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Studies on gender-specific disruption of bone tissue homeostasis by dioxinsWejheden, Carolina, January 2010 (has links)
Diss. (sammanfattning) Stockholm : Karolinska institutet, 2010. / Härtill 4 uppsatser.
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The subfornical organ and vagus nerve : a similar role in hypernatremic thirst demonstrated by hypothalamic fos-immunoreactivity /Starbuck, Elizabeth M. January 2001 (has links)
Thesis (Ph. D.)--University of Washington, 2001. / Vita. Includes bibliographical references (leaves 98-109).
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Endothelial LKB1/AMPK signaling pathway in regulating energy and vascular homeostasisLiang, Yan, 梁艳 January 2013 (has links)
Liver kinase B1 (LKB1), a serine/threonine kinase, is responsible for the activation of AMP-activated protein kinase (AMPK), the master regulator of energy metabolism. LKB1/AMPK signaling pathway possesses a wide range of biological functions in regulating cell cycle progression, cell polarity, senescence and inflammation. In cultured endothelial cells, the pro-senescence function of LKB1/AMPK signaling pathway has been observed. However, the mechanisms by which LKB1 is regulated in endothelial cells remain largely uncharacterized. Furthermore, little is known about the effects of activated endothelial LKB1/AMPK signaling pathway on vascular and energy homeostasis. The present study aimed to investigate the upstream molecular mechanisms regulating LKB1 protein stability during endothelial senescence and the downstream pathophysiological effects of hyperactivated AMPK signaling in endothelial cells.
In cultured model of cellular senescence, the lysine (K) 64 residue of LKB1 was found to be crucial for mediating its pro-senescence activities. The protein stability and intracellular localization of LKB1 mutant with K64 replaced by arginine (R) was different from the wild type protein. K64R exhibited enhanced effects on promoting endothelial senescence. Moreover, mutation of this residue attenuated the binding to HERC2, a newly identified E3 ubiquitin ligase for LKB1, in turn preventing its ubiquitination and degradation.
Using a transgenic mouse model that selectively over-expresses a constitutively active AMPK α1 subunit (EC-AMPK) in endothelial cells, the influence of hyperactivated AMPK signaling on metabolic and vascular functions was investigated. Under standard chow condition, the metabolic phenotypes were similar between wild type and EC-AMPK mice; under high fat diet condition, EC-AMPK mice showed more severe obesity-induced fatty liver injury. Selective activation of AMPK in endothelial cells caused vascular and hepatic inflammation. Cyclooxygenase-2 (COX-2) was found to be the mediator for the pro-inflammatory functions of AMPK in vascular endothelial cells and facilitated to the development of obesity-induced fatty liver injury in EC-AMPK mice. Evaluation using isolated arteries revealed an increased systolic blood pressure and abnormal endothelial function in EC-AMPK miceunder high fat diet. AMPK activation in endothelium of the blood vessel could not block vascular remodeling associated with dietary obesity.
Taken in conjunction, the above findings suggest that continuous activation of LKB1/AMPK signaling elicits adverse effects on both energy and vascular homeostasis. / published_or_final_version / Pharmacology and Pharmacy / Doctoral / Doctor of Philosophy
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Activity-dependent regulation of ion channel gene expression: a homeostatic hypothesis for drug toleranceGhezzi, Alfredo 28 August 2008 (has links)
Not available
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Molecular Mechanisms of Copper Homeostasis in Gram-negative BacteriaGeorge Thompson, Alayna Michelle January 2014 (has links)
Copper is a trace element utilized by organisms as a cofactor involved in redox chemistry, electron transport, photosynthesis, and oxidation reactions. In excess, copper is toxic; it can generate reactive oxygen species causing cellular damage, or poison other metalloproteins by replacing native metal cofactors. Gram-negative bacteria have developed homeostatic mechanisms to maintain the intracellular copper concentration in the face of changing environmental conditions. For Gram-negative enteric bacteria, like Esherichiacoli and Salmonella enterica serovar typhimurium, copper is encountered in industrial and institutional settings, where the metal is used as a broad-spectrum biocide. For environmental bacteria, such as the marine cyanobacterium Synechococcus sp. WH8102, copper stress occurs because human activity changes the concentration of copper in the ocean. This dissertation contains six chapters, relating four stories of our investigations into the molecular mechanisms of copper homeostasis in Gram-negative bacteria. Chapter I contains literature review and background on the implications of bacterial copper homeostasis. Chapter II reports our work investigating the expression of two E. coli proteins, CusF and CusB, upon copper stress; we show that CusF expresses at a ~10-fold molar excess over CusB. Chapter III describes a collaboration between our lab and Jose Argüello's lab at Worcester Polytechnic Institute, and we show that CusF can acquire Cu(I) from CopA. Our results from Chapters II and III show that CusF functions as a major copper chaperone in the periplasm of E. coli. Chapter IV details our work characterizing a novel protein from marine cyanobacteria, Synw_0921. Although Synw_0921 is believed to be involved in copper homeostasis, we show that it is an iron-sulfur cluster protein. Bioinformatic analysis suggests that Synw_0921 represents a new family of proteins that help marine cyanobacteria adapt to copper changes in their unique environment. Chapter V relates our work on CueR and GolS, two homologous sensor proteins with distinct metal-dependent transcriptional activation; we find that the activity cannot be explained by binding affinity differences. Chapter VI concludes with final thoughts on the intersection of biochemistry and molecular biology in the important process of understanding copper homeostasis.
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Structural and Biochemical Studies of the Metal Binding Protein CusF and its Role in Escherichia coli Copper HomeostasisLoftin, Isabell January 2008 (has links)
Biometals such as copper, cobalt and zinc are essential to life. These transition metals are used as cofactors in many enzymes. Nonetheless, these metals cause deleterious effects if their intracellular concentration exceeds the cells' requirement. Prokaryotic organisms usually employ efflux systems to maintain metals in appropriate intracellular concentrations.The Cus system of Escherichia coli plays a crucial part in the copper homeostasis of the organism. This system is a tetrapartite efflux system, which includes an additional component compared to similar efflux systems. This fourth component is a small periplasmic protein, CusF. CusF is essential for full copper resistance, yet its role within the Cus system has not been characterized. It could potentially serve in the role of a metallochaperone or as a regulator to the Cus system.To gain insight into the molecular mechanism of resistance of this system, I have structurally and biochemically characterized CusF. Using X-ray crystallography I determined the CusF structure. CusF displays a novel fold for a copper binding protein. Through multiple sequence alignment and NMR chemical shift experiments, I proposed a metal binding site in CusF, which I confirmed through determination of the structure of CusF-Ag(I). CusF displays a novel coordination of Ag(I) and Cu(I) through a Met2His motif and a cation-pi interaction between the metal ion and a tryptophan sidechain. Furthermore, I have shown that CusF binds Cu(I) and Ag(I) specifically and tightly.I investigated the role of the tryptophan at the binding site to establish its effect on metal binding and function of CusF. I have shown through competitive binding assays, NMR studies and through collaborative EXAFS studies that the tryptophan plays an essential role in CusF metal handling. The affinity of CusF for Cu(I) is influenced by this residue. Moreover, the tryptophan also caps the binding site such that oxidation of the bound metal as well access to adventitious ligands is prevented. In summary, these findings show that the structure and metal site of CusF are unique and are specifically designed to perform the function of CusF as a metallochaperone to the Cus system.
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Analysis and Molecular Characterization of an Unusual Copper Inducible Homeostasis Mechanism in Pseudomonas putida KT2440Quaranta, Davide January 2009 (has links)
The purpose of this research was to identify and characterize novel molecular mechanisms in copper homeostasis. Pseudomonas putida KT2440 is a soil bacterium studied for its potential use in bioremediation of soils contaminated with aromatic organic contaminants. The cinAQ operon was analyzed. cinAQ is transcribed in presence of copper. The product of cinA is a periplasmic azurin-like protein with a methionine and histidine rich region, characterized by a high redox potential (456 ±4 mV). CinQ was shown to be a pyridine nucleotide-dependent nitrile oxidoreductase that catalyzes the reduction of preQ₀ to preQ₁, the first committed step in the biosynthetic pathway leading to the production of the unusual nucleotide queuosine. Gene disruption of cinQ in Pseudomonas putida KT2440 and in Pseudomonas aeruginosa PAO1 did not result in a significant increase in copper sensitivity on disk assays. Furthermore, a P. putida KT2440 cinA mutant also did not present a greater sensitivity to copper on disk assays while cinA mutants in Pseudomonas aeruginosa PAO1 presented increased toxicity to copper compared to the wild-type. CinA is by sequence similarity proposed to be an electron shuttle, and was shown to be upregulated in the presence of copper. Increasing CinA levels in the periplasm after copper stress may represent a mechanism used to regenerate the multicopper oxidase CopA (involved in Cu(I) to Cu(II) oxidation). Alternatively, CinA could act as an electron shuttle that takes part in an alternative electron transport chain once redox active copper is available, or it could represent a periplasmic copper chaperon. CinQ is involved in the biosynthesis of the rare hyper-modified nucleotide queuosine, found in the wobble position of several tRNAs, and required to avoid the readthrough of the stop codon UAG. Transcription of cinAQ was shown to be under the control of the two component system CinR-CinS. CinS is a histidine kinase, with a sensor domain located in the periplasm. CinR is the cognate response regulator that activates transcription of genes upon phosphorylation from CinS. The CinR-CinS two component system was shown to be responsive to 0.5 LM copper. CinS displayed very high metal specificity and elicited a response only in the presence of copper and silver, but not other metals. Modeling of the CinS protein structure, performed using Swiss Model and using the periplasmic sensor DcuS from Escherichia coli as a template, identified a potential copper binding site, containing H37 and H147. Sequence alignment of copper sensing histidine kinases further identified other conserved residues in the periplasmic domain. Site-Directed Mutagenesis was used to generate CinS mutants that were tested for their ability to activate the cinAQ promoter in presence of Cu. When challenged with copper CinS mutant H37R and H147R had an almost 10 fold reduction in copper sensitivity compared to the wild-type, indicating a possible role in Cu coordination. Other CinS mutants responded similarly to the wild-type in the presence of 10 μM of Cu.
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The Estrous Cycle Modulates Contractile Function and Ca2+ Homeostasis In Isolated Mouse Ventricular MyocytesMacDonald, Jennifer 09 July 2012 (has links)
This study investigated the effect of the mouse estrous cycle on myocyte contractile function. Female mice displayed irregular estrous cycles unless induced to cycle though exposure to bedding collected from cages housing male mice. Fractional shortening and Ca2+ transient amplitudes were significantly larger in myocytes isolated from mice in estrus. The effect of the estrous cycle was preserved even when cells were paced at a more physiological frequency and in the presence of ?-adrenergic stimulation. Myofilament Ca2+ sensitivity was also modified by the estrous cycle, as myofilaments isolated from the hearts of mice in estrus were least sensitive to Ca2+. However, acute application of either 17?-estradiol or the G protein-coupled estrogen receptor (GPER) agonist, G-1, had no effect on contractions or Ca2+ transients, regardless of the estrous stage. Thus, physiological fluctuations in sex hormone levels modify myocyte contractions, Ca2+ release, and myofilament Ca2+ sensitivity.
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ADIPONECTIN MODULATES EXCITABILITY OF SUBFORNICAL ORGAN NEURONS AT DIFFERENT ENERGY STATESAlim, Ishraq 01 April 2009 (has links)
Adiponectin (ADP) is an adipokine, which acts as an insulin sensitizing hormone. Recent studies have shown that adiponectin receptors (AdipoR1, AdipoR2) are present in the CNS; however, there is some debate as to whether or not ADP crosses the blood brain barrier (BBB). Circumventricular organs (CVO) are CNS sites outside the BBB, and thus represent sites at which circulating adiponectin may act to influence the CNS without having to cross the BBB. The subfornical organ (SFO) is a CVO that is responsive to a number of different circulating satiety signals including amylin, CCK, and ghrelin. We report here that the SFO also shows a high density of mRNA for both adiponectin receptors. These observations support the concept that the SFO may be a key player in sensing circulating ADP. To test the hypothesis that ADP influences the excitability of SFO neurons, we used current-clamp electrophysiology on dissociated SFO neurons to observe changes in membrane potential. ADP (10 nM) application effected the excitability of SFO neurons, where the cells either depolarized (8.9±0.9 mV, 21 of 97 cells) or hyperpolarized (-8.0±0.5 mV, 34 of 97 cells). Using single-cell RT-PCR we found that the majority of the responsive neurons expressed AdipoR1 or R2 and the non-responsive neurons expressed neither.
In view of the recognized role of ADP in the regulation of energy balance, we next examined the effects of food deprivation for 48 hours on ADP signaling in the SFO. Our previous microarray analysis of SFO showed increases in AdipoR2 mRNA, with no significant change in AdipoR1 mRNA. We have also assessed the effects of such changes in receptor expression on ADP signaling in SFO neurons using calcium imaging and patch clamp techniques. In SFO neurons obtained from control animals, ADP induced increases in intracellular Ca2+ were observed in 25% of cells, while following food deprivation 0% of cells showed this response. Furthermore, 77% of neurons from starved animals showed clear depolarization, while no hyperpolarizing responses were observed. The results presented in this study suggest that adiponectin modulates the excitability of SFO neurons and that the response to ADP changes during starvation. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2008-09-17 18:07:35.099
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THE PHYSIOLOGICAL ACTIONS OF ADIPONECTIN IN CENTRAL AUTONOMIC NUCLEI: IMPLICATIONS FOR THE INTEGRATIVE CONTROL OF ENERGY HOMEOSTASISHOYDA, TED 13 April 2010 (has links)
Adiponectin regulates feeding behavior, energy expenditure and autonomic function through the activation of two receptors present in nuclei throughout the central nervous system, however much remains unknown about the mechanisms mediating these effects. Here I investigate the actions of adiponectin in autonomic centers of the hypothalamus (the paraventricular nucleus) and brainstem (the nucleus of the solitary tract) through examining molecular, electrical, hormonal and physiological consequences of peptidergic signalling.
RT-PCR and in situ hybridization experiments demonstrate the presence of AdipoR1 and AdipoR2 mRNA in the paraventricular nucleus. Investigation of the electrical consequences following receptor activation in the paraventricular nucleus indicates that magnocellular-oxytocin cells are homogeneously inhibited while magnocellular-vasopressin neurons display mixed responses. Single cell RT-PCR analysis shows oxytocin neurons express both receptors while vasopressin neurons express either both receptors or one receptor. Co-expressing oxytocin and vasopressin neurons express neither receptor and are not affected by adiponectin. Median eminence projecting corticotropin releasing hormone neurons, brainstem projecting oxytocin neurons, and thyrotropin releasing hormone neurons are all depolarized by adiponectin. Plasma adrenocorticotropin hormone concentration is increased following intracerebroventricular injections of adiponectin.
I demonstrate that the nucleus of the solitary tract, the primary cardiovascular regulation site of the medulla, expresses mRNA for AdipoR1 and AdipoR2 and mediates adiponectin induced hypotension. Adiponectin has electrical effects on a majority of medial solitary tract neurons and depolarizes those expressing mRNA for the hypotensive neuropeptide Y, revealing a central mechanism to modulate blood pressure.
Finally, I show that adiponectin controls paraventricular nucleus neuron excitability by either inhibiting a tetraethyl ammonium-sensitive potassium current thereby depolarizing neurons or activating a glibenclamide-sensitive voltage independent potassium current hyperpolarizing neurons. Therefore, adiponectin differentially modulates potassium current to confer its central effects.
These results are the first to show the physiological and electrical actions of adiponectin on individual neurons in blood brain barrier protected central autonomic nuclei. This thesis provides a framework for how adiponectin acts centrally to coordinate whole body energy homeostasis and feeding behavior in the rat. / Thesis (Ph.D, Physiology) -- Queen's University, 2009-09-15 16:50:13.933
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