The Functional Domains of PHLDA1: Modulation of Intracellular Localization Impacts Apoptotic Cell Death

Collins, AF Celeste

31 December 2014

<p>Pleckstrin homology like domain family A, member 1 (PHLDA1) is a member of the PHLDA family of homologous proteins recognized for their role in apoptotic cell death. PHLDA1 was first reported as a proapoptotic factor involved in Fas-mediated T-cell apoptosis. The role of this protein with regards to apoptosis remains poorly understood, with literature demonstrating both proapoptotic and antiapoptotic functions in a cell and/or pathway specific manner. Intracellular localization may account for the apoptotic potential of this protein, with nuclear accumulation of PHLDA1 increasing its apoptotic potential. We hypothesize that the functional regions of PHLDA1 including its localization signals (pNLS/pNES), pleckstrin homology like domain (PHLD), and PQ region direct cellular localization of PHLDA1, thereby regulating its apoptotic potential.</p> <p>In this thesis, well-established molecular and cellular approaches were utilized to better define the functional regions within PHLDA1 and to gain further understanding of the role of its localization on apoptosis. Using an EGFP fusion construct and leptomycin B, we confirmed that PHLDA1 contains a weak, CRM1-responsive NES. Using an EGFP-β-galactosidase fusion protein we examined the putative NLS of PHLDA1 and determined that it was not sufficient to direct nuclear localization. However, the PHLD was found to direct cellular localization, mirroring the distribution and punctate patterning of full length PHLDA1. Evidence of association of the PHLD with the membrane was confirmed using fluorescence and electron microscopy, and changes in cell morphology indicative of EMT were apparent following overexpression of the PHLD.</p> <p>Although previous reports have suggested that the PQ region of PHLDA1 is responsible for its proapoptotic function, its cellular localization was not clearly defined. Nuclear accumulation of the PQ region was found to be highly cytotoxic, indicating that it is sufficient to induce apoptosis and that its proapoptotic activity occurs within the nucleus. The findings of this thesis provide fresh insight into the functional regions of PHLDA1 and their respective contributions to the protein’s intracellular localization and apoptotic function, demonstrating that localization dictates the apoptotic potential of PHLDA1. This data provides a solid foundation for identifying the cellular mechanisms by which PHLDA1 influences the progression of chronic human diseases including diabetes, cancer and obesity.</p> / Master of Science (MSc)

PHLDA1

TDAG51

Medical Biochemistry

Medical Cell Biology

Medical Sciences

Reproductive and Urinary Physiology

Medical Biochemistry

CONTRIBUTION OF THE UNFOLDED PROTEIN RESPONSE (UPR) TO ADIPOGENESIS AND WHOLE BODY ENERGY HOMEOSTASIS

Basseri, Sana

04 1900

<p>The endoplasmic reticulum (ER) is a specialized organelle that facilitates correct protein folding and maturation. Disruptions in ER homeostasis lead to ER stress and activation of a series of signal transduction cascades known as the unfolded protein response (UPR), which acts to restore ER homeostasis. In recent years, ER stress and UPR dysfunction have been linked to obesity, fatty liver and insulin resistance. Lipid-laden adipocytes, the main cellular component of white adipose tissue (WAT), play a critical role in whole body energy homeostasis as well as lipid and carbohydrate metabolism. Mature adipocytes, which are metabolically active endocrine cells, differentiate from precursor fibroblast-like preadipocytes, through a process called adipogenesis, leading to formation of cells capable of secreting numerous proteins, cytokines and hormones. ER homeostasis and UPR activation are essential to the function/differentiation of highly secretory cells, however, the role of ER stress/UPR activation in adipogenesis had previously not been examined. We hypothesized that<em> adipogenesis may rely on physiological UPR activation to accommodate the demand on the ER for increased folding and secretion of proteins.</em></p> <p>Initial experiments examining UPR activation during 3T3-L1 adipogenesis identified that expression of ER stress/UPR markers was modulated during adipocyte differentiation. Furthermore, inhibition of ER stress/UPR activation by the chemical chaperone, 4-phenyl butyric acid (4-PBA), inhibited adipogenesis and blunted high fat-diet induced weight gain in 4-PBA supplemented mice. These findings suggested that UPR activation modulates adipogenesis and adipose tissue metabolism.</p> <p>Subsequently, we sought to identify novel candidate ER stress/UPR responsive genes that may be involved in adipogenesis and WAT metabolism. The expression of a recently recognized ER stress-responsive gene, T-cell death associated gene 51 (TDAG51) was identified to be differentially regulated during adipogenesis. However, the function of TDAG51 in adipogenesis or energy regulation was not known. Studies from this thesis showed that TDAG51 protein expression is attenuated by ER stress/UPR activation in preadipocytes and declines during adipogenesis. Based on these results, and given the importance of adipogenesis in WAT function and whole body energy metabolism, it was<em> </em>hypothesized that<em> TDAG51 may be a novel regulator of adipogenesis and energy homeostasis.</em> Indeed, as reported here, knock-down or absence of TDAG51 (<em>TDAG51^-/-</em>) in pre-adipocytes increased lipogenesis and lead to earlier and more potent expression of adipogenic markers.</p> <p>Finally, we investigated whether absence of TDAG51 in mice affected adiposity and metabolic outcomes. Consistent with the <em>in vitro </em>results, we found that <em>TDAG51^-/-</em>mice fed a standard chow diet, exhibited an age-associated increase in WAT, developed fatty liver, and exhibited insulin resistance as compared to wild-type mice.</p> <p>Taken together, the findings in this thesis indicate that physiological UPR activation and the UPR-responsive gene TDAG51 play important roles in regulating adipogenesis, lipogenesis and whole-body energy metabolism. Thus, therapeutic approaches aimed at modulating ER folding capacity, UPR activation and/or TDAG51 expression may have great potential in the treatment of obesity and its co-morbidities.</p> / Doctor of Philosophy (PhD)

Endoplasmic Reticulum Stress

TDAG51

Adipocytes

Obesity

White Adipose Tissue

Endocrinology, Diabetes, and Metabolism

Medical Cell Biology