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Notch-1 and IGF-1 as Survivin Regulatory Pathways in Cancer: A DissertationLee, Connie Wing-Ching 04 June 2008 (has links)
The 21st century brought about a dramatic increase in knowledge about genetic and molecular profiles of cancer. This information has validated the complexity of tumor cells and increased awareness of “nodal proteins”, but has yet to advance the development of rational targeted cancer therapeutics. Nodal proteins are critical cellular proteins that collect biological inputs and distribute the information across diverse biological processes. Survivin acts as a nodal protein by interfacing the multiple signals involved in mitosis and apoptosis and functionally integrate proliferation, cell death, and cellular homeostasis. By characterizing survivin as a target of both Type 1 Insulin-like Growth Factor (IGF-1) and Notch developmental signaling, we contribute to the paradigm of survivin as a nodal protein. The two signaling systems, Notch and IGF-1, regulate survivin by two independent mechanisms. Notch activation induces survivin transcription preferentially in basal breast cancer, a breast cancer subtype with poor prognosis and lack of molecular therapies. Activated Notch binds the transcription factor RBP-Jк and drives transcription from the survivin promoter. Notch mediated survivin expression increases cell cycle kinetics promoting tumor proliferation. Inhibition of Notch in a breast xenograft model reduced tumor growth and systemic metastasis. On the other hand, IGF-1 signaling drives survivin protein translation in prostate cancer cells. Binding of IGF-1 to its receptor activates downstream kinases, mammalian target of rapamycin (mTOR) and p70 S6 protein kinase (p70S6K), which modulates survivin mRNA translation to increase the apoptotic threshold. The multiple roles of survivin in tumorigenesis implicate survivin as a rational target for the “next generation” of cancer therapeutics.
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The Role of Dynamic Cdk1 Phosphorylation in Chromosome Segregation in Schizosaccharomyces pombe: A DissertationChoi, Sung Hugh 15 February 2010 (has links)
The proper transmission of genetic materials into progeny cells is crucial for maintenance of genetic integrity in eukaryotes and fundamental for reproduction of organisms. To achieve this goal, chromosomes must be attached to microtubules emanating from opposite poles in a bi-oriented manner at metaphase, and then should be separated equally through proper spindle elongation in anaphase. Failure to do so leads to aneuploidy, which is often associated with cancer. Despite the presence of a safety device called the spindle assembly checkpoint (SAC) to monitor chromosome bi-orientation, mammalian cells frequently possess merotelic kinetochore orientation, in which a single kinetochore binds microtubules emanating from both poles. Merotelically attached kinetochores escape from the surveillance mechanism of the SAC and when cells proceed to anaphase cause lagging chromosomes, which are a leading cause of aneuploidy in mammalian tissue cultured cells. The fission yeast monopolin complex functions in prevention of mal-orientation of kinetochores including merotelic attachments during mitosis. Despite the known importance of Cdk1 activity during mitosis, it has been unclear how oscillations in Cdk1 activity drive the dramatic changes in chromosome behavior and spindle dynamics that occur at the metaphase/anaphase transition. In two separate studies, we show how dynamic Cdk1 phosphorylation regulates chromosome segregation. First, we demonstrate that sequential phosphorylation and dephosphorylation of monopolin by Cdk1 and Cdc14 phosphatase respectively helps ensure the orderly execution of two discrete steps in mitosis, namely sister kinetochore bi-orientation at metaphase and spindle elongation in anaphase. Second, we show that elevated Cdk1 activity is crucial for correction of merotelic kinetochores produced in monopolin and heterochromatin mutants.
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Role of the Monocyte/Macrophage Cell Lineage in Obesity-Related Insulin ResistanceHardy, Olga T. 28 April 2010 (has links)
Background
Obesity is an important risk factor for resistance to insulin-mediated glucose disposal, and is a precursor of type 2 diabetes and other disorders.
Objectives
To identify molecular pathways in adipose tissue and inflammatory cells that may result in obesity-associated insulin resistance, we exploited the fact that not all obese individuals are prone to insulin resistance. Thus the degree of obesity as a variable was removed by studying obese subjects of similar body mass index (BMI) who are insulin-sensitive (IS) versus insulin-resistant (IR).
Methods
Combining gene expression profiling with computational approaches, we determined the global gene expression signatures of omental and subcutaneous adipose tissue samples obtained from 10 obese-IR and 10 obese-IS patients undergoing gastric bypass surgery. In a secondary study, we isolated monocytes from 4 obese-IR, 3 obese-IS, and 4 nonobese-IS adolescent and young adult subjects for purposes of assessing differences in expression of inflammatory genes in monocytes using RT-PCR.
Results
Gene sets related to chemokine activity and chemokine receptor-binding were identified as most highly enriched in the omental tissue from obese-IR compared to obese-IS subjects, independent of BMI. Strikingly, insulin resistance, but not BMI, was associated with increased macrophage infiltration in the omental adipose tissue, as was adipocyte size.
In the adolescent and young adult cohort, expression of two cytokine signaling molecules (IL8, SOCS3) and two downstream products of the JNK pathway (JunB, c-Fos) showed increased expression in the obese-IR subjects compared to the obese-IS and nonobese-IS subjects, suggesting the presence of a proinflammatory phenotype in monocytes in obesity, which is exacerbated in the insulin resistant state.
Conclusions
Our findings demonstrate that inflammation of omental adipose tissue and activation of proinflammatory monocytes is strongly associated with insulin resistance in human obesity. Manipulation of these pathways may result in the prevention of or delay in the onset of obesity-related co-morbidities.
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Role of the cJun NH2-Terminal Kinase (JNK) in Cancer: A DissertationCellurale, Cristina Arrigo 13 July 2010 (has links)
cJun NH2-terminal kinase (JNK) is a member of the MAPK (mitogen- activated protein kinase) signaling family that responds to various extracellular stimuli, such as stress, growth factors, cytokines, or UV radiation. JNK activation can lead to cellular responses including gene expression, growth, survival, and apoptosis. JNK has been implicated in normal developmental processes, including tissue morphogenesis, as well as pathological processes, such as cellular transformation and cancer. JNK exists in three isoforms, and knockout mice have been generated for each isoform; the ubiquitously expressed Jnk1 and Jnk2 have been studied independently, however, the two isoforms are partially functionally redundant. Jnk1-/- Jnk2-/-mice are nonviable, therefore studies of compound JNK-deficiency have been limited to mouse embryonic fibroblasts (MEF). Understanding the role of JNK in epithelial cells is now possible with the creation of conditional JNK knockout animals.
I sought to elucidate the role of JNK in cellular transformation, cancer, and normal development. I employed both in vitro and in vivo approaches. First, I evaluated the role of JNK in cellular transformation using p53-/- Jnk1-/- Jnk2-/- MEF transduced with oncogenic Ras. To extend this study, I examined JNK-deficiency in a Kras-induced model of lung tumorigenesis. Second, I investigated JNK1- and JNK2-deficiency in a p53-mediated model of mammary tumorigenesis. Finally, I examined the role of JNK in mouse mammary gland development by establishing JNK-deficient primary mouse mammary epithelial cells and evaluating JNK-deficient mammary gland transplants. Taken together, this work provides evidence of context-dependent roles for JNK in both normal and pathological cell biology.
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Conformational Lability in MHC II Proteins: A DissertationPainter, Corrie A. 20 May 2011 (has links)
MHC II proteins are heterodimeric glycoproteins that form complexes with antigenic peptides in order to elicit a CD4+ adaptive immune response. Even though there have been numerous MHC II-peptide crystal structures solved, there is little insight into the dynamic process of peptide loading. Through biochemical and biophysical studies, it has been shown that MHC II adopt multiple conformations throughout the peptide loading process. At least one of these conformations is stabilized by the MHC II-like homologue, HLA-DM. The main focus of this thesis is to elucidate alternate conformers of MHC II in an effort to better understand the structural features that enable HLA-DM catalyzed peptide loading. In this thesis, two altered conformations of HLA-DR were investigated, one modeled in the absence of peptide using molecular dynamics, and one stabilized by the mutation αF54C.
The model for the peptide-free form of HLA-DR1 was derived from a molecular dynamics simulation. In this model, part of the alpha-subunit extended-strand region proximal to the peptide binding groove is folded into the peptide-binding groove such that the architecture of the critical peptide binding pocket, P1, as well as the invariant hydrogen bonding network were maintained. Biochemical studies aimed at validating the predicted structural changes were consistent with the model generated from the simulations.
Next, structural studies were carried out on an MHC II mutant, αF54C, which was shown to have unique peptide binding characteristics as well as enhanced susceptibility to HLA-DM. Although this mutation did not affect the affinity for peptide, there was a striking increase in the rate of intrinsic peptide release. Both αF54C and αF54A were over 100-fold more susceptible to HLADM catalyzed peptide release than wild type as well as other mutants introduced along the peptide binding groove. In addition, mutation of the αF54 position results in a higher affinity for HLA-DM, which, unlike wild type, is detectable by surface plasmon resonance. Crystallographic studies resulted in a 2.3 Å resolution structure for the αF54C-Clip complex. There were two molecules in the asymmetric unit, one of which had no obvious deviations from other MHC II-pep complexes and one which had a conformational change as a result of a crystal contact on the αF51 residue, a residue which has been shown to be involved in the HLA-DM/HLA-DR binding interface. The crystal structure of wild type HLA-DR1- Clip was also solved, but did not have the altered conformation even though there was a similar crystal contact at the αF51. These data suggest the altered conformation seen in the mutant structure, results from increased lability in the extended stand region due to the αF54C mutation. As a result of this work, we have developed a new mechanistic model for how structural features of MHC II influence DM mediated peptide release.
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Antagonistic Pleiotropy: The Role of Smurf2 in Cancer and Aging: A DissertationRamkumar, Charusheila 01 June 2012 (has links)
In response to telomere shortening, oxidative stress, DNA damage or aberrant activation of oncogenes, normal somatic cells exit the cell cycle and enter an irreversible growth arrest termed senescence. The limited proliferative capacity imposed by senescence on cells impedes the accumulation of mutations necessary for tumorigenesis and prevents proliferation of cells at risk of neoplastic transformation. Opposite to the tumor suppressor function, accumulation of senescent cells in adult organisms is thought to contribute to aging by depleting the renewal capacity of tissues and stem/progenitor cells, and by interfering with tissue homeostasis and functions. The Antagonistic Pleiotropy Theory of senescence proposes that senescence is beneficial early in life by acting as a tumor suppressor, but harmful late in life by contributing to aging. Recent studies have provided evidence strongly supporting the tumor suppressor function of senescence, however, direct evidence supporting the role of senescence in aging remains largely elusive.
In this thesis, I describe studies to test the Antagonistic Pleiotropy Theory of senescence in tumorigenesis and aging. The approach that I have taken is to alter the senescence response in vivo by changing the expression of a senescence regulator in mice. The consequence of altered senescence response on tumorigenesis and stem cell self-renewal was investigated. The senescence regulator I studied is Smurf2, which has been shown previously to activate senescence in culture. I hypothesized that the senescence response will be impaired by Smurf2 deficiency in vivo. Consequently, Smurf2-deficient mice will develop tumors at an increased frequency, but also gain enhanced self-renewal capacity of stem/progenitor cells with age.
I generated a Smurf2-deficient mouse model, and found that Smurf2 deficiency attenuated p16 expression and impaired the senescence response in primary cells and tissues. Smurf2-deficient mice exhibited an increased susceptibility to spontaneous tumorigenesis, indicating that Smurf2 is a tumor suppressor. At the premalignant stage of tumorigenesis, a defective senescence response was documented in the Smurf2-deficient mice, providing a mechanistic link between impaired senescence response and increased tumorigenesis. The majority of tumors developed in Smurf2-deficent mice were B-cell lymphomas with an origin in germinal centers of the spleen and a phenotype resembling human diffuse large B-cell lymphoma (DLBCL). I discovered that Smurf2 mediated ubiquitination of YY1, a master regulator of germinal centers. Stabilization of YY1 in the absence of Smurf2 was responsible for increased cell proliferation and drove lymphomagenesis in Smurf2-deficient mice. Consistently, a significant decrease of Smurf2 expression was observed in human primary DLBCL samples, and more importantly, a low level of Smurf2 expression in DLBCL correlated with poor survival prognosis. Moreover, I found that hematopoietic stem cells (HSCs) in Smurf2-deficient mice had enhanced function compared to wild-type controls. This enhanced stem cell function was associated with increased cell proliferation and decreased p16 expression, suggesting that defective senescence response in Smurf2-deficient mice leads to increased self-renewal capacity of HSCs. My study, for the first time, offers direct genetic evidence of an important tumor suppressor function for Smurf2 as well as its function in contributing to stem cell aging. Collectively, these findings provide strong evidence supporting the Antagonistic Pleiotropy Theory of senescence in tumorigenesis and aging.
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Mechanical Activation of Valvular Interstitial Cell Phenotype: A DissertationThrom Quinlan, Angela M. 01 August 2012 (has links)
During heart valve remodeling, and in many disease states, valvular interstitial cells (VICs) shift to an activated myofibroblast phenotype which is characterized by enhanced synthetic and contractile activity. Pronounced alpha smooth muscle actin (αSMA)-containing stress fibers, the hallmark of activated myofibroblasts, are also observed when VICs are placed under tension due to altered mechanical loading in vivo or during in vitro culture on stiff substrates or under high mechanical loads and in the presence of transforming growth factor-beta1 (TGF-β1). The work presented herein describes three distinct model systems for application of controlled mechanical environment to VICs cultured in vitro. The first system uses polyacrylamide (PA) gels of defined stiffness to evaluate the response of VICs over a large range of stiffness levels and TGF-β1 concentration. The second system controls the boundary stiffness of cell-populated gels using springs of defined stiffness. The third system cyclically stretches soft or stiff two-dimensional (2D) gels while cells are cultured on the gel surface as it is deformed. Through the use of these model systems, we have found that the level of 2D stiffness required to maintain the quiescent VIC phenotype is potentially too low for a material to both act as matrix to support cell growth in the non-activated state and also to withstand the mechanical loading that occurs during the cardiac cycle. Further, we found that increasing the boundary stiffness on a three-dimensional (3D) cell populated collagen gel resulted in increased cellular contractile forces, αSMA expression, and collagen gel (material) stiffness. Finally, VIC morphology is significantly altered in response to stiffness and stretch. On soft 2D substrates, VICs cultured statically exhibit a small rounded morphology, significantly smaller than on stiff substrates. Following equibiaxial cyclic stretch, VICs spread to the extent of cells cultured on stiff substrates, but did not reorient in response to uniaxial stretch to the extent of cells stretched on stiff substrates. These studies provide critical information for characterizing how VICs respond to mechanical stimuli. Characterization of these responses is important for the development of tissue engineered heart valves and contributes to the understanding of the role of mechanical cues on valve pathology and disease onset and progression. While this work is focused on valvular interstitial cells, the culture conditions and methods for applying mechanical stimulation could be applied to numerous other adherent cell types providing information on the response to mechanical stimuli relevant for optimizing cell culture, engineered tissues or fundamental research of disease states.
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Human Rad51: Regulation of Cellular Localization and Function in Response to DNA Damage: A DissertationBennett, Brian Thomas 07 February 2006 (has links)
Repair of DNA double-strand breaks via homologous recombination is an essential pathway for vertebrate cell development and maintenance of genome integrity throughout the organism’s lifetime. The Rad51 enzyme provides the central catalytic function of homologous recombination while many other proteins are involved in regulation and assistance of Rad51 activity, including a group of five proteins referred to as Rad51 paralogs (Rad51B, Rad51C, Rad51D, Xrcc2, Xrcc3). At the start of my work, cellular studies of human Rad51 (HsRad51) had shown only that it forms distinct nuclear foci in response to DNA damage. Additionally, no information regarding the cellular localization, potential DNA damage-induced redistribution or cellular functions for any of the Rad51 paralog proteins was available. Therefore, the goals of this work were to (1) present a more complete description of the cellular localization and DNA damage-induced redistribution of Rad51 and the two paralog proteins known to specifically associate with Rad51, Rad51C and Xrcc3, and (2) to define specific functional roles for Rad51C and Xrcc3 in mediating Rad51 activity. I focused on the use of cellular, RNAi and immunofluorescence methods to study endogenous Rad51, Rad51C and Xrcc3 in human cells.
In my initial studies we showed for the first time that Xrcc3 forms distinct foci in both the nucleus and cytoplasm independent of DNA damage, that the distribution of these foci did not change significantly throughout the time course of DNA damage and repair, and that Xrcc3 focus formation is independent of Rad51. Additionally, and unlike most previously published images of nuclear Rad51, we found that the majority of DNA damage-induced nuclear Rad51 foci do not colocalize with gamma H2AX, a histone marker used to indicate the occurrence of DNA double strand breaks.
As a consequence of these initial outcomes, a significant amount of effort was devoted to developing and optimizing immunofluorescence methods. Importantly, we developed a purification method for commercially available monoclonal antibodies against Rad51C and Xrcc3 that significantly improved their reactivity and specificity. My next study concentrated on Rad51C. Similar to Xrcc3, we found for the first time that Rad51C forms distinct nuclear and cytoplasmic foci independent of DNA damage and Rad51. An additional and surprising outcome was our discovery that Rad51C plays an important role in regulating the ubiquitination and proteasome-mediated degradation of Rad51. While biochemical functions for Rad51 paralog proteins had been suggested in the literature, this was the first demonstration of a specific biochemical function for Rad51C that contributes directly to the Rad51 activity in the homologous recombination pathway. Our improved immunofluorescence methods allowed us to see the accumulation of Rad51, Rad51C and Xrcc3 at the nuclear periphery early in response to DNA damage, suggesting the existence of a DNA damage-dependent trafficking mechanism that promoted movement of these proteins from the cytoplasm to the nucleus. This led to further studies in which we show distinct co-localization of cytoplasmic Rad51 with actin as well as alpha and beta tubulin. Using both immunofluorescence and sub-cellular fractionation methods our recent results strongly suggest that trafficking of Rad51 to the nucleus in response to DNA damage is regulated at least in part by its association with cytoskeletal proteins, and involves movement of both existing pools of Rad51 and newly synthesized protein.
In a particularly exciting development, in collaboration with Leica Microsystems and Dr. Joerg Bewersdorf at The Jackson Laboratory, Bar Harbor, ME., I have been able to exploit a new technology, 4Pi microscopy, to provide the first images of endogenous nuclear proteins using this method.
Results presented in this thesis have added significantly to a more complete understanding of cellular localization Rad51, Rad51C and Xrcc3, and have provided important insights into possible mechanisms of cellular trafficking of Rad51 in response to response to DNA damage. Additionally, we have defined a specific function for Rad51C in its regulation of Rad51 ubiquitination. These findings open several new avenues of investigation for furthering our understanding of the cellular and molecular functions of proteins with critical roles in the maintenance of genome integrity in human cells.
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Structural and Functional Studies of the KCNQ1-KCNE K<sup>+</sup> Channel Complex: A DissertationGage, Steven D. 09 September 2008 (has links)
KCNQ1 is a homotetrameric voltage-gated potassium channel expressed in cardiomyocytes and epithelial tissues. However, currents arising from KCNQ1 have never been physiologically observed. KCNQ1 is able to provide the diverse potassium conductances required by these distinct cell types through coassembly with and modulation by type I transmembrane β-subunits of the KCNE gene family.
KCNQ1-KCNE K+ channels play important physiological roles. In cardiac tissues the association of KCNQ1 with KCNE1 gives rise to IKs, the slow delayed outwardly rectifying potassium current. IKs is in part responsible for repolarizing heart muscle, and is therefore crucial in maintaining normal heart rhymicity. IKschannels help terminate each action potential and provide cardiac repolarization reserve. As such, mutations in either subunit can lead to Romano-Ward Syndrome or Jervell and Lange-Nielsen Syndrome, two forms of Q-T prolongation. In epithelial cells, KCNQ1-KCNE1, KCNQ1-KCNE2 and KCNQ1-KCNE3 give rise to potassium currents required for potassium recycling and secretion. These functions arise because the biophysical properties of KCNQ1 are always dramatically altered by KCNE co-expression.
We wanted to understand how KCNE peptides are able to modulate KCNQ1. In Chapter II, we produce partial truncations of KCNE3 and demonstrate the transmembrane domain is necessary and sufficient for both assembly with and modulation of KCNQ1. Comparing these results with published results obtained from chimeric KCNE peptides and partial deletion mutants of KCNE1, we propose a bipartite modulation residing in KCNE peptides. Transmembrane modulation is either active (KCNE3) or permissive (KCNE1). Active transmembrane KCNE modulation masks juxtamembranous C-terminal modulation of KCNQ1, while permissive modulation allows C-terminal modulation of KCNQ1 to express. We test our hypothesis, and demonstrate C-terminal Long QT point mutants in KCNE1 can be masked by active trasnsmembrane modulation.
Having confirmed the importance the C-terminus of KCNE1, we continue with two projects designed to elucidate KCNE1 C-terminal structure. In Chapter III we conduct an alanine-perturbation scan within the C-terminus. C-terminal KCNE1 alanine point mutations result in changes in the free energy for the KCNQ1-KCNE1 channel complex. High-impact point mutants cluster in an arrangement consistent with an alphahelical secondary structure, "kinked" by a single proline residue. In Chapter IV, we use oxidant-mediated disulfide bond formation between non-native cysteine residues to demonstrate amino acid side chains residing within the C-terminal domain of KCNE1 are close and juxtaposed to amino acid side chains on the cytoplasmic face of the KCNQ1 pore domain. Many of the amino acids identified as high impact through alanine perturbation correspond with residues identified as able to form disulfide bonds with KCNQ1. Taken together, we demonstrate that the interaction between the C-terminus of KCNE1 and the pore domain of KCNQ1 is required for the proper modulation of KCNQ1 by KCNE1, and by extension, normal IKs function and heart rhymicity.
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Defining the Importance of Fatty Acid Metabolism in Maintaining Adipocyte Function: A DissertationChristianson, Jennifer L. 27 April 2009 (has links)
Although once considered a simple energy storage depot, the adipose tissue is now known to be a powerful regulator of whole body insulin sensitivity and energy metabolism. This metabolically dynamic organ functions to safely store excess fatty acid as triglyceride, thereby preventing lipotoxicity in peripheral tissues and the development of insulin resistance. In addition, the adipose tissue acts as an endocrine organ and secretes factors, called adipokines, which influence whole body insulin sensitivity and glucose homeostasis. Therefore, understanding adipose tissue development and biology is essential to understanding whole body energy metabolism.
A master regulator of adipose tissue development and whole body insulin sensitivity is the nuclear receptor, PPARγ. Due to the importance of this nuclear receptor in maintaining adipocyte function, disruptions in PPARγ activity result in severe metabolic abnormalities, such as insulin resistance and type 2 diabetes. Conversely, PPARγ activation by synthetic agonists ameliorates these conditions, demonstrating the potent control this nuclear receptor has on whole body metabolism. Therefore, understanding how PPARγ expression and activity are regulated, particularly in the adipose tissue, is paramount to understanding the pathogenesis of type 2 diabetes.
While there are several synthetic PPARγ agonists available, identifying the endogenous ligand or ligands is still an area of intense investigation. Since fatty acids can induce PPARγ activation, in the first part of this thesis, I screened several fatty acid metabolizing enzymes present in the adipocyte to identify novel modulators of PPARγ activity. These studies revealed that the fatty acid Δ9 desaturase, Stearoyl CoA Desaturase 2 (SCD2), is absolutely required for 3T3-L1 adipogenesis and to maintain adipocyte-specific gene expression in fully differentiated cells. Although SCD2 does not appear to regulate PPARγ ligand production, it does potently regulate PPARγ activity by maintaining the synthesis of PPARγ protein. Surprisingly, this effect was found only with SCD2 and not with the highly homologous protein, SCD1. Therefore, these findings identify separate cellular functions for these SCD isoforms and reveal a novel and essential role for fatty acid desaturation in the adipocyte.
Equally important to understanding PPARγ regulation is identifying the downstream mechanisms by which PPARγ activation improves insulin sensitivity. Evidence suggests that the PPARγ target gene, Cidea, is involved in mediating insulin sensitivity by binding to lipid droplets and promoting lipid storage in the adipocyte. Therefore, the second part of thesis provides mechanistic detail into Cidea function by showing that the carboxy terminal 104 amino acids is necessary and sufficient for lipid droplet targeting and the stimulation of triglyceride storage. However, these studies also identified a novel function for Cidea, which requires both the carboxy and amino termini: to induce larger and fewer droplets from smaller dispersed droplets, indicating the possible fusion of droplets. Perhaps this striking change in lipid droplet morphology allows tighter packing and more efficient storage of triglyceride and identifies a novel role for Cidea in lipid metabolism.
The results presented in this thesis elucidate key aspects of lipid metabolism that maintain adipocyte function: SCD2 is required to maintain PPARγ protein expression in the mouse; Cidea is a downstream effector of PPARγ activity by promoting efficient triglyceride storage. Therefore, these findings enhance our understanding of adipocyte biology.
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