Browsing by Subject "Comparative and Evolutionary Physiology"
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Item Age Related Changes in Rabbit Cornea: Permeability and Membrane Properties(1994-12-01) Tai-Lee, Ke; Clark, Abbot F.; Gracy, Robert W.; McConathy, Walter J.Ke, Tai-Lee, Age Related Changes in Rabbit Cornea: Permeability and Membrane Properties. Doctor of Philosophy (Biochemistry), December, 1994, 139 pp., 26 tables, 13 illustrations, bibliography, 117 titles. This investigation was designed to characterize age-related changes in corneal function and biochemical structure. The specific aims were to: 1) systematically assess changes in permeability to compounds of different molecular weights and lipophilicities, 2) examine differences in tissue binding by utilizing a theoretical transport model, and 3) evaluate the biochemical changes in lipid composition and distribution. Experiments to compare young (six weeks) versus old (three to four years) rabbit corneal permeability were carried out utilizing an in vitro diffusion model. Changes in corneal transmembrane resistance, permeability to various compounds, and metabolic capability were examined by various analytical techniques. In addition, a theoretical penetration model which took into account stromal binding was studied. Corneal lipid composition and distribution were assessed by HPLC and GC. in corneal transmembrane resistance, permeability to various compounds, and metabolic capability were examined by various analytical techniques. In addition, a theoretical penetration model which took into account stromal binding was studied. Corneal lipid composition and distribution were assessed by HPLC and GC. Permeabilities of selected compounds with different physicochemical properties were evaluated in young and old intact and denuded (wounded) rabbit corneas. With age, the membrane permeability significantly decreased in parallel with an increase in transmembrane resistance. Age-related changes in activities of esterase and phosphatase were also found. For some compounds, the aged corneas exhibited longer lag times in penetration studies. This suggested that the binding constant in the cornea from older animals was higher than in young animals. Maximum binding capacity from theoretical model calculations correlated well with experimental results in the young corneal stroma but correlation was less rigorous for old corneal stroma. Age-related changes in lipid composition and distribution in corneas were observed and provide indirect evidence for a decrease in membrane fluidity (decrease in the ratio of phosphatidylcholine/sphingomyelin) in the aged cornea. Results indicate that the aging process in the cornea is associated with changes in biochemical structural matrix including membrane lipid composition and physical properties such as fluidity (microviscosity). Functional correlations include changes in: 1) transmembrane resistance, 2) membrane permeability, 3) enzymatic activities (esterase and phosphatase), and 4) binding properties of the cornea. A possible mechanism for understanding and developing an intervention for age-related changes in the cornea is postulated.Item Carotid Baroreflex of Leg Vasculature(2004-07-01) Keller, David Melvin; Peter A. Raven; H. Fred Downey; Patricia A. GwirtzKeller, David Melvin, Carotid Baroreflex Control of Leg Vasculature. Doctor of Philosophy (Biomedical Science), July 2004; 110 pp; 5 tables; 10 figures; bibliography. The carotid baroreflex (CBR) exerts control of arterial blood pressure primarily as a result of changes in total vascular conductance. In humans, understanding CBR control of the vasculature supplying a given vascular bed, such as the leg, remains unclear. Furthermore, it appears that metabolic attenuation of sympathetic vasoconstriction may modulate the CBR of the vasculature supplying contracting skeletal muscle during exercise. However, the balance between baroreflex-mediated vasoconstriction and the mechanisms responsible for the metabolic attenuation has not been fully elucidated. Therefore, the purpose of the investigations within this dissertation was to: i) explain CBR control of leg vascular conductance (LVC) and the relationship between changes in LVC and muscle sympathetic nerve activity at rest and during one-legged knee extension exercise, ii) examine the CBR control of the vasculature supplying an exercising leg and a non-exercising leg during exercise, and iii) demonstrate the role of the ATP-sensitive potassium channel in contributing to the metabolic attenuation of CBR-mediated vasoconstriction in the vasculature supplying contracting skeletal muscle. In the first investigation, we demonstrated: i) the stimulus response relationships for CBR control of LVC and MSNA at rest and during two intensities of one-legged knee extension exercise; ii) that CBR control of LVC was preserved during exercise; iii) that the attenuation of CBR-mediated vasoconstriction was no different between 7W and 25W exercise in the vasculature supplying an exercising leg; and iv) that the contribution of changes in LVC to CBR changes in mean arterial pressure was no different from rest to exercise in both the exercising leg and the non-exercising leg. In the second investigation, we examined the role of the ATP-sensitive potassium channel in modulating sympathetically-mediated vasoconstriction at rest and during exercise in the vasculature supplying an exercising leg and a non-exercising leg. The attenuated vasoconstrictor response to the carotid baroreceptor stimulated hypotension observed in the vasculature supplying an exercising leg was partially restored two to four hours after the oral ingestion of glyburide (5mg). This finding indicates that ATP-sensitive potassium channel activation plays a primary role in the effects of functional sympatholysis during leg exercise in humans. We further demonstrated that CBR control of MAP was not altered by oral glyburide administration in healthy subjects.Item Endothelin-1 Mediated Regulation of Extracellular Matrix Collagens- A Role in Pathology of Primary Open Angle Glaucoma(2007-11-01) Rao, Vidhya Ramachandiran; Thomas Yoroi; Neeraj Agarwal; Raghu KrishnamoorthyEndothelin -1 Mediated Regulation of Extracellular Matrix Collagens –A role in Pathology of Primary Open Angle Glaucoma. Vidhya R. Rao, Doctor of Philosophy. (Pharmacology and Neuroscience), November, 2007, 157 pp., 3 tables, 18 figures. Summary. Primary Open Angle Glaucoma (POAG) is a progressive optic neuropathy characterized by loss of retinal ganglion cells, optic nerve degeneration and characteristic extracellular matrix (ECM) remodeling of the optic nerve head. An increase in collagen type I and VI is observed at the level of lamina cribosa (LC), a distinct connective tissue region of optic nerve in POAG subjects. Extensive ECM remodeling with enhanced collagen deposition observed in POAG is consistent with the pathology of fibrosis. Mechanisms contributing to ECM remodeling in POAG is not known. Endothelin-1(ET-1), a potent vaso-active peptide plays a key role in glaucoma pathology. Intra-vitreal administration of ET-1 in animal models results in optic neuropathy, RGC apoptosis, axonal transport block and ONA activation. An upregulation of ET-1 and ETB receptors is observed in glaucomatous LC and animal models of glaucoma and ET-1 mediated detrimental effects in POAG appears to be mediated by ETB receptors. ET-1 initiatives and maintains enhanced collagen synthesis and deposition in various tissues under pathological conditions and is recognized as a potent profibrotic factor. In the present study we hypothesized that ET-1 increases extracellular matrix collagen deposition in lamina cribrosa and this change in ECM contributes to optic nerve fibrosis. We have demonstrated that cells of lamina cribrose (LC) cells, express functional ETA and ETB receptors. ET-1 increases intracellular calcium mobilization via ETA receptors and increases NO release by mechanisms involving both ETA and ETB receptors. Consistent with POAG pathology we have observed an upregulation ETB receptors in LC cells in response to chronic treatment with ET-1. LC cells also express prepro-ET-1, the primary gene transcript of ET-1. We have demonstrated for the first time that ET-1 exerts its profibrotic effects by enhancing collagen type I and type VI mRNA, protein synthesis, deposition and secretion in LC cells. ET-1 enhanced collagen deposition in LC cells appears to involve both ETA and ETB receptors, as both of the receptor antagonist, individually inhibit ET-1 mediated collagen synthesis. We have demonstrated that ET-1 also exerts its profibrotic effects in vivo by enhancing collagen deposition in rat optic nerve head. We have also observed an apparent decrease in ET-1 mediated collagen VI deposition in optic nerve heads of ETB deficient transgenic rats suggesting that ET-1 mediated collagen VI synthesis involves ETB receptor activation. In conclusion, endothlein-1 stimulates collagen synthesis and deposition both in vitro in LC cells as well as in vivo at the level of rat optic nerve head. ET-1 mediated increase in collage synthesis at the level of optic nerve head could render a fibrotic mechanism that contributes to the progression of POAG.Item Estrogen Signaling Protects Mitochondrial Membrane Potential Integrity from Oxidative Stress in Lens Epithelial Cells(2008-05-01) Flynn, James Martin; Cammarata, Patrick R.; Wordinger, Robert J.; Dimitrijevich, S. DanFlynn, James Martin, Estrogen Signaling Protects Mitochondrial Membrane Potential Integrity from Oxidative Stress in Lens Epithelial Cells. Doctor of Philosophy, (Cell Biology and Genetics) May, 2008, 265 pages, 36 figures, bibliography, 190 titles. Loss of mitochondrial membrane potential has been determined to be one of the initiating factors in activation of apoptosis after cellular damage. Estrogen and estrogen analogues have been shown to enhance cell survival in numerous tissues through rapid pro-survival cell signaling. This study was focused on elucidating mechanisms through which estrogen protects the cells by preventing the activation of mitochondrial permeability transition pores and the subsequent loss of mitochondrial membrane potential. It is hypothesized that the anti-apoptotic mitochondrial protein BAD, once phosphorylated by estrogen activated upstream kinases, can prevent the formation of the permeability transition pre via direct interaction. To address this, lens epithelial cells were used as a model system for the examination of mitochondrial depolarization during periods of either oxidative or hyperglycemic stress. Estrogen attenuated the loss of impermeability of the mitochondrial membrane, thus maintaining the cells during acute periods of stress. It was discovered that a number of the estrogen receptor isoforms are expressed in lens epithelium, and that the wild-type estrogen receptor-β1 isoform is localized to the mitochondria in lens epithelial cultures derived from both human males and females. siRNA treatment against estrogen receptor-β determined that is a required component to elicit estrogen’s protective abilities against oxidative stress induced mitochondrial depolarization. Furthermore, administration of exogenous estrogen rapidly activated signaling pathways, particularly ERK, which were shown to have influence over the loss of mitochondrial membrane potential. Studies using both pharmacological inhibitors of MAPK signaling, as well as siRNA of ERK2 kinase demonstrate a correlation between the activation of ERK and the severity of response to oxidative stress. Investigation of downstream substrates of ERK revealed that the mitochondrial protein BAD is phosphorylated after the administration of estrogen, yet it is not required for the prevention of mitochondrial depolarization as originally hypothesized. In conclusion, these studies have confirmed a mitochondrial targeted mechanism activated by estrogen which is rapid, gender independent, estrogen receptor-β mediated signal transduction pathway. The targeting of mitochondrial function to reduce oxidative or hyperglycemic stress, thereby preventing activation of the permeability transition pore, defines a novel concept which will contribute to innovative regimens for prevention or treatment of mitochondrial pathology.Item Regulation of Myocardial Blood Flow and Function During Exercise in Dogs(1995-06-01) Kim, Song-Jung; Patricia A. Gwirtz; Peter B. Raven; James L. CaffreyIntroduction. Background. Coronary circulation during exercise. Coronary blood flow is regulated primarily by local metabolic mechanisms according to the oxygen and nutrient needs of the heart (2, 4, 19). The local “metabolic signal” involves vasoactive metabolites, such as adenosine, released from myocytes in direct proportion to myocardial work (Figure 1). However, other external factors are superimposed on local regulatory mechanisms and can substantially modulate coronary blood flow. One of these modulatory factors is the sympathetic nervous system. Sympathetic vasoconstriction mediated by α-adrenergic receptors in the coronary circulation has been shown to oppose metabolic vasodilation and limit oxygen supply to the myocardium during physiologic and pathophysiological cardiac stresses, such as exercise and myocardial hypoperfusion (1, 6, 7, 8, 10-14, 17, 18, 21). This limitation on myocardial oxygenation appears to impose a restriction on the increase in regional left ventricular subendocardial contractile function during submaximal exercise (7). In this regard, studies have shown that removing this α1-constrictor tone leads to an increase in coronary blood flow and, as a result, regional contractile function (8). This adrenergic coronary constriction during exercise is mediated by neutrally released norepinephrine, not by circulating catecholamines (8). Endothelial-mediated control of coronary vascular tone. Recent investigations indicate that another factor involved in modulating coronary blood flow is the vascular endothelium. The endothelium exerts an influence on vascular smooth muscle vasomotor tone by releasing an endothelium-derived relaxing factor (EDRF) or nitric oxide (NO), which is derived from the amino acid L-arginine by nitric oxide synthase (5, 22). Synthesized NO diffuses into the underlying vascular smooth muscle to activate cytosolic guanylate cyclase (GC), thereby stimulating the intracellular accumulation of cyclic GMP (cGMP). This is illustrated in Figure 2. NO is released by the stimulation of muscarinic receptors on endothelial cells by acetylcholine, as well as by other agonists or physical stimuli (e.g., shear stress) at the interface between blood and endothelial cell surface (15). During exercise, for example, the work output of the normal heart may increase several-fold by the stimulation of sympathetic nerves to heart. The increased work output of the heart increases myocardial oxygen demand. Consequently, the coronary circulation undergoes vasodilation due to local metabolic mechanisms. The elevation in shear stress caused by increases in coronary blood flow triggers release of NO from the endothelium because of the extremely pulsatile nature of the flow. Therefore, it is likely that during exercise, release of NO by shear stress and by neurohormonal stimuli, concomitant with local release of metabolites, contributes to coronary dilation. These vasodilatory influences counteract a sympathetic α-adrenergic coronary constriction, which limits the increase in coronary blood flow and cardiac performance. Accordingly, coronary vascular smooth muscle tone during exercise is modulated by the endothelium, which responds to the increased shear stress and adrenergic stimulation, which provides the major extrinsic input.