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In vitro and In vivo investigations of tolerance induction and the role of G-protein coupled kainate receptorsHesp, Blair, n/a January 2005 (has links)
The excitotoxin domoic acid (DOM) acts at both kainic acid (KA)- and α-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA)-sensitive glutamate receptors. Clinical reports suggest that elderly people are hypersensitive to the neurological effects of DOM intoxication. Young, but not aged hippocampal slices which have been preconditioned with low concentrations of DOM or KA exhibit an acute �tolerance� to subsequent high doses of DOM or KA; application of the selective AMPA agonist fluorowillardiine (FW) fails to induce tolerance to excitotoxins. The aim of this study was to further investigate the molecular mechanism of tolerance induction in vitro, and to examine the ability of compounds to cross-condition against excitotoxic insult. In addition, in vivo techniques were used to explore the age-related susceptibility to the neurological effects of DOM and acute in vivo tolerance induction. Here we show that low doses of �classical� ionotropic kainate receptor agonists and AMPA/kainate receptor antagonists act as net inverse agonists at G-protein coupled receptors, reducing constitutive GTPase activity by up to 73% in the young hippocampus. Further evidence that inverse agonist activity at G-protein coupled receptors is responsible for acute in vitro tolerance induction by kainate receptor agonists and antagonists was also identified because preconditioning with the AMPA receptor antagonist GYKI-52466 significantly inhibited KA-induced population spike suppression in in vitro hippocampal brain slices from both Sprague-Dawley and Wistar rats. The broad-spectrum protein kinase inhibitor H-7 partially blocked tolerance induction when preconditioning occurs in the presence of suggesting that protein kinases are one of the downstream effectors of this phenomenon. Tolerance-inducing compounds are also capable of cross-conditioning against the effects of other excitotoxins; with 250 nM FW suppressed population spike area by only 62.8 � 10.0% at 30 minutes following a 500 nM KA preconditioning dose, compared to almost complete spike suppression within twenty minutes in naive hippocampal brain slices. In vivo experiments indicated that despite aged animals exhibiting significantly higher cumulative behavioural scores in response to i.p. DOM (1 mg kg⁻�; young = 102 � 9, aged = 179 � 19; P < 0.01) in response to DOM after two hours), and that this age-related supersensitivity is due to impaired renal clearance (young serum DOM = 41.5 � 30.3 ng ml⁻�, aged = 813.3 � 804.4 ng ml⁻� following administration of 1 mg kg⁻� DOM after 2.5 hours earlier). Tolerance to high doses of DOM was induced within a matter of minutes following i.p. preconditioning by low dose DOM in vivo. This was evidenced by severe seizure manifestations being almost absent in both young and aged animals, despite occurring frequently in naive animals. Therefore, this study concludes that tolerance is induced by kainate receptor ligands in vitro and in vivo within a matter of minutes, and is the result of a reduction in the turnover of G-protein coupled receptors and protein kinase activation. In addition, the increased sensitivity of aged rats to in vivo DOM is a result of elevated serum DOM concentrations most likely resulting from impaired renal clearance.
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In vitro and In vivo investigations of tolerance induction and the role of G-protein coupled kainate receptorsHesp, Blair, n/a January 2005 (has links)
The excitotoxin domoic acid (DOM) acts at both kainic acid (KA)- and α-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA)-sensitive glutamate receptors. Clinical reports suggest that elderly people are hypersensitive to the neurological effects of DOM intoxication. Young, but not aged hippocampal slices which have been preconditioned with low concentrations of DOM or KA exhibit an acute �tolerance� to subsequent high doses of DOM or KA; application of the selective AMPA agonist fluorowillardiine (FW) fails to induce tolerance to excitotoxins. The aim of this study was to further investigate the molecular mechanism of tolerance induction in vitro, and to examine the ability of compounds to cross-condition against excitotoxic insult. In addition, in vivo techniques were used to explore the age-related susceptibility to the neurological effects of DOM and acute in vivo tolerance induction. Here we show that low doses of �classical� ionotropic kainate receptor agonists and AMPA/kainate receptor antagonists act as net inverse agonists at G-protein coupled receptors, reducing constitutive GTPase activity by up to 73% in the young hippocampus. Further evidence that inverse agonist activity at G-protein coupled receptors is responsible for acute in vitro tolerance induction by kainate receptor agonists and antagonists was also identified because preconditioning with the AMPA receptor antagonist GYKI-52466 significantly inhibited KA-induced population spike suppression in in vitro hippocampal brain slices from both Sprague-Dawley and Wistar rats. The broad-spectrum protein kinase inhibitor H-7 partially blocked tolerance induction when preconditioning occurs in the presence of suggesting that protein kinases are one of the downstream effectors of this phenomenon. Tolerance-inducing compounds are also capable of cross-conditioning against the effects of other excitotoxins; with 250 nM FW suppressed population spike area by only 62.8 � 10.0% at 30 minutes following a 500 nM KA preconditioning dose, compared to almost complete spike suppression within twenty minutes in naive hippocampal brain slices. In vivo experiments indicated that despite aged animals exhibiting significantly higher cumulative behavioural scores in response to i.p. DOM (1 mg kg⁻�; young = 102 � 9, aged = 179 � 19; P < 0.01) in response to DOM after two hours), and that this age-related supersensitivity is due to impaired renal clearance (young serum DOM = 41.5 � 30.3 ng ml⁻�, aged = 813.3 � 804.4 ng ml⁻� following administration of 1 mg kg⁻� DOM after 2.5 hours earlier). Tolerance to high doses of DOM was induced within a matter of minutes following i.p. preconditioning by low dose DOM in vivo. This was evidenced by severe seizure manifestations being almost absent in both young and aged animals, despite occurring frequently in naive animals. Therefore, this study concludes that tolerance is induced by kainate receptor ligands in vitro and in vivo within a matter of minutes, and is the result of a reduction in the turnover of G-protein coupled receptors and protein kinase activation. In addition, the increased sensitivity of aged rats to in vivo DOM is a result of elevated serum DOM concentrations most likely resulting from impaired renal clearance.
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Domoic acid-induced cardiac damage : an in vitro and in vivo investigationVranyac-Tramoundanas, Alexandra, n/a January 2007 (has links)
Cardiovascular pathology is seen in both animals and humans after domoic acid intoxication. Whether this damage is direct (i.e., cardiotoxic) or indirect (i.e., CNS/autonomic seizures) is not known. We have previously shown that acute in vitro domoic acid (0.05-0.25[mu]M; 10 min) treatment of isolated cardiac mitochondria compromises mitochondrial FADH and NAD⁺-linked respiratory control and mitochondrial energetics. Domoic acid was shown to traverse and bind the cellular membrane of H9c2 cardiac myoblasts. However it did not compromise cellular viability as assessed using cell quantification or lactate dehydrogenase leakage assays. Exposure of intact H9c2 cells to domoic acid only resulted in complex II-III activity impairment and assessment of reactive oxygen species (superoxide and hydrogen peroxide) production in both isolated cardiac mitochondria and H9c2 cardiomyocytes failed to show any significant differences following exposure to domoic acid. Acute ex vivo domoic acid treatment of an isolated myocardium in Langendorff perfusion mode failed to result in cardiac haemodynamic dysfunction, however there appeared to be small but significant decrease in mitochondrial oxygen utilization. The absence of any substantial damage to intact cardiomyocytes and isolated myocardium suggested that domoic acid does not have a direct toxicological effect on cardiac energetics. We therefore investigated the possibility that cardiovascular pathology is an indirect consequence of autonomic seizure activity. Domoic acid was administered intraperitoneally or intrahippocampally and the development of cardiac pathologies was assessed and compared. Sprague-Dawley rats receiving either i.p. or i.h. domoic acid were assessed behaviourally and shown to reach similar levels in their cumulative seizure scores.
Assessment of the cardiac haemodynamics (LVDP, dP/dt, heart rate and coronary flow) revealed a significant time-dependent decrease in function at 1, 3, 7 & 14-days post-i.p. and 7 & 14-days post-i.h. domoic acid administration. Measurement of ventricular mitochondrial oxygen utilization revealed a similar time-dependent decrease in respiratory control, which appeared to be associated with increased proton leakage, shown by an increase in state-4 respiration rate (P<0.01). Assessment of the mitochondrial electron transport chain (complexes I-V) and the mitochondrial marker of integrity, citrate synthase, showed marked time-dependent impairment in both models of domoic acid -induced seizures. Oxidative stress did play a small role in the myocardial damage as indicated by the small decrease in aconitase activity (P<0.05). Plasma IL-1α, IL-1β and TNF-α levels were significantly increased from 3-days post seizures. Haematoxylin & Eosin staining of ventricular sections revealed the formation of contraction bands, inflammation and oedema, confirming a structural pathology. Cardiac damage did not differ between i.p. and i.h. animals, suggesting cardiac damage following domoic acid results from CNS autonomic seizures and resultant sympathetic storm.
This thesis has demonstrated, for the first time, that the cardiac pathology seen following domoic acid exposure is most likely to be a result of CNS activation and resultant seizure episodes, and is not a consequence of the direct interaction between domoic acid and the myocardium. We have also demonstrated for the first time, that seizure episodes result in chronic cardiac dysfunction and a structural pathology which is similar, but not identical to that seen following isoprotenerol administration in vivo.
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Harmful algal blooms on the U.S. west coast : new insights into domoic acid production and identification of yessotoxin, a new marine toxin detected in California coastal waters /Armstrong Howard, Meredith Dana . Armstrong Howard, Meredith Dana. January 2007 (has links)
Thesis (Ph.D.)-University of California, Santa Cruz, 2007. / Includes bibliographical references. Also available online. Restricted to UC campuses.
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Toxic algae and other marine biota: detection, mitigation, prevention and effects on the food industryMcCollough, Bianca January 1900 (has links)
Master of Science / Food Science Institute / Curtis Kastner / Harmful Algal Blooms (HABs) including Cyanobacteria and other toxic marine biota are responsible for similar harmful effects on human health, food safety, ecosystem maintenance, economic losses and liability issues for aquaculture farms as well as the food industry. Detection, monitoring and mitigation are all key factors in decreasing the deleterious effects of these toxic algal blooms. Harmful algal blooms can manifest toxic effects on a number of facets of animal physiology, elicit noxious taste and odor events and cause mass fish as well as animal kills. Such blooms can adversely impact the perception of the efficacy and safety of the food industry, water utilities, the quality of aquaculture and land farming products, as well as cause ripple effects experienced by coastal communities. HABs can adversely impact coastal areas and other areas reliant on local aquatic ecosystems through the loss of revenues experienced by local restaurants, food manufacturers as well as seafood harvesting/processing plants; loss of tourism revenue, decreased property values and a fundamental shift in the lives of those that are reliant upon those industries for their quality of life. This paper discusses Cyanobacteria, macroalgae, HABs, Cyanobacteria toxins, mitigation of HAB populations and their products as well as the ramifications this burgeoning threat to aquatic/ landlocked communities including challenges these toxic algae pose to the field of food science and the economy.
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The Photooxidation of Domoic AcidParekh, Punam K 07 September 2012 (has links)
Domoic acid (DA) is a naturally occurring cyanotoxin, which upon ingestion, is responsible for amnesic shellfish poisoning (ASP) in both humans and animals. Produced by the marine diatom, Pseudonitzschia, DA is accumulated by a number of marine organisms including shellfish, clams and mussels which upon consumption can lead to headaches, nausea and seizures. Possessing a variety of functional groups the structure of DA contains three carboxyl groups, a pyrrole ring and a potent conjugated diene region allowing for binding to glutamate receptors in the dorsal hippocampus of the brain causing the described detrimental effects. Although limitations have been placed regarding the amount of DA that may be contained in seafood no limitations have been placed on the amount present in drinking water. Natural degradation of the toxin may occur through reactive oxygen species such as the hydroxyl radical and singlet oxygen at the conjugated diene region. In this work the photooxidation of DA via singlet oxygen has been studied using sorbic acid as a model compound. The three major reaction pathways observed during the photooxdiation process for both acids include 2 + 4 cycloaddition to produce endoperoxides , 2 + 2 reaction to afford aldehydes and ketones or an ene reaction to generate hydroperoxides. Under similar reaction conditions for SA and DA, the endoperoxide has been seen to be the major product for photoxidation of SA while the hydroperoxide has been seen to be the dominant product during photooxidation of DA.
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Factors that impact Pseudo-nitzschia spp. occurrence, growth, and toxin productionDownes-Tettmar, Naomi January 2013 (has links)
This work investigates, for the first time, the Pseudo-nitzschia (PN) dynamics in the western English Channel (L4) and the environmental factors impacting on domoic acid (DA) production in these waters. This is combined with laboratory studies examining key environmental factors and the multifactorial impact of multiple macronutrient and micronutrient availability on PN growth and DA production. An LC-MS method was established, optimised, and compared with ELISA for the accurate and reproducible extraction and determination of particulate and dissolved DA. The method was used to measure the seasonal variation in DA at L4 during 2009 and this was compared to PN seasonal abundance and diversity. Three groups a P. delicatissima-group, a P. seriata-group, and a P. pungens/multiseries-group were identified and were found to have different ecological distributions with the latter two groups significantly correlating with DA concentration. Macronutrients, in combination with other environmental factors, were found to influence PN populations at L4. Multifactorial laboratory culture experiments investigating the availability of nitrate, phosphate, and silicate, confirmed that the interrelatedness of all these nutrients significantly affected the growth, decline, and DA production of P. multiseries, and highlight the importance of both phosphate and silicate availability for DA production. When the impacts of both macronutrient (phosphate and silicate) and micronutrient (iron and copper) availability were investigated, limited growth and DA production was observed in P. multiseries cultures. Results revealed the complexity and interrelationship of factors affecting both PN growth and DA production. Furthermore, molecular methods were developed to elucidate the PN species present from 2009 Lugol’s-preserved L4 samples. DNA was successfully extracted and amplified from these samples which had been stored for up to 2 years. Initial sequence analysis identified the rbcL DNA marker as an informative site for future work with a number of L4 sequences closely relating to different Pseudo-nitzschia spp.
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Biogeochemical cycling of domoic acid and its isomers in the ocean /Lail, Erin M. January 2006 (has links) (PDF)
Thesis (M.S.)--University of North Carolina at Wilmington, 2006. / Includes bibliographical references (leaves: 36-40)
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Holistic approach to the evaluation of the anthropocentric influence on domoic acid production and the corresponding impact on the California Sea Lion (Zalophus californianus) populationRieseberg, Ashley January 2012 (has links)
Domoic acid (DA) is a neurotoxin produced by the harmful algae Pseudo-nitzschia that has been directly linked to mass stranding events of the California Sea Lion (CSL). The purpose of this paper is to review the anthropogenic influence on the production of this neurotoxin and examine how human activities are impacting this marine mammal species. A comprehensive and interdisciplinary literature review was conducted to evaluate the future sustainability of the CSL population. It was found that while Pseudo-nitzschia bloom developments are vulnerable to anthropogenic influences, the incontestable existence of natural contributing factors adds a certain complexity to the determination of causalities and the development of solutions. Strong evidence exists to show that DA can cause major and irreversible neurological damage in CSLs. Rehabilitation of DA-impacted CSLs is a polarizing issue in the U.S. and presents interesting implications for sustainable development. While the CSL population is currently healthy and plenteous, the strong abundance of future uncertainties warrants concern. A balance must be found between the involving social, economic, and environmental factors to ensure a promising future for the CSL species.
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Behavioral Criteria for the Diagnosis of Domoic Acid Toxicosis in Zalophus californianusWittmaack, Christiana 30 April 2014 (has links)
Introduction
California sea lion (Zalophus californianus) health is severely compromised by domoic acid toxicosis, which occurs in high levels during harmful algal blooms of Pseudonitzschia australis along the coast of California. Current diagnostic protocols are often inconclusive due to a 2-48 hour window of detectability within the urinary, circulatory, and gastric systems (Cook, et al. 2011 and Monte, Pers Comm, 2012). Past studies suggest that Z. californianus, with domoic acid toxicosis, commonly display abnormal behaviors (Goldstein, et al. 2008). However, many of these abnormal behaviors are also associated with other diagnoses and are therefore unreliable as diagnostic indicators. This study fills in a knowledge gap relating to abnormal behavior types and their correlation to domoic acid toxicosis and helps solve the problem of current, inconclusive, diagnostic protocols. In this study, my objectives were to identify abnormal behaviors correlated to domoic acid toxicosis, create a diagnostic ethogram, determine the applicability of the method in the field, and determine the applicability of triage based on the relationship between abnormal behaviors and domoic acid levels.
Methods
I conducted focal animal continuous scans (continuous observation of a single animal at a time, for a set period) with continuous data entry, on animals admitted to the Marine Mammal Center (main study location during 2011-2013) and the Marine Mammal Care Center (comparison location, 2013). I conducted my observations from behind a blind to prevent both human habituation and behavioral influence of the observer. Observations lasted between 10-15 minutes (10 minutes per pen in 2011, 15 minutes per animal in 2012-2013). Subjects were selected based on an admit date no later than 7 days from the observation date.
I conducted focal animal continuous scans at Pier 39, a haul out location, in the San Francisco Bay. Animals included in the study had identifying marks or were isolated from other animals (making them easy to identify). I observed animals once per observation day with a total observation period not exceeding 15 minutes per animal.
I logged domoic acid levels in feces, urine, and serum (collected by veterinary staff and analyzed with liquid chromatography and bioassays for the presence of domoic acid). I then compared these results to the types and severity of abnormal behaviors displayed by the domoic acid toxicosis sample.
Results
Results from data collected at the Marine Mammal Center suggest that head weaving (Wilcoxon, p
Results from the Pier 39 study suggest that behavioral criteria may be applicable for ruling out domoic acid toxicosis in groups of animals. However, I did not test the method during times of harmful algal blooms. Therefore, the applicability of the method for use as a diagnostic tool in the field is unknown and further research is required.
Results for the triage study were inconclusive. The number of animals that tested positive for domoic acid was small and not suitable for statistical analysis. I suggest further research into triage abilities.
Conclusion
Based on the results of these studies, I can conclude that behavioral analysis offers a reliable diagnostic tool for rescued Z. californianus. Practitioners can use behavioral diagnostic criteria with confidence for the diagnosis of domoic acid toxicosis in Z. californianus.
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