> *Dissertation Defense Announcement:
> To: The George Mason University Community*
>
> *Anne B. Verhoeven
> PhD Biosciences Candidate
> *
> *Date: Thursday June 17, 2010
> Time: 10:30 a.m.
> Place: George Mason University
> ** Room 256, Bull Run Hall
> Prince William campus <http://www.gmu.edu/resources/visitors/findex.html>
>
> Dissertation Chair: Dr. Monique van Hoek
> Committee members: Dr. Emanuel Petricoin III, Dr. Yuntao Wu, Dr. Timothy Born*
>
> *Title: "An Analysis of Signaling Pathways Activated by /Francisella Tularensis/ Infection"*
>
> A copy of the dissertation is on reserve in the Johnson Center
> Library, Fairfax campus. The doctoral project will not be read at the
> meeting, but should be read in advance.
>
> All members of the George Mason University community are invited to
> attend.*
> *
>
> *ABSTRACT:
> *
> /Francisella tularensis /is a zoonotic, gram negative pathogen that in
> recent years has become a pathogen of increasing interest because of
> its bioterrorism implications. /Francisella /has been classified as a
> Type A pathogen by the CDC. It is capable of producing severe
> infection with doses as low as 10 organisms. The possible threat of
> /Francisella /as a biological weapon makes understanding its specific
> pathogenicity of utmost importance.
> /Francisella /is an intracellular pathogen that enters the cell
> through an unknown method. Infection from /Francisella /occurs in
> many different cell types, including macrophages, hepatocytes, and
> endothelial cells. Once in the cell, /Francisella /is encapsulated in
> a phagosome. Between 2-4 hours after the initial infection
> /Francisella /escapes the phagosome and proceeds to replicate in the
> hosts cytosol. Previous studies have demonstrated that /Francisella
> /inhibits the release of pro-inflammatory cytokines such as TNF-alpha,
> IL-1, IL-12, and IL-8, thus hampering the ability of the innate immune
> system to respond to infection. Also, there is an increase of IL-10
> seen during /Francisella /infection. IL-10 is an anti-inflammatory
> cytokine that further decreases the innate immune system response.
> The lack of proper cytokine production might be caused by
> /Francisella/'s ability to block the TLR pathways, CR3 pathways, and
> the apoptosis pathways, further impeding the innate immune response.
> Interestingly, /Francisella /does not employ any known secretion
> systems, such as type III or type IV secretion systems that are
> commonly found in pathogenic bacteria. Nor does it produce toxins
> that could explain its ability to block cell signaling pathways. The
> mechanism used by /Francisella /directly interacts with host cell
> pathways is still unknown.
> *We hypothesize that by looking at specific pathways that are
> activated during infection of J774A.1 macrophages by /Francisella
> tularensis /LVS and /Francisella novicida /that we will be able to
> obtain a phosphorylation map of activated host cell responses*. *We
> hope that this map will point out virulence and pathogenic factors
> that /Francisella/ employs when it is infecting host's cells which
> could lead to better therapeutics as well as possible vaccine
> targets*. The steps that we will use to accomplish this task are: 1)
> the use of Reverse Phase Protein Microarray analysis to generate a
> phosphorylation map of /Francisella /LVS and /Francisella novicida/
> infection in J774A.1 cells, 2) validation of this map through western
> blots and analysis of previous reported data on specific signaling
> pathways, 3) comparison of different phosphorylation maps of
> /Francisella novicida /and /Francisella /LVS to determine differences
> between the strains, and 4) in a separate study, we will examing
> changes in gene expression in human lung epithelial cells through the
> use of microarrays to determine the difference in host cell gene
> transcription between uninfected A549 cells and /Francisella /LVS
> infected A549 cells.
>
>
> ###
>
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