18 results on '"René S. Shahmohamadloo"'
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2. Cyanotoxins within and Outside of Microcystis aeruginosa Cause Adverse Effects in Rainbow Trout (Oncorhynchus mykiss)
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Paul K. Sibley, Michael Sarnacki, Gabrielle Hankins, John S. Lumsden, Damon Strong, Xavier Ortiz Almirall, Denina B.D. Simmons, Polina Konopelko, Angela Vander Eyken, Satyendra P. Bhavsar, René S. Shahmohamadloo, Kate Hubbs, and Trudy Watson-Leung more...
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chemistry.chemical_classification ,0303 health sciences ,biology ,General Chemistry ,Microcystin ,010501 environmental sciences ,biology.organism_classification ,01 natural sciences ,Microbiology ,03 medical and health sciences ,chemistry ,Microcystis ,Toxicity ,polycyclic compounds ,Extracellular ,Environmental Chemistry ,Microcystis aeruginosa ,Rainbow trout ,14. Life underwater ,Anion binding ,Intracellular ,030304 developmental biology ,0105 earth and related environmental sciences - Abstract
The global expansion of toxic Microcystis blooms, and production of cyanotoxins including microcystins, are an increasing risk to freshwater fish. Differentiating intracellular and extracellular microcystin toxicity pathways (i.e., within and outside of cyanobacterial cells) in fish is necessary to assess the severity of risks to populations that encounter harmful algal blooms in pre-to-postsenescent stages. To address this, adult and juvenile Rainbow Trout (Oncorhynchus mykiss) were, respectively, exposed for 96 h to intracellular and extracellular microcystins (0, 20, and 100 μg L-1) produced by Microcystis aeruginosa. Fish were dissected at 24 h intervals for histopathology, targeted microcystin quantification, and nontargeted proteomics. Rainbow Trout accumulated intracellular and extracellular microcystins in all tissues within 24 h, with greater accumulation in the extracellular state. Proteomics revealed intracellular and extracellular microcystins caused sublethal toxicity by significantly dysregulating proteins linked to the cytoskeletal structure, stress responses, and DNA repair in all tissues. Pyruvate metabolism in livers, anion binding in kidneys, and myopathy in muscles were also significantly impacted. Histopathology corroborated these findings with evidence of necrosis, apoptosis, and hemorrhage at similar severity in both microcystin treatments. We demonstrate that sublethal concentrations of intracellular and extracellular microcystins cause adverse effects in Rainbow Trout after short-term exposure. more...
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- 2021
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3. Experimental evidence from the field that naturally weathered microplastics accumulate cyanobacterial toxins in eutrophic lakes
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Eden K. Hataley, René S. Shahmohamadloo, Xavier Ortiz Almirall, Anna L. Harrison, Chelsea M. Rochman, Shan Zou, and Diane M. Orihel
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microplastics ,Microcystins ,Cyanobacteria Toxins ,Health, Toxicology and Mutagenesis ,biofilm ,Lakes ,adsorption ,freshwater toxicology ,550 Earth sciences & geology ,algal toxins ,Environmental Chemistry ,Humans ,Plastics ,absorption ,Ecosystem ,Water Pollutants, Chemical ,Environmental Monitoring - Abstract
Freshwater ecosystems with recurring harmful algal blooms can also be polluted with plastics. Thus the two environmental problems may interact. To test whether microplastics influence the partitioning of microcystins in freshwater lakes, we examined the sorption of four microcystin congeners to different polymers of commercially available plastics (low-density polyethylene, polyethylene terephthalate, polyvinyl chloride, and polypropylene). We conducted three experiments: a batch sorption experiment in the laboratory with pristine microplastics of four different polymers, a second batch sorption experiment in the laboratory to compare pristine and naturally weathered microplastics of a single polymer, and a 2-month sorption experiment in the field with three different polymers experiencing natural weathering in a eutrophic lake. This series of experiments led to a surprising result: microcystins sorbed poorly to all polymers tested under laboratory conditions (0.01% of the initial amount added), irrespective of weathering, yet in the field experiment, all polymers accumulated microcystins under ambient conditions in a eutrophic lake (range: 0-84.1 ng/g). Furthermore, we found that the sorption capacity for microcystins differed among polymers in the laboratory experiment yet were largely the same in the field. We also found that the affinity for plastic varied among microcystin congeners, namely, more polar congeners demonstrated a greater affinity for plastic than less polar congeners. Our study improves our understanding of the role of polymer and congener type in microplastic-microcystin sorption and provides novel evidence from the field, showing that naturally weathered microplastics in freshwater lakes can accumulate microcystins. Consequently, we caution that microplastics may alter the persistence, transport, and bioavailability of microcystins in freshwaters, which could have implications for human and wildlife health. Environ Toxicol Chem 2022;41:3017-3028. © 2022 SETAC. more...
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- 2022
4. Effects of Hydrogen Peroxide on Cyanobacterium Microcystis aeruginosa in the Presence of Nanoplastics
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Yawen Guo, Chelsea M. Rochman, René S. Shahmohamadloo, Anna M O'Brien, Tiago F. Lins, David Sinton, and Xavier Ortiz Almirall
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0303 health sciences ,biology ,Chemistry ,010501 environmental sciences ,biology.organism_classification ,01 natural sciences ,03 medical and health sciences ,chemistry.chemical_compound ,Chemistry (miscellaneous) ,Environmental Chemistry ,Chemical Engineering (miscellaneous) ,Microcystis aeruginosa ,Hydrogen peroxide ,030304 developmental biology ,0105 earth and related environmental sciences ,Water Science and Technology ,Nuclear chemistry - Published
- 2021
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5. Cyanotoxins accumulate in Lake St. Clair fish yet their fillets are safe to eat
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René S. Shahmohamadloo, Satyendra P. Bhavsar, Xavier Ortiz Almirall, Stephen A. C. Marklevitz, Seth M. Rudman, and Paul K. Sibley
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Environmental Engineering ,Environmental Chemistry ,Pollution ,Waste Management and Disposal - Abstract
Consuming fish exposed to cyanobacterial harmful algal blooms (HABs) may be a major route of microcystin toxin exposure to humans. However, it remains unknown whether fish can accumulate and retain microcystins temporally in waterbodies with recurring seasonal HABs, particularly before and after a HAB event when fishing is active. We conducted a field study on Largemouth Bass, Northern Pike, Smallmouth Bass, Rock Bass, Walleye, White Bass, and Yellow Perch to assess the human health risks to microcystin toxicity via fish consumption. We collected 124 fish in 2016 and 2018 from Lake St. Clair, a large freshwater ecosystem in the North American Great Lakes that is actively fished pre- and post-HAB periods. Muscles were analyzed using the MMPB Lemieux Oxidation method for total microcystins, which was used to perform a human health risk assessment for comparison against fish consumption advisory benchmarks available for Lake St. Clair. From this collection 35 fish livers were additionally extracted to confirm the presence of microcystins. Microcystins were detected in all livers at widely varying concentrations (1-1,500 ng g-1ww), suggesting HABs are an underappreciated and pervasive stressor to fish populations. Conversely, microcystin levels were consistently low in muscles (0-15 ng g-1ww) and presented negligible risk, empirically supporting that fillets may be safely consumed before and after HAB events following fish consumption advisories. more...
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- 2023
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6. Lake Erie fish safe to eat yet afflicted by algal hepatotoxins
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René S. Shahmohamadloo, Satyendra P. Bhavsar, Xavier Ortiz Almirall, Stephen A. C. Marklevitz, Seth M. Rudman, and Paul K. Sibley
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Environmental Engineering ,Environmental Chemistry ,Pollution ,Waste Management and Disposal - Abstract
Microcystin toxins from harmful algal blooms (HABs) can accumulate and persist in fish, raising dual concerns about human health risks from consumption and the potential for detrimental impacts on fish populations. However, there are fundamental unknowns about the relationship between HABs and fish populations driven by a lack of field information on toxin accumulation and retention over space and time. We conducted a field study to assess human health risks from consuming fish caught across all life stages of a HAB and to determine the pervasiveness of potentially harmful levels of microcystins on fish populations. We collected 190 fish in 2015 and 2017 from Lake Erie, a large freshwater ecosystem that is highly productive for fisheries and is an epicenter of HABs and microcystin toxicity events. Muscles and livers were analyzed for total microcystins, which was used to conduct a human health risk assessment for comparison against fish consumption advisory benchmarks available for Lake Erie. We find low human health risk from muscle consumption following the World Health Organization’s safety thresholds. However, all fish across capture dates had microcystins in their livers at levels shown to cause adverse effects, suggesting a pervasive and underappreciated toxic stressor. These data demonstrate that microcystins are retained in fish livers well beyond the cessation of HABs and calls for additional research to better understand the effects of sublethal toxic exposures for fish population dynamics, conservation, and related ecosystem services. more...
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- 2022
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7. The sustainable agriculture imperative: A perspective on the need for an agrosystem approach to meet the United Nations Sustainable Development Goals by 2030
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Catherine M. Febria, Evan D. G. Fraser, René S. Shahmohamadloo, and Paul K. Sibley
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Sustainable development ,Climate resilience ,Conservation of Natural Resources ,Regenerative agriculture ,United Nations ,Intensive farming ,Natural resource economics ,business.industry ,Geography, Planning and Development ,Agriculture ,Biodiversity ,General Medicine ,Sustainable Development ,Ecosystem services ,Soil ,Sustainability ,Sustainable agriculture ,Business ,Ecosystem ,General Environmental Science - Abstract
The development of modern, industrial agriculture and its high input-high output carbon energy model is rendering agricultural landscapes less resilient. The expected continued increase in the frequency and intensity of extreme weather events, in conjunction with declining soil health and biodiversity losses, could make food more expensive to produce. The United Nations has called for global action by establishing 17 sustainable development goals (SDGs), four of which are linked to food production and security: declining biodiversity (SDG 15), loss of ecosystem services and agroecosystem stability caused by increasing stress from food production intensification and climate change (SDG 13), declining soil health caused by agricultural practices (SDGs 2 and 6), and dependence on synthetic fertilizers and pesticides to maintain high productivity (SDG 2). To achieve these SDGs, the agriculture sector must take a leading role in reversing the many negative environmental trends apparent in today's agricultural landscapes to ensure that they will adapt and be resilient to climate change in 2030 and beyond. This will demand fundamental changes in how we practice agriculture from an environmental standpoint. Here, we present a perspective focused on the implementation of an agrosystem approach, which we define to promote regenerative agriculture, an integrative approach that provides greater resilience to a changing climate, reverses biodiversity loss, and improves soil health; honors Indigenous ways of knowing and a holistic approach to living off and learning from the land; and supports the establishment of emerging circular economies and community well-being. Integr Environ Assess Manag 2022;18:1199-1205. © 2021 SETAC. more...
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- 2021
8. Cyanotoxins within and Outside of
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René S, Shahmohamadloo, Xavier, Ortiz Almirall, Denina B D, Simmons, John S, Lumsden, Satyendra P, Bhavsar, Trudy, Watson-Leung, Angela Vander, Eyken, Gabrielle, Hankins, Kate, Hubbs, Polina, Konopelko, Michael, Sarnacki, Damon, Strong, and Paul K, Sibley more...
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Microcystis ,Microcystins ,Harmful Algal Bloom ,Oncorhynchus mykiss ,Animals ,Fresh Water ,Cyanobacteria - Abstract
The global expansion of toxic
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- 2021
9. An efficient and affordable laboratory method to produce and sustain high concentrations of microcystins by Microcystis aeruginosa
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Xavier Ortiz Almirall, René S. Shahmohamadloo, Claire Holeton, David G. Poirier, Paul K. Sibley, Satyendra P. Bhavsar, and Richard Chong-Kit
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Cyanobacteria ,Cyanotoxins ,Clinical Biochemistry ,Microcystin ,010501 environmental sciences ,Toxicology ,01 natural sciences ,Algal bloom ,Freshwater ecosystem ,03 medical and health sciences ,Laboratory flask ,Harmful algal blooms ,polycyclic compounds ,Microcystis aeruginosa ,14. Life underwater ,lcsh:Science ,ComputingMethodologies_COMPUTERGRAPHICS ,030304 developmental biology ,0105 earth and related environmental sciences ,chemistry.chemical_classification ,0303 health sciences ,Laboratory methods ,biology ,Hepatotoxin ,biology.organism_classification ,6. Clean water ,Medical Laboratory Technology ,Method for production of microcystins in Blue-Green-11 (BG-11) medium ,chemistry ,Environmental chemistry ,Environmental Science ,Strain CPCC 300 ,Environmental science ,lcsh:Q - Abstract
Graphical abstract, Microcystis aeruginosa is a cosmopolitan cyanobacteria that continues to jeopardize freshwater ecosystem services by releasing the hepatotoxin microcystin, which can, in some cases, cause death to aquatic fauna and even humans. Currently, our abilities to understand the mechanisms of microcystin toxicology are limited by the lack of a method for producing high concentrations, which are central to large-scale and long-term research in natural systems. Here we present an efficient and affordable laboratory method to produce high concentrations of microcystins by a toxigenic strain of M. aeruginosa. Through batch culture studies, we yielded microcystins at concentrations that are environmentally relevant to freshwaters around the world (1–300 μg L−1), maintained these concentrations without resupplying fresh medium (further reducing costs), and utilized rate equations to model the relationship between the environmental conditions in the cultures and changes occurring within the M. aeruginosa cells. Our assessment suggests that steady production of microcystins depends on the availability of carbon throughout the experiment. Hence, we recommend the use of tissue culture treated flasks with a vented cap to ensure the production of microcystins is uninterrupted. This method demonstrates that microcystins can be produced in the laboratory at concentrations relevant to freshwater ecosystems. • The method demonstrates M. aeruginosa CPCC 300 is a reliable strain of freshwater cyanobacteria that can yield microcystins at environmentally relevant concentrations. • Validation showed M. aeruginosa CPCC 300 is resilient in carbon-limited situations and may respond to stress by shifting the ratio of microcystin congeners. • Cell culture flasks with vented caps —filled no more than 50 % of the flask volume to allow for sufficient air exchange— are an excellent and cost-effective approach to maintaining cell growth and producing microcystins at a range between 300 to 1200 μg L−1. more...
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- 2019
10. Fish tissue accumulation and proteomic response to microcystins is species-dependent
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Satyendra P. Bhavsar, René S. Shahmohamadloo, Denina B.D. Simmons, David G. Poirier, Xavier Ortiz Almirall, and Paul K. Sibley
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Cyanobacteria ,Proteomics ,Environmental Engineering ,Microcystis ,Microcystins ,Health, Toxicology and Mutagenesis ,Harmful Algal Bloom ,Zoology ,Microcystin ,010501 environmental sciences ,01 natural sciences ,Algal bloom ,03 medical and health sciences ,polycyclic compounds ,Environmental Chemistry ,Animals ,Humans ,Microcystis aeruginosa ,14. Life underwater ,030304 developmental biology ,0105 earth and related environmental sciences ,Salvelinus ,chemistry.chemical_classification ,0303 health sciences ,biology ,Public Health, Environmental and Occupational Health ,General Medicine ,General Chemistry ,biology.organism_classification ,Pollution ,6. Clean water ,Trout ,chemistry ,Freshwater fish ,Rainbow trout - Abstract
Cyanotoxins including microcystins are increasing globally, escalating health risks to humans and wildlife. Freshwater fish can accumulate and retain microcystins in tissues; however, uptake and depuration studies thus far have not exposed fish to microcystins in its intracellular state (i.e., cell-bound or conserved within cyanobacteria), which is a primary route of exposure in the field, nor have they investigated sublethal molecular-level effects in tissues, limiting our knowledge of proteins responsible for microcystin toxicity pathways in pre-to-postsenescent stages of a harmful algal bloom. We address these gaps with a 2-wk study (1 wk of ‘uptake’ exposure to intracellular microcystins (0–40 μg L−1) produced by Microcystis aeruginosa followed by 1 wk of ‘depuration’ in clean water) using Rainbow Trout (Oncorhynchus mykiss) and Lake Trout (Salvelinus namaycush). Liver and muscle samples were collected throughout uptake and depuration phases for targeted microcystin quantification and nontargeted proteomics. For both species, microcystins accumulated at a higher concentration in the liver than muscle, and activated cellular responses related to oxidative stress, apoptosis, DNA repair, and carcinogenicity. However, intraspecific proteomic effects between Rainbow Trout and Lake Trout differed, and interspecific accumulation and retention of microcystins in tissues within each species also differed. We demonstrate that fish do not respond the same to cyanobacterial toxicity within and among species despite being reared in the same environment and diet. more...
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- 2021
11. Optimization of an MMPB Lemieux Oxidation method for the quantitative analysis of microcystins in fish tissue by LC-QTOF MS
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Paul K. Sibley, Maryam Tabatabaei Anaraki, René S. Shahmohamadloo, Xavier Ortiz Almirall, Satyendra P. Bhavsar, Karen MacPherson, and André J. Simpson
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Cyanobacteria ,Environmental Engineering ,010504 meteorology & atmospheric sciences ,Microcystins ,Microcystin ,010501 environmental sciences ,Isotope dilution ,Mass spectrometry ,01 natural sciences ,chemistry.chemical_compound ,Tandem Mass Spectrometry ,Environmental Chemistry ,Animals ,Derivatization ,Waste Management and Disposal ,0105 earth and related environmental sciences ,chemistry.chemical_classification ,Detection limit ,Perch ,Chromatography ,biology ,Fractional factorial design ,biology.organism_classification ,Pollution ,Lakes ,chemistry ,Oxidation-Reduction ,Chromatography, Liquid - Abstract
Microcystins are toxic heptapeptides produced by cyanobacteria in marine and freshwater environments. In biological samples such as fish, microcystins can be found in the free form or covalently bound to protein phosphatases type I and II. Total microcystins in fish have been quantified in the past using the Lemieux Oxidation approach, where all toxins are oxidated to a common fragment (2-methyl-3-methoxy-4-phenylbutyric acid, MMPB) regardless of their initial amino acid configuration or form (free or protein bound). These studies have been carried out using different experimental conditions and employed different quantification strategies. The present study has further investigated the oxidation step using a systematic approach, to identify the most important factors leading to a higher, more robust MMPB generation yield from fish tissue in order to reduce the method detection limit. Field samples were quantified using an in-situ generated MMPB matrix matched calibration curve by isotope dilution with d3-MMPB via liquid chromatography coupled to time-of-flight mass spectrometry (LC-QTOF MS). This approach improves method's accuracy by taking into account of potential matrix effects that could affect the derivatization, sample prepation and instrumental analysis steps. The validated method showed 16.7% precision (RSD) and +6.7% accuracy (bias), with calculated method detection limits of 7.28 ng g−1 Performance of the method was assessed with the analysis of laboratory exposed Rainbow Trout (Oncorhynchus mykiss) to cyanobacteria as a positive control, where no microcystins were detected in the pre-exposure fish liver and fillet, low levels in the exposed fillet (65.0 ng g−1) and higher levels in the exposed liver (696 ng g−1). Finally, the method was employed for the analysis of 26 fillets (muscle) and livers of Walleye (Sander vitreus) and Yellow Perch (Perca flavescens) from Lake Erie, showing very low concentrations of microcystins in the fillet and higher concentrations in liver, up to 3720 ng g−1. more...
- Published
- 2020
12. Evaluating the effects of triclosan on 3 field crops grown in 4 formulations of biosolids
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Paul K. Sibley, René S. Shahmohamadloo, Linda Lissemore, and Ryan S. Prosser
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Soil test ,Biosolids ,Health, Toxicology and Mutagenesis ,010501 environmental sciences ,engineering.material ,complex mixtures ,01 natural sciences ,Environmental impact of pharmaceuticals and personal care products ,chemistry.chemical_compound ,Environmental Chemistry ,0105 earth and related environmental sciences ,business.industry ,Compost ,fungi ,food and beverages ,04 agricultural and veterinary sciences ,Triclosan ,Agronomy ,chemistry ,Agriculture ,Soil water ,Shoot ,040103 agronomy & agriculture ,engineering ,0401 agriculture, forestry, and fisheries ,Environmental science ,business - Abstract
A growing body of evidence suggests that amending soil with biosolids can be an integral component of sustainable agriculture. Despite strong evidence supporting its beneficial use in agriculture, there are concerns that chemicals, such as pharmaceuticals and personal care products, could present a risk to terrestrial ecosystems and human health. Triclosan is one of the most commonly detected compounds in biosolids. To date, laboratory studies indicate that triclosan likely poses a de minimis risk to field crops; however, these studies were either conducted under unrealistic exposure conditions or only assessed 1 or 2 formulations of biosolids. The purpose of the present study was to characterize the effects of triclosan on field crops in soils amended with 4 different formulations of biosolids (liquid, dewatered, compost, and alkaline-hydrolyzed), containing both background and spiked triclosan concentrations, following best management practices used in the province of Ontario. Three crop species (corn, soybean, and spring wheat) were evaluated using several plant growth endpoints (e.g., root wet mass, shoot length, shoot wet/dry mass) in 70-d to 90-d potted soil tests. The results indicated no adverse impact of triclosan on any crop-biosolids combination. Conversely, amending soil with biosolids either enhanced or had no negative effect, on the growth of plants. Results of the present study suggest little risk of triclosan to crops in agricultural fields amended with biosolids. Environ Toxicol Chem 2017;36:1896–1908. © 2016 SETAC more...
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- 2017
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13. Shotgun proteomics analysis reveals sub-lethal effects in Daphnia magna exposed to cell-bound microcystins produced by Microcystis aeruginosa
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René S. Shahmohamadloo, Denina B.D. Simmons, and Paul K. Sibley
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Proteomics ,Microcystis ,Microcystins ,Physiology ,Harmful Algal Bloom ,Daphnia magna ,Apoptosis ,Microcystin ,010501 environmental sciences ,01 natural sciences ,Biochemistry ,Daphnia ,Microbiology ,Arthropod Proteins ,03 medical and health sciences ,polycyclic compounds ,Genetics ,Animals ,Microcystis aeruginosa ,Shotgun proteomics ,Molecular Biology ,reproductive and urinary physiology ,030304 developmental biology ,0105 earth and related environmental sciences ,chemistry.chemical_classification ,0303 health sciences ,biology ,fungi ,biology.organism_classification ,chemistry ,Fertilization ,Toxicogenomics - Abstract
Microcystins that are cell-bound within Microcystis have demonstrated the ability to cause lethal and reproductive impairment in Daphnia, who constitute an important part of aquatic food chains and are known to feed on viable cyanobacterial cells. Recent advances in environmental toxicogenomics can be used to better understand the mechanistic effects from exposure to cell-bound microcystins in Daphnia; however, there remains a need to examine the effects of microcystins exposure as a function of dose and time in order to help elucidate the progression of (sub-)lethal effects. This study examines the effects of cell-bound microcystin exposure in Daphnia magna as a function of dose and time with shotgun proteomics in order to measure and provide insightful evidence describing functional mechanisms from, and relationships between, protein populations in response to toxic Microcystis aeruginosa. We further characterize the life-history fitness of D. magna in the presence of toxic exposure by measuring somatic growth rate. Chronic dietary exposure to cell-bound microcystins reduced the somatic growth rate of D. magna. Through proteomics analysis, we identified a significant increase in abundance of proteins related to reproductive success and development, removal of superoxide radicals, and motor activity in D. magna parents exposed to cell-bound microcystins at sub-lethal concentrations. We also identified a significant decrease in abundance of proteins related to apoptosis, metabolism, DNA damage repair, and immunity in D. magna neonates. This information will improve our understanding of the risks posed by cell-bound microcystins to cladocerans in freshwater ecosystems. more...
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- 2019
14. Assessing the toxicity of cell-bound microcystins on freshwater pelagic and benthic invertebrates
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David G. Poirier, Xavier Ortiz Almirall, René S. Shahmohamadloo, Paul K. Sibley, and Satyendra P. Bhavsar
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Food Chain ,Microcystins ,Health, Toxicology and Mutagenesis ,Harmful Algal Bloom ,Daphnia magna ,0211 other engineering and technologies ,Zoology ,Fresh Water ,02 engineering and technology ,Microcystin ,010501 environmental sciences ,01 natural sciences ,Daphnia ,Algal bloom ,Lethal Dose 50 ,Microcystis ,polycyclic compounds ,Animals ,14. Life underwater ,Ephemeroptera ,0105 earth and related environmental sciences ,Invertebrate ,chemistry.chemical_classification ,021110 strategic, defence & security studies ,Life Cycle Stages ,biology ,Reproduction ,fungi ,Public Health, Environmental and Occupational Health ,Ceriodaphnia dubia ,Pelagic zone ,General Medicine ,biology.organism_classification ,Pollution ,chemistry ,Water Pollutants, Chemical - Abstract
Cyanobacterial harmful algal blooms dominated by Microcystis frequently produce microcystins, a family of toxins capable of inflicting harm to pelagic and benthic freshwater invertebrates. Research on the effect of microcystins on invertebrates is inconclusive; from one perspective, studies suggest invertebrates can coexist in toxic blooms; however, studies have also measured negative food-associated effects from microcystins. To test the latter perspective, we examined the reproduction, growth, and survival of laboratory-cultured Ceriodaphnia dubia, Daphnia magna, and Hexagenia spp. exposed to cell-bound microcystins through a series of life-cycle bioassays. Test organisms were exposed to a concentration gradient ranging from 0.5 μg L−1 to 300 μg L−1 microcystins, which corresponds to values typically found in freshwaters during bloom season. Lethal concentrations in C. dubia (LC50 = 5.53 μg L−1) and D. magna (LC50 = 85.72 μg L−1) exposed to microcystins were among the lowest recorded to date, and reproductive effects were observed at concentrations as low as 2.5 μg L−1. Length of D. magna was significantly impacted in microcystin treatments great than 2.5 μg L−1. No lethality or growth impairments were observed in Hexagenia. This information will improve our understanding of the risks posed by microcystins to food webs in freshwaters. more...
- Published
- 2019
15. Effect of Microcystis aeruginosa-Associated Microcystin-LR on the Survival of 2 Life Stages of Freshwater Mussel (Lampsilis siliquoidea)
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Ryan S. Prosser, Xavier Ortiz, Samantha May Gene, and René S. Shahmohamadloo
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Canada ,Lampsilis siliquoidea ,Microcystis ,Microcystins ,Health, Toxicology and Mutagenesis ,Harmful Algal Bloom ,0211 other engineering and technologies ,Zoology ,02 engineering and technology ,Microcystin ,010501 environmental sciences ,01 natural sciences ,Lethal Dose 50 ,polycyclic compounds ,Toxicity Tests, Acute ,Environmental Chemistry ,Animals ,Microcystis aeruginosa ,14. Life underwater ,Toxicity Tests, Chronic ,0105 earth and related environmental sciences ,chemistry.chemical_classification ,021110 strategic, defence & security studies ,biology ,fungi ,Environmental exposure ,Mussel ,Unionidae ,biology.organism_classification ,6. Clean water ,Acute toxicity ,Bivalvia ,chemistry ,13. Climate action ,Toxicity ,Marine Toxins - Abstract
Microcystin-LR is a toxin commonly produced by the cyanobacterium Microcystis aeruginosa. It is present in harmful algal blooms and is a concern for both human and environmental health in Canadian freshwater systems. Previous studies have investigated the toxicity of microcystin-LR to other organisms such as fish; however, it is important to assess its toxicity to native freshwater mussels (family Unionidae), which are considered imperiled. The present study examined the toxicity of microcystin-LR to fatmucket mussels (Lampsilis siliquoidea) at 2 different life stages. Juvenile mussels were exposed to microcystin-LR in a 28-d chronic test, and glochidia underwent a 72-h acute toxicity test. There was no significant relationship between glochidia viability and microcystin-LR concentration. The median lethal concentration (LC50) value for juvenile mussels after 28 d of exposure was 2.1 µg/L. To determine the environmental relevance of the observed toxicity, an environmental exposure distribution was created using Canadian and Canadian-US Great Lakes microcystin measurements. The 28-d LC50 value (2.1 µg/L) was greater than those values that occurred in the environment 95% of the time; however, the LC10 (0.45 µg/L) and LC25 (0.97 μg/L) values were not greater than the measured microcystin environmental values. This finding indicates that microcystins may exert toxic effects on juvenile mussels at environmentally relevant concentrations. Further investigation should be considered in terms of prolonged exposure to persistent microcystin-LR, and toxicity to sensitive species at different life stages. Environ Toxicol Chem 2019;38:2137-2144. © 2019 SETAC. more...
- Published
- 2019
16. Mentoring with trust
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René S. Shahmohamadloo
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Medical education ,Government ,Multidisciplinary ,Mentorship ,Work (electrical) ,Critical thinking ,Principal (computer security) ,Lab notebook ,Psychology ,Set (psychology) ,Graduation - Abstract
I hurried downstairs to the cafeteria. At the table sat my new mentees: six eager undergraduates who had signed on to work on an 8-month aquatic toxicology project I had devised. It was a crucial piece of my Ph.D. research, and it would satisfy a key graduation requirement for the undergrads. “Starting today, I get to learn what it's like to be my Ph.D. adviser,” I thought to myself excitedly. But a few minutes into the meeting, the students broke the news: They didn't have any training in toxicology. My chest tightened. How would this ever work? > “Letting the students find their own way gave them room to grow as scientists.” My inspiration to engage undergraduates in my research had come after 2 years of working as a teaching assistant. Many of my undergraduate students had voiced the same frustrations I once had: They were expected to absorb facts and regurgitate them in exams, rinse and repeat, without any real critical thinking or opportunity to apply what they had learned. I could fill that gap, I believed, by creating a project related to my own work and enlisting undergrads as the researchers, guiding them through the process while empowering them to take the lead. My thesis adviser was supportive, knowing it would be good experience for a principal investigator (PI) hopeful like me. My department purchased the fish we would study, and a government research lab offered space for the experiments. Everything was in place—except for the students' toxicology training. I was worried. But 150 yearling rainbow trout were waiting to be picked up from the hatchery. Backing out was not an option. I reminded myself how green I had been when I was an undergrad just starting to work with a Ph.D. student. My first day in the lab, I was tasked with exposing plants to precise doses of chemicals and measuring their responses—experiments unlike any I'd done before. Despite my lack of experience, my mentor gave me a key to the plant growth chambers and walked me through how to set up and run the experiment. Then, he left me to it. He assured me that he was available to help, but he did not hover over my shoulder. I spent hours meticulously setting up the experiment—and realized 3 hours later, after checking my lab notebook, that I had dosed the plants with the wrong concentrations of chemicals. I had to throw everything out and start over. But my mentor was patient. He let me make these mistakes so I could learn from them and find my own way as a researcher. Now his example inspired me. On the students' first day in the lab, I walked them through the facilities and trained them on the protocols they would be using. Then, I let them be and stood by, ready to help. In the first few days, I noticed that some forgot to calibrate the instruments or didn't follow my instructions for dissecting the fish. My instinct was to jump in and save the day. But instead, I refrained from intervening and watched proudly as the students identified their mistakes and learned from them. Later, I put them in the driver's seat when writing up the results for publication. The students surprised me by taking the paper in a different direction than we had discussed. Again, I trusted them, and they prepared an excellent manuscript. When we reconvened in the cafeteria for a reflection meeting 6 months into the project, the students thanked me for not micromanaging them, even though it had been scary for them at first. Letting the students find their own way gave them room to grow as scientists. And in the process, I also grew as a mentor. Good mentorship means trusting your mentees' capacity and treating them as more than instruments to collect data. I hope that someday I'm able to put this approach to use as a PI running my own lab. But it can be employed at any level. Good mentorship is good mentorship, whether you're a grad student or a PI—and, when given the chance, mentees can handle the responsibility. more...
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- 2020
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17. Effect of biosolids-derived triclosan and triclocarban on the colonization of plant roots by arbuscular mycorrhizal fungi
- Author
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René S. Shahmohamadloo, Ryan S. Prosser, Linda Lissemore, and Paul K. Sibley
- Subjects
Environmental Engineering ,Biosolids ,Triclocarban ,Moisture stress ,Agriculture ,Lettuce ,Biology ,Plant Roots ,Waste Disposal, Fluid ,Pollution ,Triclosan ,Crop ,chemistry.chemical_compound ,Nutrient ,Anti-Infective Agents ,Agronomy ,Symbiosis ,chemistry ,Mycorrhizae ,Soil Pollutants ,Environmental Chemistry ,Colonization ,Waste Management and Disposal ,Carbanilides - Abstract
Arbuscular mycorrhizal fungi (AMF) form a symbiotic relationship with the majority of crop plants. AMF provide plants with nutrients (e.g., P), modulate the effect of metal and pathogen exposure, and increase tolerance to moisture stress. The benefits of AMF to plant growth make them important to the development of sustainable agriculture. The land application of biosolids is becoming an increasingly common practice in sustainable agriculture, as a source of nutrients. However, biosolids have been found to contain numerous pharmaceutical and personal care products including antimicrobial chemicals such as triclosan and triclocarban. The potential risks that these two compounds may pose to plant-AMF interactions are poorly understood. The current study investigated whether biosolids-derived triclosan and triclocarban affect the colonization of the roots of lettuce and corn plants by AMF. Plants were grown in soil amended with biosolids that contained increasing concentrations of triclosan (0 to 307 μg/g dw) or triclocarban (0 to 304 μg/g dw). A relationship between the concentration of triclosan or triclocarban and colonization of plants roots by AMF was not observed. The presence of biosolids did not have a significant (p0.05) effect on percent colonization of corn roots but had a significant, positive effect (p0.05) on lettuce roots. Biosolids-derived triclosan and triclocarban did not inhibit the colonization of crop plant roots by AMF. more...
- Published
- 2015
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18. Evaluating the effects of triclosan on 3 field crops grown in 4 formulations of biosolids
- Author
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René S, Shahmohamadloo, Linda, Lissemore, Ryan S, Prosser, and Paul K, Sibley
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Crops, Agricultural ,Tandem Mass Spectrometry ,Humans ,Soil Pollutants ,Soybeans ,Zea mays ,Chromatography, High Pressure Liquid ,Plant Shoots ,Triclosan ,Triticum - Abstract
A growing body of evidence suggests that amending soil with biosolids can be an integral component of sustainable agriculture. Despite strong evidence supporting its beneficial use in agriculture, there are concerns that chemicals, such as pharmaceuticals and personal care products, could present a risk to terrestrial ecosystems and human health. Triclosan is one of the most commonly detected compounds in biosolids. To date, laboratory studies indicate that triclosan likely poses a de minimis risk to field crops; however, these studies were either conducted under unrealistic exposure conditions or only assessed 1 or 2 formulations of biosolids. The purpose of the present study was to characterize the effects of triclosan on field crops in soils amended with 4 different formulations of biosolids (liquid, dewatered, compost, and alkaline-hydrolyzed), containing both background and spiked triclosan concentrations, following best management practices used in the province of Ontario. Three crop species (corn, soybean, and spring wheat) were evaluated using several plant growth endpoints (e.g., root wet mass, shoot length, shoot wet/dry mass) in 70-d to 90-d potted soil tests. The results indicated no adverse impact of triclosan on any crop-biosolids combination. Conversely, amending soil with biosolids either enhanced or had no negative effect, on the growth of plants. Results of the present study suggest little risk of triclosan to crops in agricultural fields amended with biosolids. Environ Toxicol Chem 2017;36:1896-1908. © 2016 SETAC. more...
- Published
- 2016
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