The integrated stress response directs cell fate decisions in response to perturbations in protein homeostasis

Teske, Brian Frederick

29 January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Disruptions of the endoplasmic reticulum (ER) cause perturbations in protein folding and result in a cellular condition known as ER stress. ER stress and the accumulation of unfolded protein activate the unfolded protein response (UPR) which is a cellular attempt to remedy the toxic accumulation of unfolded proteins. The UPR is implemented through three ER stress sensors PERK, ATF6, and IRE1. Phosphorylation of the α-subunit of eIF2 by PERK during ER stress represses protein synthesis and also induces preferential translation of ATF4, a transcriptional activator of stress response genes. Early UPR signaling involves translational and transcriptional changes in gene expression that is geared toward stress remedy. However, prolonged ER stress that is not alleviated can trigger apoptosis. This dual signaling nature of the UPR is proposed to mimic a 'binary switch' and the regulation of this switch is a key topic of this thesis. Adaptive gene expression aimed at balancing protein homeostasis encompasses the first phase of the UPR. In this study we show that the PERK/eIF2~P/ATF4 pathway facilitates both the synthesis of ATF6 and trafficking of ATF6 from the ER to the Golgi where ATF6 is activated. Liver-specific depletion of PERK significantly lowers expression of survival genes, leading to reduced expression of protein chaperones. As a consequence, loss of PERK in the liver sensitizes cells to stress which ultimately leads to apoptosis. Despite important roles in survival, PERK signaling is often extended to the vii activation of other downstream transcription factors such as CHOP, a direct target of ATF4-mediated transcription. Accumulation of CHOP is a hallmark of the second phase in the binary switch model where CHOP is shown to be required for full activation of apoptosis. Here the transcription factor ATF5 is found to be induced by CHOP and that loss of ATF5 improves the survival of cells following changes in protein homeostasis. Taken together this study highlights the importance of UPR signaling in determining the balance between cell survival and cell death. A topic that is important for understanding the more complex pathological conditions of diseases such as diabetes, cancer, and neurodegeneration.

Endoplasmic reticulum -- Research

Proteins -- Physiological transport

Endoplasmic reticulum -- Pathophysiology

Cellular signal transduction

Stress (Physiology)

Proteins -- Metabolism

Homeostasis

Molecular chaperones

Proteins -- Denaturation

Phosphorylation

Genetic transcription -- Regulation

Apoptosis

Cell death

Proteins -- Conformation

Optimizing hydropathy scale to improve IDP prediction and characterizing IDPs' functions

Huang, Fei

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Intrinsically disordered proteins (IDPs) are flexible proteins without defined 3D structures. Studies show that IDPs are abundant in nature and actively involved in numerous biological processes. Two crucial subjects in the study of IDPs lie in analyzing IDPs’ functions and identifying them. We thus carried out three projects to better understand IDPs. In the 1st project, we propose a method that separates IDPs into different function groups. We used the approach of CH-CDF plot, which is based the combined use of two predictors and subclassifies proteins into 4 groups: structured, mixed, disordered, and rare. Studies show different structural biases for each group. The mixed class has more order-promoting residues and more ordered regions than the disordered class. In addition, the disordered class is highly active in mitosis-related processes among others. Meanwhile, the mixed class is highly associated with signaling pathways, where having both ordered and disordered regions could possibly be important. The 2nd project is about identifying if an unknown protein is entirely disordered. One of the earliest predictors for this purpose, the charge-hydropathy plot (C-H plot), exploited the charge and hydropathy features of the protein. Not only is this algorithm simple yet powerful, its input parameters, charge and hydropathy, are informative and readily interpretable. We found that using different hydropathy scales significantly affects the prediction accuracy. Therefore, we sought to identify a new hydropathy scale that optimizes the prediction. This new scale achieves an accuracy of 91%, a significant improvement over the original 79%. In our 3rd project, we developed a per-residue C-H IDP predictor, in which three hydropathy scales are optimized individually. This is to account for the amino acid composition differences in three regions of a protein sequence (N, C terminus and internal). We then combined them into a single per-residue predictor that achieves an accuracy of 74% for per-residue predictions for proteins containing long IDP regions.

Intrinsically disordered proteins

Support vector machine

Clustering

Proteins -- Conformation -- Research

Proteins -- Denaturation

Protein folding -- Research

Support vector machines

Aggregation (Chemistry)

Amino acids -- Analysis

Cellular signal transduction

Molecular biology -- Mathematics

Algorithms

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

Mechanisms of translational regulation in the pancreatic β cell stress response

Templin, Andrew Thomas

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The islet beta cell is unique in its ability to synthesize and secrete insulin for use in the body. A number of factors including proinflammatory cytokines, free fatty acids, and islet amyloid are known to cause beta cell stress. These factors lead to lipotoxic, inflammatory, and ER stress in the beta cell, contributing to beta cell dysfunction and death, and diabetes. While transcriptional responses to beta cell stress are well appreciated, relatively little is known regarding translational responses in the stressed beta cell. To study translation, I established conditions in vitro with MIN6 cells and mouse islets that mimicked UPR conditions seen in diabetes. Cell extracts were then subjected to polyribosome profiling to monitor changes to mRNA occupancy by ribosomes. Chronic exposure of beta cells to proinflammatory cytokines (IL-1 beta, TNF-alpha, IFN-gamma), or to the saturated free fatty acid palmitate, led to changes in global beta cell translation consistent with attenuation of translation initiation, which is a hallmark of ER stress. In addition to changes in global translation, I observed transcript specific regulation of ribosomal occupancy in beta cells. Similar to other privileged mRNAs (Atf4, Chop), Pdx1 mRNA remained partitioned in actively translating polyribosomes during the UPR, whereas the mRNA encoding a proinsulin processing enzyme (Cpe) partitioned into inactively translating monoribosomes. Bicistronic luciferase reporter analyses revealed that the distal portion of the 5’ untranslated region of mouse Pdx1 (between bp –105 to –280) contained elements that promoted translation under both normal and UPR conditions. In contrast to regulation of translation initiation, deoxyhypusine synthase (DHS) and eukaryotic translation initiation factor 5A (eIF5A) are required for efficient translation elongation of specific stress relevant messages in the beta cell including Nos2. Further, p38 signaling appears to promote translational elongation via DHS in the islet beta cell. Together, these data represent new insights into stress induced translational regulation in the beta cell. Mechanisms of differential mRNA translation in response to beta cell stress may play a key role in maintenance of islet beta cell function in the setting of diabetes.

Diabetes, Islet, ER stress, Pdx1

Pancreatic beta cells -- Research

Endoplasmic reticulum -- Pathophysiology

Stress (Physiology)

Cellular signal transduction

Islands of Langerhans -- Research

Small interfering RNA -- Research

Protein folding -- Research

Proteins -- Conformation

Apoptosis

Pancreas -- Growth -- Molecular aspects

Transcription factors

Cellular control mechanisms

Mechanisms of binding diversity in protein disorder : molecular recognition features mediating protein interaction networks

Hsu, Wei-Lun

25 February 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Intrinsically disordered proteins are proteins characterized by lack of stable tertiary structures under physiological conditions. Evidence shows that disordered proteins are not only highly involved in protein interactions, but also have the capability to associate with more than one partner. Short disordered protein fragments, called “molecular recognition features” (MoRFs), were hypothesized to facilitate the binding diversity of highly-connected proteins termed “hubs”. MoRFs often couple folding with binding while forming interaction complexes. Two protein disorder mechanisms were proposed to facilitate multiple partner binding and enable hub proteins to bind to multiple partners: 1. One region of disorder could bind to many different partners (one-to-many binding), so the hub protein itself uses disorder for multiple partner binding; and 2. Many different regions of disorder could bind to a single partner (many-to-one binding), so the hub protein is structured but binds to many disordered partners via interaction with disorder. Thousands of MoRF-partner protein complexes were collected from Protein Data Bank in this study, including 321 one-to-many binding examples and 514 many-to-one binding examples. The conformational flexibility of MoRFs was observed at atomic resolution to help the MoRFs to adapt themselves to various binding surfaces of partners or to enable different MoRFs with non-identical sequences to associate with one specific binding pocket. Strikingly, in one-to-many binding, post-translational modification, alternative splicing and partner topology were revealed to play key roles for partner selection of these fuzzy complexes. On the other hand, three distinct binding profiles were identified in the collected many-to-one dataset: similar, intersecting and independent. For the similar binding profile, the distinct MoRFs interact with almost identical binding sites on the same partner. The MoRFs can also interact with a partially the same but partially different binding site, giving the intersecting binding profile. Finally, the MoRFs can interact with completely different binding sites, thus giving the independent binding profile. In conclusion, we suggest that protein disorder with post-translational modifications and alternative splicing are all working together to rewire the protein interaction networks.

Disordered binding site

Molecular recognition feature

Intrinsically disordered protein

Binding diversity

Protein interaction networks

One-to-many binding

Many-to-one binding

Partner selection

MoRF

Proteins -- Conformation

Proteins -- Structure -- Databases

Nucleic acids -- Research -- Technique

Protein binding

Molecular association -- Research

Proteins -- Analysis

Proteins -- Physiological transport

Peptides