Toward Determining the Role of PKA in Controlling TORC2 Function and Chemotaxis in Dictyostelium Discoideum

Petlick, Alexandra Ruth

January 2014

Chemotaxis is a process whereby single- and multi-cellular organisms migrate in response to external chemical stimuli. This directed cell movement is regulated by complex signaling pathways and is implicated in embryonic development, immune response, and the metastasis of cancer cells. Dictyostelium discoideum, social amoebae with the ability to migrate and aggregate in response to chemoattractants such as cAMP, have been used as a model system to study chemotaxis. Preliminary research suggests that protein kinase (PKA) is involved in some of the signaling pathways that regulate chemotaxis. The role of PKA in chemotaxis was investigated, first, by characterizing the phenotype of PKA null cells using established cell biological and biochemical assays. Furthermore, spatiotemporal regulation of critical cytoskeletal proteins was probed in wild-type and PKA null cells using confocal fluorescence microscopy, indicating misregulation of both F-actin and Myosin II in pkaC- and pkaR- cells. Finally, preliminary work was done to lay the groundwork for experiments exploring possible PKA targets mediating TORC2 function in chemotaxis.

Chemotaxis

confocal microscopy

Dictyostelium

Myosin

TORC2

Chemistry

Actin

Hormone-induced expression of the epithelial sodium channel in human airway cells

Ismail, Noor

January 2013

Respiratory distress syndrome and pulmonary oedema often result in poor health and in the worst case scenario, death. Several studies have proposed that the eventual resolution of these dangerous conditions is due to active sodium reabsorption through the epithelial sodium channel (ENaC), which is crucial for lung fluid clearance. Although clinical prognosis can be improved by using glucocorticoid hormones to augment the ENaC-dependent removal of liquid from the lungs, we still require a better understanding of the underlying mechanism in order to improve treatments in the future. This thesis, therefore explores the role of serum / glucocorticoid-inducible protein kinase 1 (SGK1) and protein kinase A (PKA) in the responses of hormone-stimulated H441 human airway cells. Dexamethasone, a synthetic glucocorticoid hormone, is thought to evoke expression of the gene encoding SGK1 and, to become catalytically active, this gene product must then be phosphorylated via TORC2 and PDK1, protein kinases activated via the P13-kinase pathway. Once activated, SGK1 appears to exert control over the surface abundance of ENaC subunits by phosphorylation, and thus inactivating, a ubiquitin ligase (Nedd4-2), that normally mediate the withdrawal of ENaC subunits from the plasma membrane. Protein kinase A (PKA) may contribute to this control mechanism by also phosphorylating Nedd4-2. In order to clarify the way in which these pathways contribute to glucocorticoid-induced lung liquid clearance, the present thesis has explored the effects of dexamethasone and / or PKA activation upon the overall / surface expression of ENaC subunits, the activities of SGK1 and PKA and the phosphorylation status of physiologically-important residues within Nedd4-2 itself.

616.2

PAS Kinase and TOR, Controllers of Cell Growth and Proliferation

Cozzens, Brooke Jasmyn

01 March 2019

Nutrient sensing kinases lie at the heart of cellular health and homeostasis, allowing cells to quickly adapt to changing environments. Target of Rapamycin (TOR) and PAS kinase (PASK, or PASKIN) are two such nutrient kinases, conserved from yeast to man. In yeast, these kinases each have paralogs. The two TOR paralogs in yeast mimic the mammalian TORC1 and TORC2 complexes, except both Tor1 and Tor2 may contribute to TORC1 or TORC2 function. The two PAS kinase paralogs are paired with the TOR paralogs, meaning that both Psk1 and Psk2 regulate TORC1, while Psk2 suppresses a temperature-sensitive allele of Tor2. Herein we review the evolutionary models for these paralogs, their function in yeast and mammalian cells, as well as the overlapping function of PAS kinase and TOR. We also use Rice University’s Direct Coupling Analysis algorithms to analyze co-evolutionary relationships and identify potential interaction sites between PAS kinase and several of its substrates.

PAS kinase

gene duplication

mTOR

TORC1

TORC2

glucose metabolism

signal transduction

nutrient sensing

Direct Coupling Analysis

Ugp1

Cbf1

Utr1

USF1

ATXN2

Life Sciences

Microbiology

Molecular Biology