Characterizing the role and regulation of growth arrest specific FABP4 in chicken embryo fibroblasts

Donders, Jordan

January 2020

Conditions which promote reversible growth arrest, such as hypoxia and high cell density, lead to activation of a diverse network of proteins known as growth arrest specific (GAS) genes. Fatty acid binding protein 4 (FABP4), a lipid chaperone involved in the regulation of metabolic and inflammatory responses, has been shown to be part of the GAS program. While the induction of FABP4 in oxygen-deprived environments is well characterized, its functionality and regulation in such conditions remains unclear. In this study, we describe how mis-expression of FABP4 affects cell viability and survival within low oxygen conditions. Loss of FABP4 using shRNA was shown to be associated with a significant increase in oxidative stress and lipid peroxidation, a reduction in lipid droplet formation and a greater incidence of apoptosis. Hypoxia-mediated expression of FABP4 was also found to be positively correlated with cellular levels of C/EBP-beta, an essential activator of p20K in quiescence. FABP4 and p20K are both lipocalins that have been shown to share similar induction patterns and ability to assist in the maintenance of lipid trafficking in cellular stress circumstances. Unexpectedly, the depletion of FABP4 or p20K results in loss of the other in limited oxygen concentrations. This occurs independently of disruption to the broad GAS gene program, suggesting the two proteins may be co-regulated in a shared hypoxic-signalling pathway. C/EBP-beta appears to be the transcriptional activator shared by FABP4 and p20K in quiescence, and the three may be part of an intricate system to sense and respond to reactive oxygen species and lipid radicals. However, the forced expression of either FABP4 or p20K when the other is repressed only moderately restores cell survival through alleviating oxidative stress, indicating the two are both necessary for optimal response to hypoxia. In all, these studies suggest that analogous to the p20K lipocalin, FABP4 plays a critical role in lipid homeostasis and cell survival in conditions of limited oxygen concentrations, and its stimulation is dependent on C/EBP-beta activity. / Thesis / Master of Science (MSc) / A study investigating the role of FABP4 and p20K in conditions of reversible growth arrest with an emphasis on cell survival, lipid homeostasis and mitigating the effects of oxidative stress, and regulation of the two lipocalins by C/EBP-beta.

quiescence

reversible growth arrest

fatty acid binding protein 4 (FABP4)

AP2

P20K

Lipocalin

chicken embryo fibroblast (CEF)

Growth arrest specific gene (GAS)

C/EBP-beta

oxidative stress

hypoxia

lipid peroxidation

membrane stress response

lipid damage response

reactive oxygen species

contact inhibition

Die Regulation des humanen Lipopolysaccharid bindenden Proteins (hLBP)

Hallatschek, Werner

26 January 2005

Das Lipopolysaccharid Bindende Protein (LBP) ist ein überwiegend in der Leber synthetisiertes Akutphaseprotein. Es bindet den Zellwandbestandteil Lipopolysaccharid (LPS) Gram-negativer Bakterien und transportiert es zu zellulären Rezeptoren, wodurch das angeborene Immunsystem aktiviert wird. In dieser Arbeit wird die Regulation der LBP-Expression in Interleukin (IL)-1, IL-6 und Dexamethason (Dex) stimulierten humanen Hepatomzelllinien HuH-7 und HepG2 untersucht. Der wichtigste Stimulator ist dabei IL-6, dessen Wirkung über die Transkriptionsfaktoren (TF) Stat-3, C/EBP-beta und AP-1 vermittelt wird. Für alle 3 TF konnten aktive Bindungsstellen auf dem LBP-Promotor nachgewiesen werden. Für IL-1-Effekte die u. a. über den TF NF-kappaB vermittelt werden, konnten ebenfalls aktive Bindungsstellen nachgewiesen werden. Die Wirkung von Dex wird über Glucocorticoid Responsive Elements (GREs) vermittelt. Auf dem LBP-Promotor befinden, sich wie gezeigt werden konnte, mehrere aktive GREs, wobei einige verstärkend und einige hemmend wirken. Eine zu beobachtende Synergiewirkung von Dex und IL-6 wird durch die Aufregulation des IL-6-Rezeptors durch Dex verursacht. Die LBP-Expression kann durch TGF (Transforming Growth Factor)-beta gehemmt werden. Der TGF-beta-Signalweg über Smads ist in den Hepatomzellen aktiv, vermittelt aber nicht den TGF-beta-Hemmeffekt, sondern eine geringe stimulierende Wirkung, die bei alleiniger TGF-beta-Inkubation auftritt. Die inhibierende Wirkung von TGF-beta wird durch Gfi-1- und AP-1-Bindungsstellen vermittelt. Die Gfi-1-Bindungsstelle nimmt dabei, wie hier erstmals gezeigt werden konnte, eine herausragende Stellung ein. Die Aufklärung der LBP-Regulation und dabei besonders die Hemmung der LBP-Expression kann mittelfristig dazu beitragen, den klinischen Verlauf von inflammatorischen und infektiösen Erkrankungen zu beeinflussen und bietet daher Potenzial für neue Therapieansätze. / Lipopolysaccharide (LPS) binding protein (LBP) is an acute phase protein with the ability to bind and transfer LPS of Gram-negative bacteria. This soluble pattern recognition molecule represents an important defense principle of the host. Regulation of the hepatic acute phase response and its termination are important mechanisms for limiting systemic inflammatory activity of the host. Here were analyze the cooperation of Interleukin (IL)-1, IL-6, and Dexamethasone (Dex) at LBP expression in the hepatoma cell lines HuH-7 and Hep G2. The major inducer of LBP expression is IL-6. Within the LBP promoter numerously highly consensus binding sites such as AP-1, C/EBP-beta? and STAT3 are present, that confer transcriptional activity as shown by truncation and mutation experiments. Additionally, activate NF-kappaB sites activated by IL-1 were detected at the LBP promoter. By mutation experiments of the promoter furthermore were found differentially active glucocorticoid response elements (GREs). The promoter contains GREs enhancing the activity as well as inhibitory ones. The enhancing effect towards LBP expression by Dex was mediated by IL-6. Dex stimulated the expression of the IL-6 receptor and therefore upregulated the IL-6 pathway. Transforming Growth Factor (TGF)-beta is able to inhibit LBP expression in stimulated cells. An AP-1 binding site was identified mediating inhibitory TGF-beta effects towards LBP promoter activity. Furthermore it was shown that a growth factor independence (Gfi)-1 binding site localized near the AP-1 site is essential for mediating the TGF-beta inhibitory effect. The relevancy of the Gfi-1 site fore mediating TGF-beta effects indicates a novel mechanism for understanding inhibitory TGF-beta effects at the transcriptional level. In summary the complex regulation of LBP were elucidate which may help to eventually develop novel intervention strategies for acute phase, sepsis, and septic shock.

LPS binding protein (LBP)

Lipopolysaccharid (LPS)

Interleukin-6 (IL-6)

Dexamethason (Dex)

Aktivatorprotein-1 (AP-1)

Nuclear factor kappa B (NF kappa B)

Glucocorticoid responsive element (GRE)

Growth factor independence-1 (Gfi-1)

LPS binding protein (LBP)

lipopolysaccharid (LPS)

interleukin-6 (IL-6)

dexamethasone (Dex)

activator protein-1 (AP-1)

nuclear factor kappa B (NF kappa B)

glucocorticoid responsive element (GRE)

growth factor independence-1 (Gfi-1)

570 Biowissenschaften, Biologie

32 Biologie

WF 9900

ddc:570