achieved more than 90% PDK1 knockdown in vivo, a level sufficient to impact physiological functions resulting in hyperinsulinemia and hyperglycemia. This phenotype was reversible on PDK1 reexpression. Unexpectedly, long-term PDK1 knockdown revealed a lack of potent antitumor efficacy in 3 different mouse models of PTEN-deficient cancer. Thus, despite efficient PDK1 knockdown, inhibition of the PI3K pathway was marginal suggesting that PDK1 was not a rate limiting factor. Ex vivo analysis of pharmacological inhibitors revealed that AKT and mTOR inhibitors undergoing clinical development are more effective than PDK1 inhibitors at blocking activated PI3K pathway signaling. Taken together our findings weaken the widely held expectation that PDK1 represents an appealing oncology target.

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