SELECTIVE REGULATION OF CARDIOMYOCYTE SIGNALING BY RGL2

Allen, Leah M.

01 January 2008

A key cardiovascular signaling molecule involved in both physiologic and pathologic regulation of cardiomyocytes is the small molecular weight G-protein, Ras. Differential effects of Ras are mediated by multiple effector molecules, including the RalGEFs which activate Ral. Studies performed in cardiomyocytes have indicated a role for Ral in cardiac hypertrophic signaling and the RalGEF family member, Rgl2, was shown to specifically interact with Ras in the heart. Therefore, I hypothesized that Rgl2 was an important Ras effector that would regulate cardiomyocyte signaling. To elucidate the potential importance of Rgl2 in regulating cardiomyocyte signaling, a gain-of-function approach was utilized in which NRVMs were infected with an adenovirus to increase Rgl2 expression. Using this approach, I found that Rgl2 increased Ral-GTP levels, Ras-GTP levels, and PI3-kinase-Akt signaling, but decreased ERK phosphorylation. Overall, my results suggest a model in which Rgl2 disrupts Ras-Raf and Ras-RasGAP interaction to decrease ERK phosphorylation and increase Ras-GTP, respectively. Furthermore, Rgl2-induced Ral activation promotes the enhanced PI3- kinase-Akt signaling. The physiologic consequence of Rgl2 signaling is difficult to predict, but the increase in PI3-kinase-Akt signaling would be expected to promote cardiomyocyte survival and enhance cardiac function, both of which are characteristic of physiologic hypertrophy.

Rgl2

Ras

Signal transduction

Cardiomyocyte

Insulin

Pharmacy and Pharmaceutical Sciences

Inhibiting protein clearance to induce cell death in tuberous sclerosis and pancreatic cancer

Hendricks, Jeremiah William

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Sequestration at the aggresome and degradation through autophagy are two approaches by which a cell can counteract the toxic effect of misfolded proteins. Tuberous sclerosis (TS) and cancer cells can become dependent on autophagy for survival due to the high demand for protein synthesis, thus making protein clearance a potential therapeutic target. Because of its histone deacetylase (HDAC) inhibitory activity, we hypothesized that 4-phenylbutyrate (4-PBA) inhibits HDAC6 and aggresome formation to induce TS cell death. We found that 4-PBA treatment increases cell death and reduces bortezomib-induced aggresome formation. To link these results with HDAC inhibition we used two other HDAC inhibitors, trichostatin A (TSA) and tubastatin, and found that they also reduce bortezomib-induced protein aggregation. Because tubulin is a target of HDAC6, we next measured the effect of the HDAC inhibitors and 4-PBA treatment on tubulin acetylation. As expected, tubastatin increased tubulin acetylation but surprisingly TSA and 4-PBA did not. Because 4-PBA did not significantly inhibit HDAC6, we next hypothesized that 4-PBA was alternatively inducing autophagy and increasing aggresome clearance. Surprisingly, autophagy inhibition did not prevent the 4-PBA-induced reduction in protein aggregation. In conclusion, we found 4-PBA to induce cell death and reduce aggresome levels in TS cells, but we found no link between these phenomena. We next hypothesized that loss of the Ral guanine nucleotide exchange factor Rgl2 induces cell death via autophagy inhibition in pancreatic adenocarcinoma (PDAC) cells. KRas is mutationally activated in over 90% of PDACs and directly activates Rgl2. Rgl2 activates RalB, a known regulator of autophagy, and Rgl2 has been shown to promote PDAC cell survival. We first confirmed that loss of Rgl2 does increase cell death in PDAC cells. Initial experiments using doubly tagged fluorescent p62 and LC3 (autophagy markers) suggested that loss of Rgl2 inhibited autophagosome accumulation, but after developing a more sophisticated quantitation method we found loss of Rgl2 to have no effect. We also measured endogenous LC3 levels, and these experiments confirmed loss of Rgl2 to have no effect on autophagy levels. Therefore, loss of Rgl2 increases cell death in PDAC cells, but does not have a significant effect on autophagy.

Pancreas -- Cancer -- Research

Cancer -- Molecular aspects

Proteins-- Biodegradation

Tuberous sclerosis -- Research

Proteins -- Pathophysiology

Cell death -- Research -- Methodology

Histone deacetylase -- Research

Proteins -- Synthesis

Genetic regulation

Cell aggregation

Acetylation -- Research