dictyNews
Electronic Edition
Volume 32, number 13
May 15, 2009

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Abstracts
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Legionella pneumophila multiplication is enhanced by chronic AMPK signalling in 
mitochondrially diseased Dictyostelium cells.

Lisa Francione1, Paige K. Smith1, Sandra L. Accari1, Philip E. Taylor2, 
Paul B. Bokko1, Salvatore Bozzaro3, Peter L. Beech2 and Paul R. Fisher1*.

1 Department of Microbiology, La Trobe University, VIC 3086, Australia
2 Centre for Cellular and Molecular Biology, Deakin University, Burwood, 
VIC 3125, Australia  
3 Department of Clinical and Biological Sciences, University of Turin, 
Ospedale S. Luigi, 10043 Orbassano, Italy 


Disease Models and Mechanisms, in press

Human patients with mitochondrial diseases are more susceptible to bacterial 
infections, particularly of the respiratory tract. To investigate the 
susceptibility of mitochondrially diseased cells to an intracellular 
bacterial respiratory pathogen, we exploited the advantages of Dictyostelium 
discoideum as an established model for mitochondrial disease and for 
Legionella pneumophila pathogenesis. Legionella infection of macrophages 
involves recruitment of mitochondria to the Legionella-containing phagosome. 
We confirm here that this also occurs in Dictyostelium and investigate the 
effect of mitochondrial dysfunction on host cell susceptibility to Legionella. 
In mitochondrially diseased Dictyostelium strains, the pathogen was taken 
up at normal rates, but it grew faster and reached counts that were twofold 
higher than in the wild type host. We previously reported that other 
mitochondrial disease phenotypes for Dictyostelium are due to activity 
of an energy-sensing cellular alarm protein, AMP-activated protein kinase 
(AMPK). Here we show that the increased ability of mitochondrially diseased 
cells to support Legionella proliferation is suppressed by antisense-inhibiting 
expression of the catalytic AMPKalpha subunit. Conversely, mitochondrial 
dysfunction is phenocopied and intracellular Legionella growth enhanced, 
by overexpressing an active form of AMPKalpha in otherwise normal cells. 
These results indicate that AMPK signalling in response to mitochondrial 
dysfunction enhances Legionella proliferation in host cells.
   

Submitted by: Paul Fisher [P.Fisher@latrobe.edu.au]
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[End dictyNews, volume 32, number 13]