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Auswirkung eines Knockouts des Protein-Phosphatase-Inhibitor-1 auf den Verlauf der druckinduzierten Herzinsuffizienz in MäusenHartmann, Knut 18 April 2017 (has links)
Aims
Protein Phosphatase Inhibitor 1 (I-1) functions as an amplifier of the β-adrenergic cascade in cardiomyocytes. Once activated via PKA, I-1 specifically blocks PP-1-mediated dephosphorylation of phospholamban and the ryanodine receptor-1. In heart failure I-1 activity as well as its expression is significantly reduced. It is still unclear whether this adaptation is protective or detrimental. This work aims at examining the impact of I-1 depletion on the course of pressure-induced heart failure, more precisely on acute and long-term mortality, on cardiac morphology and function and on expression levels of hypertrophy markers. Results may help evaluating the benefit of putative I-1 inhibiting substances in the therapy of heart failure.
Methods and Results
25 I-1KO and 28 WT mice (C57Bl/6J, age- and sex-matched) underwent transverse aortic constriction (TAC). Cardiac function was assessed via transthoracic echocardiography prior to the intervention and weekly afterwards. Additionally, mice were exposed to β-adrenergic stimulation by injection of dobutamine once prior to TAC and two times afterwards, each controlled by echocardiography. For male mice acute survival was significantly increased in WT compared to I-1KO, whereas the mortality of surviving animals did not differ during the investigation period. For female mice no difference was seen in acute mortality after TAC, but during heart failure progression I-1KO revealed a significantly better survival. Prior to TAC contractility in I-1KO after application of dobutamine was significantly lower than in WT. This effect was mainly induced by female mice. Overall female mice of both WT and I-1KO showed smaller increases in heart rate (HR) and stroke volume (SV) when stimulated. In contrast, following TAC neither line- nor sex-dependent differences were found according to β-adrenergic stimulation. The comparison of hypertrophy markers in control groups revealed clearly decreased levels for I-1KO compared to WT.
Conclusion
In pressure-induced heart failure, I-1 knockout alters cardiac contractility and modulates mortality in a phase- and sex-dependent way. The depletion is detrimental for male mice in the acute phase of cardiac stress, whereas it is protective for female mice during heart failure progression. The increased mortality in the acute phase might result from the loss of I-1 as an amplifier of β-adrenergic signaling as this leads to a restriction of contractile adaptation. The increased survival in heart failure progression might be caused by a reduced transmission of pathologically increased sympathetic activity on the SR due to the depletion of I-1. Additionally, hypertrophy marker analyses point to differences in expression levels even under non-pathological conditions. / Ziel
Der Proteinphosphatase-Inhibitor I-1 wirkt als ein Verstärker der β-adrenergen Kaskade in Kardiomyozyten. Nach PKA-abhängiger Phosphorylierung hemmt er spezifisch die Dephosphorylierung von PLB und RYR-2 durch die Proteinphosphatase-1. Im Rahmen einer Herzinsuffizienz sind sowohl Aktivität als auch Expression von I-1 deutlich reduziert. Hierbei ist unklar, ob dies eine protektive oder eine schädliche Adaption der β-adrenergen Kaskade darstellt. Diese Arbeit untersucht den Einfluss einer Depletion des I-1 (I-1KO) im Rahmen der druckinduzierten Herzinsuffizienz auf die akute bzw. auf die langfristige Mortalität, auf die kardiale Morphologie und Funktion sowie auf die Expression typischer Hypertrophiemarker. Hieraus sollen Erkenntnisse über den Nutzen der Verwendung putativ I-1 inhibierender Substanzen in der Behandlung der Herzinsuffizienz gewonnen werden.
Methoden und Resultate
25 I-1KO- sowie 28 WT-Mäuse (C57Bl/6J, age and sex matched) erhielten eine Transverse Aortic Constriction (TAC). Die kardiale Funktion wurde einmalig vor der Intervention sowie danach wöchentlich mittels TTE untersucht. Zusätzlich wurden die Tiere einmalig vor TAC und zweimalig danach unter echokardiographischer Kontrolle mittels Dobutamin β-adrenerg stimuliert. Für die männlichen Tiere zeigte sich in den ersten Tagen nach TAC eine signifikant erhöhte Überlebensrate des WT gegenüber I-1KO. Die Mortalität der überlebenden männlichen Tiere unterschied sich hingegen nicht über den Versuchszeitraum. Für die weiblichen Tiere bestand kein Unterschied in der akuten Sterblichkeit nach TAC, während sich im Verlauf eine signifikant bessere Überlebensrate der weiblichen I-1KO gegenüber WT zeigte. Vor TAC wurde eine signifikant herabgesetzte Kontraktilität (FAS) des I-1KO unter Dobutamin festgestellt, der im Wesentlichen durch die weiblichen Tiere bewirkt wird. Insgesamt zeigten die weiblichen Tiere beider Linien unter β-adrenerger Stimulation eine geringere Zunahme von Herzfrequenz (HR) und Schlagvolumen (SV). Hingegen waren nach TAC keine linien- oder geschlechtsabhängigen Unterschiede unter Dobutamingabe feststellbar. Ein Vergleich der Hypertrophiemarker in der Kontrollgruppe zeigte für I-1KO ein deutlich vermindertes Niveau der Marker gegenüber WT.
Ergebnis
Der I-1-Knockout verändert die kardiale Kontraktilität und wirkt sowohl in phasen- als auch in geschlechtsabhängiger Weise auf die Mortalität infolge druckinduzierter Herzinsuffizienz. Er ist nachteilig für männliche Tiere in der akuten Phase kardialer Belastung, während er für weibliche Tiere im weiteren Verlauf protektive Wirkung entfaltet. Eine erhöhte Mortalität in der akuten Phase kann durch den Ausfall der Verstärkerfunktion des I-1 erklärt werden, da hiermit eine Einschränkung der akut notwendigen kontraktilen Adaptionsfähigkeit einhergeht. Ein Überlebensvorteil bei chronischer kardialer Belastung könnte darauf zurückzuführen sein, dass die pathologisch erhöhte sympathische Aktivierung der β-adrenergen Kaskade infolge der I-1-Depletion eine geringere Auswirkung auf die Zielstrukturen des aktivierten I-1 am Sarkoplasmatischen Retikulum hat. Darüber hinaus lassen die Analysen der Hypertrophiemarker eine veränderte Genexpression zwischen I-1KO und WT auch unter nicht-pathologischen Bedingungen vermuten.
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Protein Phosphatase 4 ist ein neuer Regulator der circadianen Uhr in SäugernKlemz, Sabrina 11 September 2014 (has links)
Circadiane Uhren sind endogene Oszillatoren, die tägliche Rhythmen in Physiologie, Metabolismus und Verhalten steuern. Auf molekularem Level wird die Dynamik der circadianen Oszillation über ein genregulatorisches Netzwerk aus transkriptionellen-translationalen Rückkopplungsschleifen gesteuert. Posttranslationale Modifikationen von Uhrproteinen sind für eine präzise Justierung der circadianen Periode essentiell. Dabei spielt die Phosphorylierung von Uhrproteinen für die Regulation von Aktivität, Stabilität und intrazellulärer Lokalisation eine wichtige Rolle. Bisher sind verschiedene Kinasen als Modulatoren der circadianen Uhr charakterisiert worden, jedoch ist eine funktionale Rolle von Protein Phosphatasen bisher nur unzureichend untersucht. In dieser Arbeit wurde mittels eines RNAi-basierten Screenings in oszillierenden humanen Zellen untersucht, ob sich die gezielte Depletion katalytischer Untereinheiten der Serin/Threonin-Phosphatasen auf die normale Oszillationsdynamik auswirkt und welche Rolle ausgewählte Phosphatase-Kandidaten für die posttranslationale Kontrolle des molekularen Oszillators spielen. Die RNAi vermittelte Depletion von Protein Phosphatase 4 führte gewebe- und speziesübergreifend zu einer signifikant kurzen circadianen Periode, während die Überexpression von wildtypischer Pp4c in einer stark reprimierten Amplitude resultierte. Mechanistische Untersuchungen zur funktionellen Relevanz von PP4c für die Regulation der circadianen Uhr zeigten, dass PP4c womöglich eine duale Rolle spielt: Einerseits ist PP4c in die direkte Aktivierung des Bmal1-Promotors über RRE-Elemente involviert. Anderseits wirkt PP4c inhibierend auf die CLOCK/BMAL1-vermittelte, E-Box getriebene Genexpression. Ein favorisiertes Modell fundiert auf der Vermutung, dass eine durch PP4c induzierte Modulation des Phosphorylierungsstatus von BMAL1 zu einem stabilen, aber transktiptionsinaktiven BMAL1 und damit zu einer verstärkten Repression der Uhrgentranskription führt. / Circadian clocks are endogenous oscillators that drive daily rhythms in physiology, metabolism and behavior. On the molecular level the dynamics of circadian oscillations are regulated by a transcriptional-translational gene-regulatory network. Posttranslational modifications of clock proteins are essential for the precise timing of an about 24 hour-period. Among these modifications, protein phosphorylation plays an important role in regulating activity, stability and intracellular localization of clock proteins. Several kinases were characterized as regulators of the circadian clock. However, the function of protein phosphatases, which balance phosphorylation events, in the mammalian clock mechanism is less well understood. By using a systematic RNAi-based approach in oscillating human cells, this work aimed to study the impact of catalytic subunits of Serine/Threonin-phosphatases on normal circadian dynamics and the functional role of potential candidates in the posttranslational control of the mammalian molecular oscillator. This study demonstrates, that genetic depletion of the catalytic subunit of protein phosphatase 4 results independently from tissue and species in a significant shorter period, whereas overexpression of wildtype PP4c results in a severely reduced amplitude rhythm. Mechanistic experiments to uncover the functional relevance of PP4c in the regulation of the circadian clock showed, that PP4c plays a dual role: Firstly, PP4 is involved in the direct activation of the Bmal1-promotor via RRE elements. Secondly, PP4c is inhibiting the CLOCK/BMAL1-mediated gene expression. A favored model is based on the assumption, that PP4c-induced modulation of the phosphorylation status of BMAL1 leads to a more stable and transcriptional inactive protein and thereby to a repression of the transcription of clock genes.
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Regulation of Mitotic Spindle Assembly in Caenorhabditis elegans Embryos / Regulation der Bildung der mitotischen Spindel in Caenorhabditis elegans embryosSchlaitz, Anne-Lore 10 June 2007 (has links) (PDF)
The mitotic spindle is a bipolar microtubule-based structure that mediates proper cell division by segregating the genetic material and by positioning the cytokinesis cleavage plane. Spindle assembly is a complex process, involving the modulation of microtubule dynamics, microtubule focusing at spindle poles and the formation of stable microtubule attachments to chromosomes. The cellular events leading to spindle formation are highly regulated, and mitotic kinases have been implicated in many aspects of this process. However, little is known about their counteracting phosphatases. A screen for genes required for early embryonic cell divisions in C. elegans identified rsa-1 (for regulator of spindle assembly 1), a putative Protein Phosphatase 2A (PP2A) regulatory subunit whose silencing causes defects in spindle formation. Upon rsa-1(RNAi), spindle poles collapse onto each other and microtubule amounts are strongly reduced. My thesis work demonstrates that RSA-1 indeed functions as a PP2A regulatory subunit. RSA-1 associates with the PP2A enzyme and recruits it to centrosomes. The centrosome binding of PP2A furthermore requires the new protein RSA-2 as well as the core centrosomal protein SPD-5 and is based on a hierarchical protein-protein interaction pathway. When PP2A is lacking at centrosomes after rsa-1(RNAi), the centrosomal amounts of two critical mitotic effectors, the microtubule destabilizer KLP-7 and the kinetochore microtubule stabilizer TPXL-1, are altered. KLP-7 is increased, which may account for the reduction of microtubule outgrowth from centrosomes in rsa-1(RNAi) embryos. TPXL-1 is lost from centrosomes, which may explain why spindle poles collapse in the absence of RSA-1. TPXL-1 physically associates with RSA-1 and RSA-2, suggesting that it is a direct target of PP2A. In summary, this work defines the role of a novel PP2A complex in mitotic spindle assembly and suggests a model for how different microtubule re-organization steps might be coordinated during spindle formation.
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Cdc55 controls the balance of phosphatases to coordinate spindle assembly and chromosome disjunction during budding yeast meiosisBizzari, Farid Fouad Mahmoud January 2012 (has links)
Meiosis is the process by which haploid gametes are produced from a diploid cell. It is a specialised form of cell division which involves one round of DNA replication followed by two rounds of chromosome segregation. Errors in the segregation process can give rise to aneuploidy, which can result in miscarriages and birth defects. In the first meiotic division homologous chromosomes are segregated, and sister chromatids are segregated in the second division. This is coordinated with two rounds of spindle microtubule assembly and disassembly. How these two processes are coordinated is unknown. In my PhD, I study the role of the protein phosphatase 2A (PP2A) regulatory subunit, Cdc55, in budding yeast meiosis. PP2A is a conserved heterotrimeric enzyme that has important roles in mitosis and meiosis. These roles are dictated by binding to either of its two regulatory subunits, Rts1 and Cdc55, in budding yeast . I show that Cdc55 is required for the proper assembly of a meiotic spindle in meiosis I, through the maintenance of the Cdc14 phosphatase in the nucleolus early in meiosis. In addition, Cdc55 is also required to limit the formation of PP2A complexes with the Rts1 regulatory subunit, and this is essential for the timely dissolution of sister chromatid cohesion. Thus, Cdc55 couples spindle assembly with chromosome segregation through its interactions with Cdc14 and PP2ARts1. Finally, I show some preliminary studies looking at the possible downstream effectors of Cdc14 that are important in this mechanism.
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Regulation of the Target of Rapamycin Signaling Pathway in Saccharomyces cerevisiaePracheil, Tammy 17 May 2013 (has links)
An integrative, biochemical, genetic, and molecular biology approach utilizing gene manipulation, gene knock outs, plasmid based protein expression, and in vivo protein localization of fluorescence tagged proteins was employed to determine the function of an essential protein, Lst8, in TORC1 and TORC2 signaling and a previously uncharacterized complex, the Far3-7-8-9-10-11 complex (Far complex) in the budding yeast, Saccharomyces cerevisiae. Mutations in SAC7 and FAR11 suppressed lethality of both lst8 and tor2-21 mutations but not TORC1 inactivation, suggesting that the essential function of Lst8 is linked only to TORC2.
Far11, a component of a six-member complex, was found to interact with Tpd3 and Pph21, conserved components of Protein Phosphatase 2A (PP2A) via co-immunoprecipitation. Mutations in FAR11 and RTS1, which encodes a PP2A regulatory B subunit, restore phosphorylation to the TORC2 substrate Slm1 in a tor2-21 mutant. These data suggest that TORC2 signaling is antagonized by Far11-dependent PP2A activity.
To characterize the assembly of the Far complex in vivo, intracellular localization of the Far complex was examined by fluorescence microscopy. It was found that the Far complex localizes to the endoplasmic reticulum (ER). The data show that Far9 and Far10 are tail-anchored proteins that localize to the ER first and recruit a Far8-Far7-Far3 pre-complex. Far11 is found at the ER only when all other Far proteins are assembled at the ER. Surprisingly, ER localization is required for the Far Complex’s role TORC2 signaling because deletion of the tail-anchor domain of Far9 results in partial bypass of the tor2-21 mutant growth defect at 37 ˚C.
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Die Rolle des Protein-Phosphatase-1-Inhibitor-1 in der β-adrenergen Signalkaskade kardialer Fibroblasten / The role of protein phosphatase inhibitor-1 in β-adrenergic signaling in cardiac fibroblastsEwens, Sebastian 04 April 2019 (has links)
No description available.
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A importância da proteína fosfatase sitA na adesão, integridade da parede celular, biofilme e virulência de Aspergillus fumigatus / The Aspergillus fumigatus sitA phosphatase homologue is important for adhesion, cell wall integrity, biofilm formation, and virulenceBom, Vinícius Leite Pedro 12 February 2016 (has links)
Aspergillus fumigatus é um fungo patogênico oportunista capaz de infectar pacientes imunocomprometidos causando eventualmente infecções disseminadas difíceis de serem controladas e com alta taxa de mortalidade dos indivíduos infectados.. Para um melhor entendimento de como esse fungo age no hospedeiro é importante saber como as vias de sinalização que regulam esses fatores de virulência são orquestradas. Proteínas fosfatases são centrais em uma grande variedade de vias de transdução de sinal. Neste trabalho, nós caracterizamos a proteína fosfatase 2A SitA, a proteína homóloga de Sit4 em Saccharomyces serevisiae. O gene sitA não é essencial e por isso fomos capazes de construir um mutante nulo em A. fumigatus. A cepa ?sitA apresenta aumento na fosforilação da MpkA, é mais sensível à agentes que causam dano na parede celular, tem um aumento na quantidade de ?-1,3 glicano e quitina, e também tem problemas na adesão e formação de biofilme. O mutante ?sitA é mais sensível a vários metais e íons, como MnCl2, CaCl2, LiCl, entretanto é mais resistente à ZnSO4. O mutante ?sitA é avirulento em modelo de aspergilose pulmonar invasiva em camundongos. Esses resultados revelam que a fosfatase SitA está envolvida na via de integridade da parede celular de A. fumigatus possivelmente modulando a atividade de PkcA/MpkA / Aspergillus fumigatus is an opportunistic pathogenic fungus able to infect immunocompromised patients causing eventually disseminated infections that are difficult to be controlled, and lead to high mortality rates. It is important to understand how are orchestrated the signalling pathways that regulate these factors involved in virulence. Protein phosphatases are central to numerous signal transduction pathways. Here we characterize A. fumigatus protein phosphatase 2A SitA, the S. cerevisiae Sit4p homologue. The sitA gene is not an essential gene and we were able to construct an A. fumigatus null mutant. The ?sitA strain had increased MpkA phosphorylation, was more sensitive to cell wall damaging agents, had increased ??1,3?glican and chitin, and was impaired in biofilm formation. The ?sitA strain is more sensitive to several metals and ions such as MnCl2, CaCl2, and LiCl, however, it is more resistant to ZnSO4. The ?sitA strain was avirulent in a murine model of invasive pulmonary aspergillosis. These results stress the importance of A. fumigatus SitA as a possible modulator of PkcA/MpkA activity and its involvement in the cell wall integrity pathway
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Role of pp2a/bβ2 and pka/akap1 in brain development and function via dynamin-related protein 1 (drp1) control of mitochondria shape and bioenergeticsDickey, Audrey Sarah 01 December 2010 (has links)
Mitochondria are critical for energy production and Ca2+ homeostasis and undergo fission and fusion reactions, perturbation of which can contribute to neuronal injury and disease. Mitochondrial fission is catalyzed by Drp1 (dynamin-related protein 1), a large GTPase tightly controlled by various posttranslational modifications, including phosphorylation. Bβ2 is a neuron-specific postnatally induced protein phosphatase 2A (PP2A) regulatory subunit that mediates PP2A translocation to the outer mitochondrial membrane (OMM) to promote mitochondrial fragmentation and sensitize neurons to various injuries. Opposing PP2A/Bβ2's effect on mitochondrial morphology and cell death is protein kinase A (PKA) anchored to the OMM via A kinase anchoring protein 1 (AKAP1). This dissertation describes how reversible phosphorylation of Drp1 at a conserved Serine residue by an outer mitochondrial kinase (PKA/AKAP1) and phosphatase complex (PP2A/Bβ2) affects dendrite and synapse development in hippocampal neurons and synaptic plasticity and learning and memory in vivo.
Inducing mitochondria fragmentation decreases dendritic arbor complexity, but increases spine and synapse number. Mitochondrial elongation induces opposite effects. L-carnitine increases mitochondria membrane potential and recapitulates the dendritic and synaptic effects of mitochondrial elongation. Epistasis experiments substantiate our hypothesis that PP2A/Bβ2 dephosphorylates and PKA/AKAP1 phosphorylates Drp1 to change mitochondrial shape and regulate mitochondria localization, dendrite outgrowth, and synapse development.
Bβ2 null mice are viable and fertile, without obvious abnormalities. Bβ2 null mice demonstrate significantly larger cortical and hippocampal neuronal mitochondria than in wildtype. Bβ2 deletion decreases spine number on apical and basal cortical dendrites and hippocampal dendrites. Bβ2 null mice display significantly decreased input/output relationship in the hippocampus, consistent with a decrease in synapse number. In a combined context and cued fear-conditioning protocol, the hippocampal-dependent context recall trial revealed significant deficits in Bβ2 null and heterozygous mice. This deficit is also seen in hippocampal-dependent Barnes maze performance. These results are consistent with the reduced hippocampal long-term potentiation (LTP) found in Bβ2 null mice and demonstrate the importance of Bβ2 in hippocampal synaptic plasticity and memory. In conclusion, PP2A/Bβ2 and PKA/AKAP1 have important roles in mitochondria regulation and dendritic and synaptic development as seen in our results in vitro with rat hippocampal cultures and in vivo with Bβ2 null mice.
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Ecological Factors Controlling Microcystin Concentrations in the Bay of Quinte, Maumee Bay, and Three Grand River ReservoirsYakobowski, Sarah Jane 01 1900 (has links)
Certain types of cyanobacteria have the potential to produce toxins including microcystin, a hepatotoxin. Toxic cyanobacterial blooms are becoming increasingly common worldwide. They are a concern in the Great Lakes and surrounding waters. In this study, Lake Ontario’s Bay of Quinte, Lake Erie’s Maumee Bay, and three reservoirs along the Grand River were studied. Environmental variables, cyanobacterial biomass inferred from the Fluoroprobe, and microcystin concentrations were measured. In 2005 the three reservoirs, Belwood Lake, Conestogo Lake, and Guelph Lake were sampled every two weeks from July to September. Belwood Lake was also sampled in October when a cyanobacterial bloom occurred. In 2006 the Bay of Quinte was sampled twice, in July and September, and Maumee Bay was sampled twice, in June and August.
Physical variables measured included water transparency and temperature. All species of nitrogen (N) and phosphorus (P) were measured, along with extracted chlorophyll a and particulate carbon (C), N, and P. The distribution of chlorophyll and major algal groups throughout the water column was profiled in situ using a spectral fluorometer (Fluoroprobe).Variable fluorescence of phytoplankton was assessed using Pulse Amplitude Modulated (PAM) fluorometry to measure photosynthetic parameters. Phytoplankton counts were performed on selected samples from the Bay of Quinte and Maumee Bay.
Total and dissolved microcystin were measured using the protein phosphatase inhibition assay (PPIA). PPIA was chosen over alternative detection methods because it is a functional assay that measures the level of microcystin in a sample via the amount of protein phosphatase inhibition that it exerts. This yields ecologically relevant data as protein phosphatase inhibition is the main mode of microcystin toxicity. The PPIA formulation used in our lab was based on variations in the literature that use unconcentrated water samples directly in the assay. The assay was optimized to employ both a higher and lower standard curve through the use of two enzyme concentrations. The lower enzyme concentration allowed the method detection limit to be decreased to 0.05 µg/L to accommodate our low-microcystin samples.
In the Bay of Quinte, microcystin levels were higher in July 2006 (total mean=2.25 μg/L ) than in September 2006 (total mean=0.58 μg/L). In July a cyanobacterial bloom consisting of 97% Microcystis spp. was present. In September 83% of the cyanobacterial biomass was composed of Anabaena spiroides and only 8% was Microcystis spp. In the Bay of Quinte elevated microcystin concentrations were associated with higher soluble reactive P levels, lower seston C:P molar ratios, and lower total N. In Maumee Bay microcystin levels were higher in August 2006 (total mean= 4.45 μg/L) than they were in June 2006 (<0.05 μg/L). In August a cyanobacterial bloom consisting of 22% Microcystis spp. and 48% Aphanizomenon flos-aquae was observed. Higher microcystin concentrations in Maumee Bay were associated with decreased total N: total P molar ratios, increased total P, and decreased water transparency as measured by Secchi depth.
Belwood Lake had the highest microcystin levels of the three reservoirs but only once exceeded the recommended World Health Organization concentration of 1.0 μg/L. Belwood Lake’s largest cyanobacterial bloom in October 2005 was accompanied by relatively low microcystin levels (<0.2 μg/L). Conestogo and Guelph lakes always had microcystin levels below 0.2 μg/L and 0.6 μg/L, respectively. In the Grand River reservoirs, increased microcystin concentrations were associated with higher chlorophyll a, higher light attenuation coefficients, lower total N, lower total N: total P molar ratios, higher C:P molar ratios, lower nitrate, higher cyanobacterial biomass, and higher total P. When data from the Bay of Quinte, Maumee Bay, and Grand River reservoirs were pooled, total microcystin had the most significant positive correlation with total P. Total microcystin and water temperature also had a significant positive correlation.
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Ecological Factors Controlling Microcystin Concentrations in the Bay of Quinte, Maumee Bay, and Three Grand River ReservoirsYakobowski, Sarah Jane 01 1900 (has links)
Certain types of cyanobacteria have the potential to produce toxins including microcystin, a hepatotoxin. Toxic cyanobacterial blooms are becoming increasingly common worldwide. They are a concern in the Great Lakes and surrounding waters. In this study, Lake Ontario’s Bay of Quinte, Lake Erie’s Maumee Bay, and three reservoirs along the Grand River were studied. Environmental variables, cyanobacterial biomass inferred from the Fluoroprobe, and microcystin concentrations were measured. In 2005 the three reservoirs, Belwood Lake, Conestogo Lake, and Guelph Lake were sampled every two weeks from July to September. Belwood Lake was also sampled in October when a cyanobacterial bloom occurred. In 2006 the Bay of Quinte was sampled twice, in July and September, and Maumee Bay was sampled twice, in June and August.
Physical variables measured included water transparency and temperature. All species of nitrogen (N) and phosphorus (P) were measured, along with extracted chlorophyll a and particulate carbon (C), N, and P. The distribution of chlorophyll and major algal groups throughout the water column was profiled in situ using a spectral fluorometer (Fluoroprobe).Variable fluorescence of phytoplankton was assessed using Pulse Amplitude Modulated (PAM) fluorometry to measure photosynthetic parameters. Phytoplankton counts were performed on selected samples from the Bay of Quinte and Maumee Bay.
Total and dissolved microcystin were measured using the protein phosphatase inhibition assay (PPIA). PPIA was chosen over alternative detection methods because it is a functional assay that measures the level of microcystin in a sample via the amount of protein phosphatase inhibition that it exerts. This yields ecologically relevant data as protein phosphatase inhibition is the main mode of microcystin toxicity. The PPIA formulation used in our lab was based on variations in the literature that use unconcentrated water samples directly in the assay. The assay was optimized to employ both a higher and lower standard curve through the use of two enzyme concentrations. The lower enzyme concentration allowed the method detection limit to be decreased to 0.05 µg/L to accommodate our low-microcystin samples.
In the Bay of Quinte, microcystin levels were higher in July 2006 (total mean=2.25 μg/L ) than in September 2006 (total mean=0.58 μg/L). In July a cyanobacterial bloom consisting of 97% Microcystis spp. was present. In September 83% of the cyanobacterial biomass was composed of Anabaena spiroides and only 8% was Microcystis spp. In the Bay of Quinte elevated microcystin concentrations were associated with higher soluble reactive P levels, lower seston C:P molar ratios, and lower total N. In Maumee Bay microcystin levels were higher in August 2006 (total mean= 4.45 μg/L) than they were in June 2006 (<0.05 μg/L). In August a cyanobacterial bloom consisting of 22% Microcystis spp. and 48% Aphanizomenon flos-aquae was observed. Higher microcystin concentrations in Maumee Bay were associated with decreased total N: total P molar ratios, increased total P, and decreased water transparency as measured by Secchi depth.
Belwood Lake had the highest microcystin levels of the three reservoirs but only once exceeded the recommended World Health Organization concentration of 1.0 μg/L. Belwood Lake’s largest cyanobacterial bloom in October 2005 was accompanied by relatively low microcystin levels (<0.2 μg/L). Conestogo and Guelph lakes always had microcystin levels below 0.2 μg/L and 0.6 μg/L, respectively. In the Grand River reservoirs, increased microcystin concentrations were associated with higher chlorophyll a, higher light attenuation coefficients, lower total N, lower total N: total P molar ratios, higher C:P molar ratios, lower nitrate, higher cyanobacterial biomass, and higher total P. When data from the Bay of Quinte, Maumee Bay, and Grand River reservoirs were pooled, total microcystin had the most significant positive correlation with total P. Total microcystin and water temperature also had a significant positive correlation.
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