Browsing by Author "Kontos, Christopher D"
Results Per Page
Sort Options
Item Open Access A Paradoxical Role for PTEN in the Cellular Response to Hypoxia(2010) Melonakos, Janet HartRegulation of cell growth is controlled by a variety of factors, including a number of oncogenes and tumor suppressors. PTEN is an inositol phosphatase that regulates cell growth by hydrolyzing the phospholipid products of PI3K. PTEN is mutated in a number of cancers, leading to its characterization as an important tumor suppressor. Recent data indicate that PTEN may also perform important functions that are independent of its phosphatase activity, most notably within the nucleus. Studies in this thesis addressed a novel role for PTEN in the regulation of the cellular response to hypoxia.
PTEN overexpression significantly increased hypoxic gene expression independent of its catalytic activity, while shRNA-mediated silencing of PTEN significantly inhibited hypoxia-mediated HRE-luciferase activity. Nuclear-localized PTEN was more effective in promoting HRE activity than nuclear-excluded PTEN. These results suggested a scaffolding function of PTEN in the hypoxic nucleus. To identify specific gene targets regulated by PTEN in hypoxia, a custom oligo-array consisting of 46 hypoxia-responsive genes was utilized following both gain- and loss-of- PTEN function. Based on real-time quantitative results, PTEN positively regulated genes involved in metabolism (PFKFB3, PFKFB4, ALDOA, PGK-1), oxygen supply (VEGFA, EPO), cell growth (Tgf-a, TERT, cyclin D1, BNIP3), motility (E-cadherin) and transcription (DEC2). A single missense mutation at isoleucine 224 (I224M) of PTEN, however, abrogated the ability of PTEN to regulate the hypoxia response without affecting its lipid phosphatase activity. PTEN has previously been shown to bind to the co-activator p300 and to affect p53 acetylation and stabilization. As p300 is also a co-activator for the HIF proteins, we hypothesized that PTEN's association with p300 would promote the HIF/p300 complex to positively regulate hypoxic gene transcription. Overexpression of PTEN-WT extended the half-life of p300 and histone acetyltransferase activity of p300 in hypoxia, while overexpression of PTEN-I224M or PTEN silencing decreased both. In vivo, these effects resulted in a significant increase in hypoxic area in PTEN-null tumors compared to tumors expressing endogenous levels of PTEN, suggesting an inability to mount a hypoxia response necessary for revascularization of the tissue. PTEN's effect on p300 extended to other functions of p300 outside of the hypoxia response, most notably p300's role in p53 stability and p53-mediated gene transcription. Overexpression of PTEN resulted in an increase in p53 reporter activity following DNA damage (mitomycin C treatment). PTEN silencing or overexpression of PTEN-I224M resulted in abrogation of these effects. Taken together, these findings demonstrate that PTEN is required for the hypoxia response and they suggest that PTEN acts as a scaffold for p300 and the HIF machinery in the hypoxic nucleus independent of its canonical lipid phosphatase activity. These results may have important implications for the treatment of tumors in which PTEN is lost or mutated. The potential use of PTEN-I224M as a therapeutic is also discussed
Item Open Access An Essential Role for Skeletal Muscle Progenitor Cells in Response to Ischemia in Vascular Disease(2020) Abbas, HasanPeripheral artery disease (PAD) is nearly as common as coronary artery disease, but few effective treatments exist, and it is associated with significant morbidity and mortality. Although PAD studies have focused on the vascular response to ischemia, studies from our lab indicate that skeletal muscle cells, particularly Pax7-expressing muscle progenitor cells (MPCs), also known as satellite cells, may play a critically important role in determining the phenotypic manifestation of PAD. Here, we demonstrate that genetic ablation of satellite cells in a murine model of PAD resulted in a complete absence of normal muscle regeneration following ischemic injury, despite a lack of morphological or physiological changes in resting muscle. Compared to ischemic muscle of control mice (Pax7WT), the ischemic limb of Pax7-deficient mice (Pax7∆) was unable to generate significant force 7- or 28-days after hind limb ischemia (HLI) in ex vivo force measurement studies. A dramatic increase in adipose infiltration was observed 28 days after HLI in Pax7∆ mice, which replaced functional muscle, a phenotype seen in PAD patients with severe disease. To investigate the mechanism of these adipogenic changes, we first investigated whether a pool of progenitor cells known as fibro-adipogenic progenitors (FAPs) was upregulated and demonstrated an increase in the expression of their canonical marker PDGFRα in Pax7∆ mice. Inhibition of FAPs using the drug batimastat resulted in a decrease in muscle adipose tissue and a corresponding increase in fibrosis. MPCs cultured from mouse muscle tissue failed to form myotubes in vitro following depletion of satellite cells in vivo, and they displayed an increased propensity to differentiate into fat in adipogenic medium. Importantly, this phenotype was recapitulated in patients with critical limb ischemia (CLI), the most severe form of PAD. Skeletal muscle samples from CLI patients demonstrated an increase in adipose deposition in more ischemic regions of muscle, which corresponded with a decrease in the number of satellite cells in those regions. Collectively, these data demonstrate that Pax7+ MPCs are required for normal muscle regeneration after ischemic injury, and they suggest that targeting muscle regeneration may be an important therapeutic approach to prevent muscle degeneration in PAD. Future studies will focus on the role of other supporting cells (such as pericytes) and the cross-talk between FAPs and satellite cells in ischemic muscle regeneration.
Item Open Access Characterizing the Role of the Previously Undescribed Protein Caskin2 in Vascular Biology(2016) Mueller, Sarah BethMaintenance of vascular homeostasis is an active process that is dependent on continuous signaling by the quiescent endothelial cells (ECs) that line mature vessels. Defects in vascular homeostasis contribute to numerous disorders of significant clinical impact including hypertension and atherosclerosis. The signaling pathways that are active in quiescent ECs are distinct from those that regulate angiogenesis but are comparatively poorly understood. Here we demonstrate that the previously uncharacterized scaffolding protein Caskin2 is a novel regulator of EC quiescence and that loss of Caskin2 in mice results in elevated blood pressure at baseline. Caskin2 is highly expressed in ECs from various vascular beds both in vitro and in vivo. When adenovirally expressed in vitro, Caskin2 inhibits EC proliferation and migration but promotes survival during hypoxia and nutrient deprivation. Likewise, loss of Caskin2 in vivo promotes increased vascular branching and permeability in mouse and zebrafish models. Caskin2 knockout mice are born in normal Mendelian ratios and appear grossly normal during early adulthood. However, they have consistently elevated systolic and diastolic blood pressure at baseline and significant context-dependent abnormalities in systemic metabolism (e.g., body weight, fat deposition, and glucose homeostasis). Although the precise molecular mechanisms of these effects remain unclear, we have shown that Caskin2 interacts with several proteins known to have important roles in endothelial biology and cardiovascular disease including the serine/threonine phosphatase PP1, the endothelial receptor Tie1, and eNOS, which is a critical regulator of vascular homeostasis. Ongoing work seeks to further characterize the functions of Caskin2 and its mechanisms of action with a focus on how Caskin2-mediated regulation of endothelial phenotype relates to its systemic effects on cardiovascular and metabolic function.
Item Embargo Investigating the Metabolic Reprogramming of Ovarian Cancer(2023) Bose, ShreeOvarian cancer (OC) is the most lethal gynecological malignancy, with aggressive metastatic disease responsible for the majority of ovarian cancer related deaths. Despite the clinical significance of OC omental metastases, the precise molecular mechanisms which drive this phenomenon have not been well characterized, making the resulting aggressive phenotype even more puzzling. Recent evidence has highlighted the importance of metabolic reprograming in driving this tumoral behavior, with OC metastases adapting to utilize nutrients available in the metastatic niche to rapidly proliferate. To better understand the metabolic changes that underlie the aggressive nature of OC, we undertook a broad investigation to better characterize metabolic reprogramming in ovarian cancer, with a focus on omental metastasis and chemoresistance. Firstly, we sought to expand the arsenal of tools used to study OC metabolism. In particular, we were interested in using organoids, self-organizing, expanding 3D cultures derived from stem cells, to study OC. Using tissue derived from patients, these miniaturized models have been shown to recapitulate various aspects of patient physiology and disease phenotypes including genetic profiles and drug sensitivities. However, as metabolism modeling in these 3D cultures remains yet unexplored, we aimed to introduce genetically encoded, fluorescent biosensors as robust tools to interrogate metabolism in this context. In Chapter 2, we detail our investigation in which we transfected plasmids encoding the metabolic biosensors HyPer, iNap, Peredox, and Perceval into 15 ovarian cancer cell lines to assay oxidative stress, NADPH/NADP+, NADH/NAD+, and ATP/ADP, respectively. Fluorescence readings were used to assay dynamic metabolic responses to omental conditioned media (OCM) and 100 μM carboplatin treatment. SKOV3 cells expressing HyPer were imaged as 2D monolayers, 3D organoids, and as in vivo metastases via an intravital omental window. We further established organoids from ascites collected from Stage III/IV OC patients with carboplatin-resistant or carboplatin-sensitive tumors (n=8 total). These patient-derived organoids (PDOs) were engineered to express HyPer, and metabolic readings of oxidative stress were performed during treatment with 100 μM carboplatin. Exposure to OCM or carboplatin induced heterogenous metabolic changes in 15 OC cell lines, as measured using metabolic sensors. Oxidative stress of in vivo omental metastases, measured via intravital imaging of metastasizing SKOV3-HyPer cells, was more closely recapitulated by SKOV3-HyPer organoids than by 2D monolayers. Finally, carboplatin treatment of HyPer-expressing PDOs induced higher oxidative stress in organoids derived from carboplatin-resistant patients than from those derived from carboplatin-sensitive patients. Our study showed that biosensors provide a useful method of studying dynamic metabolic changes in preclinical models of OC, including 3D organoids and intravital imaging. As 3D models of OC continue to evolve, the repertoire of biosensors will likely serve as valuable tools to probe the metabolic changes of clinical importance in OC. Secondly, in Chapter 3, we focused on characterizing the role of the pentose phosphate pathway (PPP), a metabolic pathway responsible for producing nucleotide pentose precursors through a nonoxidative series of reactions and the reducing equivalent NADPH through a distinct oxidative branch. Using computational analysis of gene expression data, metabolomics analysis, and biochemical approaches, we observed upregulation of the pentose phosphate pathway (PPP), a key cellular redox homeostasis mechanism, of metastatic OC cells in the omentum compared to primary OC tumors. We established these increases coincided with increased oxidative stress experienced by OC cells in the omental microenvironment, using both established oxidative stress assays and genetically encoded biosensors; and sought to understand if the PPP was an important cellular mechanism to compensate for this metabolic pressure. Indeed, both shRNA-mediated and pharmacological inhibition of G6PD, the rate-limiting enzyme of the PPP, reduces tumor burden in pre-clinical models of OC, suggesting this adaptive metabolic dependency is important for OC omental metastasis. This work collectively illustrates the importance of characterizing OC metabolism and supports future efforts to develop tools to more effectively investigate and target aspects of metabolic reprogramming in OC which drive metastasis and chemoresistance.
Item Open Access Metabolic Targeting of Cancer Cells: Two Molecular Mechanisms Involving Glucose Metabolism(2009) Quinones, Quintin JoseSelective therapeutic targeting of tumors requires identification of differences between the homeostatic requirements of cancer and host cells. One such difference is the manner in which cancer cells acquire energy. Cancer cells often grow in an environment of local hypoxia; under these conditions tumor cells depend on glycolysis for energy, but are unable to perform oxidative phosphorylation. Many tumor cells, despite normoxic conditions, continue to perform glycolysis without oxidative phosphorylation. The net result of glycolysis without oxidative phosphorylation is twofold: the need to consume a greater amount of glucose than a non-cancerous host cell, and the burden of increased intracellular lactic acid. The proteins responsible for the transport of lactic acid in and out of cells are known as the monocarboxylate transporters (MCTs). Monocarboxylate Transporter 1 (MCT1) and Monocarboxylate Transporter 4 (MCT4) are the MCTs that play a major role in the transport of lactic acid. Tumor cells depend on MCT1 and MCT4 activity to excrete excess intracellular lactic acid to maintain neutral intracellular pH and homeostasis. Using human neuroblastoma and prostate cancer cell lines this work demonstrates that tumor cells can be selectively targeted tumor under conditions of hypoxia or acidosis in vitro with the drug lonidamine, with a small molecule inhibitor selective for MCT1, or with RNA interference of MCT1. Inhibition of MCT1 activity in neuroblastoma cells under acidic extracellular conditions results in intracellular acidification and cell death. MCT1 mRNA is expressed in human neuroblastoma and positively correlated with clinical risk profile. Inhibition of MCT1 activity in hypoxic prostate cancer cells results in a reduction of lactate excretion, decreased intracellular pH, inhibition of ATP production, and subsequent cell death. MCT1 expression in sections of human prostate tumors has been demonstrated to validate MCT1 as a target in prostate cancer.
Through the Pasteur and Warburg effects, tumors have an increased demand for glucose. Some cancers store glycogen, but the reasons for this are largely unknown. It is hypothesized that tumor glycogen is used to promote tumor survival during transient hypoxia or low glucose, and that the mechanisms by which glycogen is stored is a potential therapeutic target in cancer. Tumors from human cell lines (WiDr, PC3, FaDu) have been grown in nude mice, sectioned and stained to measure glycogen storage. Using consecutive frozen sections, levels of hypoxia, glucose, lactate, ATP, and CD31, an endothelial cell marker, have been determined. These sections have been employed to elucidate the "architecture" of tumor metabolism in terms of vessel distance. Additionally, PAS-stained EF5 labeled human tumor samples were used to obtain calibrated hypoxia measurements to correlate with PAS. These studies demonstrate a correlation between hypoxia and the formation of glycogen deposits in human tumors and nude mouse xenografts. In cell culture, formation of glycogen deposits after exposure to hypoxia has been demonstrated, in addition to expression of glycogen synthase in human cancer cell lines.
The development of novel selective cancer chemotherapeutics will require the identification of differences between cancerous cells and normal host cells to exploit as targets. Several differences in metabolism, including the need to excrete excess lactic acid and store glycogen under hypoxic conditions, are such targets. Novel therapeutics exploiting these targets should be effective against cancer cells and minimally toxic to host cells.
Item Open Access Soluble Tie 2: Mechanisms of Regulation and Role in Modulating Angiogenesis(2009) Findley, Clarence MauriceAngiogenesis, the production of new vessels from pre-existing vasculature, is a complex biological process that is dependent on a series of regulated events, including endothelial cell (EC) proliferation, migration, survival, and capillary morphogenesis (tube formation). These events are required for angiogenesis to occur properly and the steps are regulated by a variety of vascular growth factors and their receptors. Tie2, an endothelial receptor tyrosine kinase (RTK), is required for embryonic and postnatal angiogenesis. Studies have demonstrated that Tie2 is proteolytically cleaved, producing a 75 kDa soluble receptor fragment (sTie2). However, the mechanisms and function of sTie2 have not been elucidated. Here, we investigated signaling pathways and effector molecule(s) responsible for Tie2 cleavage. Additionally, we investigated the role of other growth factors and conditions on the degree of Tie2 cleavage. Finally, we examined sTie2 levels in peripheral artery disease, a human model of ischemic disease. We demonstrated that Tie2 cleavage is VEGF- and PI3K/Akt-dependent and sTie2 can bind Ang1 and Ang2 and prevent ligand-mediated Tie2 activation and downstream cellular responses. Also, ADAM15 cleaves Tie2 in a hypoxia-dependent manner and this response was also observed to be VEGF-mediated. With respect to peripheral artery disease, sTie2 levels were only significantly elevated in the most angiogenically compromised group (critical limb ischemia) of patients. These data shed light on the mechanism and function of Tie2 cleavage and suggest a role for sTie2 in mediating the angiogenic process.
Item Open Access The Role of Angiopoietin-2 in Signaling Through the Endothelial Receptor Tyrosine Kinase Tie1(2010) Otvos, Balint IstvanA functioning vasculature is critical for the supply of nutrients to other systems as well as a host of physiologic and pathologic processes. Vascular development and maintenance are tightly regulated by a number of signaling processes, among which the Tie proteins are two functioning receptors. Although they have been shown to exhibit essential roles in endothelial cell sprouting and quiescence, the mechanistic details of Tie interactions and the effects of their associations with the Angiopoietins have not been elucidated. Studies in this thesis investigated the effects of Ang2 on Tie1 activation, signaling, and cellular responses within the context of both native and immortalized endothelial cells. Additionally, we investigated the role of Ang2 in the cellular reorganization and subsequent downregulation of Tie1. We observed that Ang2, but not Ang1, induces phosphorylation of Tie1 in endothelial cells and that the extracellular domain of Tie2 is required for Ang2-mediated activation of Tie1. Furthermore, we demonstrated that Tie1 activation leads to signaling through the Akt axis, and the consequent stimulation of anti-apoptotic and pro-proliferative cellular effects. Additionally, we demonstrated that Ang2 induces a concentration and time dependent downregulation of Tie1, and that Tie2's role in the process appears to be recruitment of the ligand to the multimeric Tie complexes. Interestingly, although Ang2 stimulation is necessary, we demonstrated that Ang2 activation of Tie1 receptor complexes is not required for ligand induced downregulation of the receptor. Finally, we characterized the modulatory role of Tie1 with regards to Angiopoietin signaling through Tie2, and observed that removal of Tie1 from the surface of endothelial cells induces Ang2 activation of Tie2 leading to increases in cell survival signaling cascades. Taken together, these data shed new light on Angiopoietin signaling through the Tie receptors, further characterize the interactions between Tie1 and Tie2, suggest novel forms of endothelial cell regulation within developing and mature vasculature, and may have implications in signaling within a host of physiologic and pathologic states.
Item Open Access The Role of Tie1 Threonine Phosphorylation in a Novel Angiogenesis Regulatory Pathway(2015) Reinardy, JessicaThe endothelial receptor tyrosine kinase (RTK) Tie1 was discovered over 20 years ago, yet its precise function and mode of action remain enigmatic. To shed light on Tie1’s role in endothelial cell biology, we investigated a potential threonine phosphorylation site within the juxtamembrane domain of Tie1. Expression of a non-phosphorylatable mutant of this site (T794A) in zebrafish (Danio rerio) significantly disrupted vascular development, resulting in fish with stunted and poorly branched intersomitic vessels. Similarly, T794A-expressing human umbilical vein endothelial cells formed significantly shorter tubes with fewer branches in three-dimensional Matrigel cultures. However, mutation of T794 did not alter Tie1 or Tie2 tyrosine phosphorylation or downstream signaling in any detectable way, suggesting that T794 phosphorylation may regulate a Tie1 function independent of its activity as a kinase. Although T794 is within a consensus Akt phosphorylation site, we were unable to identify a physiological activator of Akt that could induce T794 phosphorylation, suggesting that Akt is not the physiological Tie1-T794 kinase. However, the small GTPase Ras-related C3 botulinum toxin substrate 1 (Rac1), which is required for angiogenesis and capillary morphogenesis, was found to associate with phospho-T794 but not the non-phosphorylatable T794A mutant. Pharmacological activation of Rac1 induced downstream activation of p21-activated kinase (PAK1) and T794 phosphorylation in vitro, and inhibition of PAK1 abrogated T794 phosphorylation. Our results provide the first demonstration of a signaling pathway mediated by Tie1 in endothelial cells, and they suggest that a novel feedback loop involving Rac1/PAK1-mediated phosphorylation of Tie1 on T794 is required for proper angiogenesis.