Global ETD Search

341	Oxygen delivery-utilization matching in skeletal muscle Hirai, Daniel Muller January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / David C. Poole / The overall aim of this dissertation is to better understand the mechanisms determining skeletal muscle oxygen delivery-utilization matching in health and disease. Emphasis is directed toward the role of nitric oxide (NO) bioavailability in modulating muscle microvascular oxygenation (PO2mv; the sole driving force for blood-myocyte oxygen flux) during transitions in metabolic demand. The first investigation of this dissertation (Chapter 2) demonstrates that alterations in NO bioavailability have a major impact on skeletal muscle PO2mv kinetics following both the onset and cessation of contractions. Specifically, increased NO levels (via the NO donor sodium nitroprusside; SNP) elevates whereas reduced NO levels (non-specific NOS inhibition with NG-nitro-L-arginine methyl ester; L-NAME) diminishes muscle PO2mv at the onset and during recovery from contractions in the spinotrapezius muscle of healthy young rats. Consistent with these results, inhibition of the neuronal NO synthase isoform (S-methyl-L-thiocitrulline; SMTC; Chapter 3) reveals alterations in NO-mediated regulation of skeletal muscle PO2mv with advanced age that likely contribute to exercise intolerance in this population. In Chapter 4 we observed that pronounced oxidative stress is implicated in these pathological responses seen in aged and diseased states. Transient elevations in the oxidant hydrogen peroxide to levels seen in the early stages of senescence and cardiovascular diseases promote detrimental effects on skeletal muscle contractile function (i.e., augmented oxygen cost of force production). Chapter 5 demonstrates that endurance exercise training improves skeletal muscle microvascular oxygenation (i.e., greater PO2mv and slower PO2mv kinetics) across the metabolic transient partly via enhanced NO-mediated function in healthy young individuals. These data carry important clinical implications given that exercise training may ameliorate NO-mediated function, muscle microvascular oxygenation deficits and consequently exercise intolerance in aged and diseased populations. In conclusion, alterations in NO bioavailability have a major impact on the dynamic balance between skeletal muscle oxygen delivery and utilization (i.e., PO2mv kinetics) in health and disease. While advanced age or the predations of disease impair considerably skeletal muscle microvascular oxygenation, exercise training-induced adaptations on the oxygen transport system constitute a non-pharmacological therapeutic intervention potentially capable of mitigating these microcirculatory deficits. Exercise Physiology Nitric oxide Microcirculation Biology, Animal Physiology (0433) Health Sciences (0566) Physiology (0719)
342	Transforming growth factor beta 1 modulates electrophysiological parameters of vas deferens epithelial cells Yi, Sheng January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Bruce Schultz / Transforming growth factor β1 (TGF-β1) is a cytokine that reportedly affects the severity of cystic fibrosis lung disease. The goal of this project was to define the effect of TGF-β1 on vas deferens, an organ that is universally affected in male cystic fibrosis patients. In the first study, experiments were conducted using freshly isolated porcine vas deferens epithelial cells. Primary porcine vas deferens epithelial cells exposed to TGF-β1 exhibited a significantly reduced basal transepithelial electrical resistance (Rte). TGF-β1-induced reduction in Rte was prevented by SB431542, a TGF-β receptor I inhibitor, indicating that the effect of TGF-β1 requires the activation of TGF-β receptor I. Western blot and immunohistochemistry results showed the expression of TGF-β receptor I in native vas deferens epithelia, indicating that the impaired barrier function and anion secretion that were observed in cultured vas deferens cells can likely be observed in the native context. Immunohistochemical outcomes showed that TGF-β1 exposure led to loss of organization of tight junction proteins occludin and claudin-7. These outcomes suggest that TGF-β1 impairs the barrier integrity of epithelial cells lining the vas deferens. In a parallel study that employed PVD9902 cells that are derived from porcine vas deferens, TGF-β1 exposure significantly reduced anion secretion stimulated by forskolin, forskolin/IBMX, and 8-pCPT-cAMP, suggesting that TGF-β1 affects downstream targets of the cAMP signaling pathway. Real-time RT-PCR and western blot analysis showed that TGF-β1 exposure reduced both the mRNA and the protein abundance of cystic fibrosis transmembrane conductance regulator (CFTR). Pharmacological studies showed that the inhibitory effect of TGF-β1 on forskolin-stimulated anion secretion was abrogated by SB431542 and attenuated by SB203580, a p38 mitogen-activated protein kinase (MAPK) inhibitor. These outcomes suggest that TGF-β1, via the activation of TGF-β receptor I and p38 MAPK signaling, reduces CFTR expression, and thus impairs CFTR-mediated anion secretion. Outcomes from these studies suggest that, in epithelial cells lining the vas deferens, TGF-β1 exposure leads to an impaired physical barrier and/or reduced anion secretion, which is expected to modify the composition and the maintenance of the luminal environment and thus, is expected to reduce male fertility. TGF Cystic fibrosis Vas deferens epithelia Tight junction Ion transport P38 MAPK Physiology (0719)
343	Regulation of sodium transport across epithelia derived from human mammary gland Wang, Qian January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Bruce D. Schultz / The first aim of this project is to define the cellular mechanisms that account for the low Na[superscript]+ concentration in human milk. MCF10A cells, which were derived from human mammary epithelium and grown on permeable supports, exhibit amiloride- and benzamil-sensitive short circuit current (I[subscript]sc), suggesting activity of the epithelial Na[superscript]+ channel, ENaC. When cultured in the presence of cholera toxin (Ctx), MCF10A cells exhibit greater amiloride sensitive I[subscript]sc at all time points tested, an effect that is not reduced with Ctx washout for 12 hours or by cytosolic pathways inhibitors. Ctx increases the abundance of both beta and gamma-ENaC in the apical membrane and increases its monoubiquitination but without changing total protein and mRNA levels. Additionally, Ctx increases the levels of both the phosphorylated and the nonphosphorylated forms of Nedd4-2, a ubiquitin-protein ligase that regulates ENaC degradation. The results reveal a novel mechanism in human mammary gland epithelia by which Ctx regulates ENaC-mediated Na[superscript]+ transport. The second project aim is to develop a protocol to isolate mammary gland epithelia for subsequent in vitro culture. Caprine (1[superscript]0CME) and bovine mammary epithelia (1[superscript]0BME) were isolated and cultured on permeable supports to study hormone- and neurotransmitter-sensitive ion transport. Both 1[superscript]0CME and 1[superscript]0BME cells were passed for multiple subcultures and all passages formed electrically tight barriers. 1[superscript]0CME were cultured in the presence of hydrocortisone and exhibited high electrical resistance and amiloride-sensitive I[subscript]sc, suggesting the presence of ENaC-mediated Na[superscript]+ transport. 1[superscript]0BME were grown in a complex media in the presence or absence of dexamethasone. In contrast to 1[superscript]0CME, 1[superscript]0BME exhibited no detectable amiloride-sensitive I[subscript]sc in either culture condition. However, 1[superscript]0BME monolayers responded to an adrenergic agonist, norepinephrine, and a cholinergic agonist, carbamylcholine, with rapid increases in I[subscript]sc. Thus, this protocol for isolation and primary cell culture can be used for future studies that focus on mammary epithelial cell regulation and functions. In conclusion, the results from these projects demonstrate that mammary epithelial cells form electrically tight monolayers and can exhibit neurotransmitter- and/or hormone-induced net ion transport. The mechanisms that regulate Na[superscript]+ transport across mammary gland may provide clues to prevent or treat mastitis. Epithelial sodium channel (ENaC) Sodium transport Mamamry epithelia Cholera toxin Short circuit current Isc Physiology (0719)
344	The Mechanisms Underlying Free Fatty Acid-induced Hepatic Insulin Resistance Park, Kyu Yol Edward 01 August 2008 (has links) Elevated circulating free fatty acids (FFA) cause hepatic insulin resistance; however, the mechanisms for this process are incompletely understood. The objective of the studies in the thesis was to examine whether protein kinase C (PKC)-delta (d), oxidative stress, and the serine kinase IkBa kinase (IKK) B are causally involved in FFA-induced hepatic insulin resistance. To test this, we infused rats with lipid with or without inhibitors of the aforementioned factors for 7h, during the last 2h of which a hyperinsulinemic-euglycemic clamp was performed. In Study 1, inhibition of hepatic PKC-d using antisense oligonucleotide prevented FFA-induced membrane translocation of PKC-d, which is a marker of its activation, in parallel with prevention of lipid-induced hepatic insulin resistance, without affecting lipid-induced peripheral insulin resistance. These results implicate PKC-d as a causal mediator of FFA-induced hepatic insulin resistance. In Study 2, the antioxidant N-acetyl-L-cysteine (NAC) prevented lipid-induced hepatic insulin resistance in conjunction with reversal of lipid-induced increase in markers of IKKB and c-Jun NH2-terminal kinase 1 (JNK1) activation, and of impairment of insulin signaling, without affecting PKC-d membrane translocation and increase in phosphorylated p38 mitogen-activated protein kinase (MAPK) induced by lipid infusion. These findings suggested that oxidative stress is a causal mediator of lipid-induced hepatic insulin resistance upstream of IKKB and JNK1, and potentially downstream of PKC-d and p38 MAPK. In Study 3, sodium salicylate, an IKKB inhibitor, prevented FFA-induced hepatic insulin resistance via restoration of hepatic insulin signaling, thus implicating IKKB as a causal factor in the process. Together, the results from these studies demonstrate that PKC-d, oxidative stress, and IKKB are causally involved in FFA-induced hepatic insulin resistance and suggest that the sequence for the process is: FFA -> PKC-d -> oxidative stress -> IKKB -> impaired hepatic insulin signaling. Hepatic Insulin Resistance Diabetes Mellitus Free Fatty Acids Oxidative Stress PKC-Delta Inflammation Obesity 0719
345	The Effect of Insulin and Insulin Resistance on Glucagon-like Peptide-1 Secretion from the Intestinal L Cell Lim, Gareth Eu-Juang 03 March 2010 (has links) Glucagon-like peptide-1 (GLP-1) is secreted from the enteroendocrine L cell following nutrient ingestion. Although GLP-1 regulates several aspects of nutrient homeostasis, one important function is to enhance glucose-dependent insulin secretion. In type 2 diabetes, post-prandial GLP-1 secretion is impaired. Insulin resistance, which is required for the pathogenesis of type 2 diabetes, is also associated with impaired GLP-1 secretion. I, therefore, hypothesized that insulin modulates GLP-1 secretion from the intestinal L cell and, furthermore, insulin resistance directly impairs the function of the endocrine L cell. In well-characterized L cell models, I established that insulin stimulates GLP-1 secretion through the MEK1/2-ERK1/2 pathway, and induction of insulin resistance in vitro attenuated insulin- and heterologous secretagogue-induced GLP-1 release. Furthermore, glucose-stimulated GLP-1 secretion was decreased in hyperinsulinemic-insulin resistant MKR mice, demonstrating that insulin resistance is associated with impaired L cell function. I next examined the role of the actin cytoskeleton in insulin-stimulated GLP-1 secretion. Insulin treatment transiently induced actin depolymerization, and depolymerization of the actin cytoskeleton potentiated insulin-stimulated GLP-1 release from the L cell, demonstrating that the cytoskeleton functions as a permissive barrier. Central to insulin’s effects on actin dynamics is the Rho GTPase, Cdc42, as siRNA-mediated knockdown and over-expression of a dominant-negative mutant, prevented insulin-stimulated actin remodeling and GLP-1 release. Insulin also promoted activation of PAK1, the downstream kinase of Cdc42, and over-expression of a kinase-dead PAK1 mutant attenuated insulin-stimulated GLP-1 release. In cells that expressed dominant-negative Cdc42 or kinase-dead PAK1, activation of ERK1/2 following insulin treatment was attenuated, demonstrating that the Cdc42-PAK1 axis regulates the activity of the canonical ERK1/2 pathway. In summary, this thesis demonstrates, for the first time, that insulin is a GLP-1 secretagogue, and this effect of insulin is mediated through the canonical ERK1/2 pathway and the Cdc42-PAK1 axis. Insulin resistance in the L cell impairs the responsiveness of the L cell to heterologous secretagogues. Collectively, these findings suggest that an alternative approach to treat type 2 diabetes and/or insulin resistance may be to directly improve the function of the L cell, thereby enhancing endogenous GLP-1 release. insulin diabetes insulin resistance glucagon-like peptide-1 actin cytoskeleton intestine 0719
346	Development of Neuronal Responses to Frequency-modulated Tones in Chinchilla Auditory Cortex Brown, Trecia 05 August 2010 (has links) A central issue in auditory research is how the auditory brain encodes complex stimuli. However, the process by which the auditory cortex interprets complex sounds during development and the extent to which cortical organization can be manipulated by complex stimulation is still undetermined. We have addressed this gap in the following three studies. First, we characterized the responses of cortical neurons in adult chinchillas to frequency-modulated (FM) stimulation. Next, we asked whether FM coding at the cortical level is innate or if its development is influenced by normal postnatal environmental experience. Finally, we investigated the effect of sustained neonatal FM sweep exposure on the development of cortical responses to tonal and FM stimuli. In our adult study, results indicated that >90% of sampled neurons were responsive to FM sweeps. The population preference was for upward FM sweeps and for medium to fast speeds ( 0.3 kHz/ms). Three types of temporal response patterns were observed: a single peak at sweep onset/offset (‘onset’) and a single peak (‘late’) or multiple peaks (‘burst’) during the sweep. ‘Late’ units expressed the highest direction and speed selectivity; ‘onset’ units were selective only for direction and ‘burst’ units were selective for neither direction nor speed. In our developmental study, our results showed a significant developmental increase in FM direction selectivity. However, FM speed selectivity appeared to be established early in development. In our developmental plasticity study, we hypothesized that constant FM exposure would increase the proportion of auditory neurons that are selectively responsive to the conditioning FM sweep. However, our results showed that while tonal response latencies increased after the exposure period, the conditioning stimulus had minimal effect on the FM direction preferences of cortical neurons and decreased overall neuronal FM speed selectivity. In conclusion, we suggest that chinchilla auditory cortical neurons are not uniquely activated by FM sounds but that FM responses are largely predictable based on how changing frequency stimuli interact with the receptive fields of these neurons. We also propose that the development of FM direction sensitivity is experience-independent and that perhaps normal acoustic experience is required to maintain FM speed tuning. FM sweeps development direction selectivity acoustic exposure speed selectivity conditioning 0719
347	Mechanisms of High Glucose-induced Decrease in β-cell Function Tang, Christine 23 February 2011 (has links) Chronic hyperglycemia, a hallmark of type 2 diabetes, can decrease β-cell function and mass (β-cell glucotoxicity); however, the mechanisms are incompletely understood. The objective was to examine the mechanisms of β-cell glucotoxicity using in vivo and ex vivo models. The hypothesis is that oxidative stress plays a causal role in high glucose-induced β-cell dysfunction in vivo via pathways that involve endoplasmic reticulum (ER) stress and JNK. The model of β-cell glucotoxicity was achieved by prolonged i.v. glucose infusion (to achieve hyperglycemia). In Study 1, 48h glucose infusion increased total and mitochondrial superoxide levels in islets, and impaired β-cell function in vivo and ex vivo. Co-infusion of the superoxide dismutase mimetic Tempol decreased total and mitochondrial superoxide, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. These results suggest that increased superoxide generation plays a role in β-cell glucotoxicity. In Study 2, 48h glucose infusion increased activation of the unfolded protein response (XBP-1 mRNA splicing and phospho-eIF2α levels). This was partially prevented by Tempol. Co-infusion of the chemical chaperone 4-phenylbutyrate with glucose decreased spliced XBP-1 levels, and prevented high glucose-induced β-cell dysfunction in vivo and ex vivo. Co-infusion of 4-phenylbutyrate also decreased total and mitochondrial superoxide induced by high glucose. These results suggest that 1) ER stress plays a causal role in high glucose-induced β-cell dysfunction, and 2) there is a link between oxidative stress and ER stress in high glucose-induced β-cell dysfunction in vivo. In Study 3, JNK inhibition using the inhibitor SP600125 in rats or JNK-1 null mice prevented high glucose-induced β-cell dysfunction ex vivo and in vivo. SP600125 prevented high-glucose-induced β-cell dysfunction without decreasing total and mitochondrial superoxide levels. Both Tempol and 4-phenylbutyrate prevented JNK activation induced by high glucose. These results suggest a role of JNK activation in high glucose-induced β-cell dysfunction downstream of increased superoxide generation and ER stress in vivo. Together, the results suggest that 1) oxidative stress, ER stress and JNK activation are causally involved in β-cell glucotoxicity, and 2) High glucose-induced oxidative stress and ER stress are linked, and both impair β-cell dysfunction via JNK activation in vivo. Glucotoxicity Oxidative Stress Type 2 Diabetes Endoplasmic Reticulum Stress c-jun N-terminal kinase 0719
348	Matador and the Regulation of cyclin E1 in Normal Human Placental Development and Placental Pathology Ray, Jocelyn 23 February 2011 (has links) Preeclampsia and molar pregnancy are two devastating placental pathologies characterized by an immature proliferative trophoblast phenotype accompanied by excessive cell death. It is therefore of paramount importance to study the regulation of cell fate in the placenta, to gain a further understanding of the mechanisms that contribute to these diseases. In this dissertation we report that during normal placental development and in preeclampsia, Matador (Mtd), a pro-apoptotic member of the Bcl-2 family, has a dual function in regulating trophoblast cell proliferation and death. Importantly, we reveal a novel role of Mtd-L in promoting cyclin E1 expression and cell cycle progression. Of clinical importance, we also identify that both cyclin E1 and the CDK inhibitor p27, are increased in severe early onset preeclampsia. However, the inhibitory function of p27 in this pathology may be hampered due to its increased phosphorylation at Ser10, resulting in its nuclear export. Of equal importance, data presented demonstrate that placentae from severe early onset preeclampsia display a molecular profile distinct from late onset preeclampsia or intrauterine growth restricted pregnancies. In the final data chapter we demonstrate that Mtd is highly expressed in molar tissue, where it localizes to both apoptotic and proliferative cells. Our data suggests that an abundance of Mtd and cyclin E1 in conjunction with the low level of p27 may contribute to the hyperproliferative nature of the disorder. The body of work in this dissertation uncovers novel insights into the regulation of trophoblast cell fate. Importantly, the impact of Mtd on cyclin E1 to promote G1-S transition is a novel mechanism found to regulate trophoblast cell proliferation in normal and pathological placentation. Equally important is our identification of molecular differences between placental pathologies that may help to differentiate early and late onset preeclampsia, IUGR and molar pregnancy. Preeclampsia Molar pregnancy Bcl-2 family members Matador Human Placenta Trophoblast cell cycle cyclin E1 0719
349	Role of Epithelium-specific ETS Transcription Factor-1 in Airway Epithelial Regeneration Oliver, Jordan 26 March 2012 (has links) Human epithelium-specific ETS transcription factor-1 (ESE-1), which is also known as E74-like factor-3 (Elf3) in mice, is strongly expressed in lung during fetal development and in certain lung cancers. The primary goal of the work presented in this thesis was to investigate whether ESE-1 is involved in regeneration of the injured lung epithelium by administering naphthalene to both wild-type (Elf3 +/+) and Elf3-deficient (Elf3 -/-) mice. However, optimal conditions for proper utilization of the naphthalene-induced lung injury model must first be established. Therefore, dose-response studies were initially conducted by administering three different doses of naphthalene to both male and female mice, as described in chapter 2. Although it is shown that the extent of naphthalene-induced Clara cell injury is dose-dependent in both male and female mice, female mice are more sensitive to naphthalene-induced injury than male mice independent of the dose. Furthermore, it is also demonstrated that these gender-dependent differences in naphthalene injury can subsequently influence downstream lung repair kinetics. In light of these findings, lung regeneration was examined in both sexes of both Elf3 +/+ and Elf3 -/- mice. As reported in chapter 3, the kinetics of bronchiolar epithelial cell proliferation and differentiation is delayed considerably in Elf3 -/- mice following naphthalene injury. Moreover, expression of transforming growth factor-beta type II receptor, which is a well-known transcriptional target gene of ESE-1 and is involved in the induction of epithelial cell differentiation, is significantly lower in the bronchiolar airway epithelium of Elf3 -/- mice as compared to Elf3 +/+ mice under steady-state conditions and during repair of naphthalene-induced damage. Collectively, these findings occur to a similar extent in both sexes of both Elf3 +/+ and Elf3 -/- mice, and suggest that ESE-1 plays an important role in regulating the kinetics of airway epithelial regeneration after acute lung injury. ESE-1 ETS transcription factor airway epithelial injury airway epithelial regeneration 0571 0719 0383
350	Innate Immune Transcription Activator Interferon Regulatory Factor-3 (IRF3) Contributes to Maladaptive Remodeling Post-myocardial Infarction de Couto, Geoffrey 19 March 2013 (has links) Cardiovascular disease, and myocardial infarction (MI) in particular, remains a major burden in the developed world today. In fact, the remodeling process, which follows the initial ischemic episode of MI, is a major determinant of heart failure. Although several key mechanistic pathways involving cell growth and death have been identified, there is limited knowledge surrounding the role of the innate immune response as a positive or negative regulator of cardiac remodeling. Recent data strongly support a role for key regulatory components within the toll-like receptor (TLR) family as potent modulators of cardiac remodeling post-MI. It has been demonstrated that targeted gene knockdown of TLR4, as well as downstream adaptor proteins and kinases, significantly improve cardiac function and overall survival. While the well-known NF-κB transcriptional factor that is downstream to TLR4 signaling has been linked to remodeling, there has been no evidence thus far describing a role of the parallel interferon regulatory factor-3 (IRF3) signaling cascade in any facet of this process. Several key findings suggest that IRFs contribute to both cell growth and apoptosis, thus providing an appealing, and novel target for interrogation. In this thesis I describe how IRF3 contributes to maladaptive remodeling post-MI. In my first set of experiments, I demonstrate that IRF3 is acutely upregulated within the cardiomyocyte following MI and that this response contributes to excessive apoptosis post-MI. A targeted deletion of the IRF3 gene enhances cardiac function, decreases infarct size, and improves survival following MI. In the second set of experiments I demonstrate that IRF3 attenuates angiogenesis at the ischemic border zone by upregulating the expression of thrombospondins. I have shown that IRF3 deficiency, which liberates endogenous anti-angiogenic signals, promotes angiogenesis following ischemic injury. These data suggest that IRF3 is a potent regulator of cardiac remodeling and may be an effective therapeutic target to ameliorate maladaptive cardiac repair post-MI. Myocardial Infarction Cardiac Remodeling Interferon Regulatory Factor-3 Innate Immunity 0719

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