Indirect Effects of Heavy Metals on Parasites May Cause Shifts in Snail Species Compositions

Lefcort, Hugh; Aguon, M. Q.; Bond, K. A.; Chapman, Kristopher; Chaquette, R.; Clark, J. Marshall; Kornachuk, P.; Lang, Bruce Z.; Martin, Jean-Charles

doi:10.1007/s00244-002-1173-8

Cited by 40 publications

(27 citation statements)

References 18 publications

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“…In fact, over one-half the superfund sites in the United States are contaminated with at least one heavy metal (www.atsdr.cdc.gov). Heavy metals contaminate drinking water reservoirs and freshwater habitats and can alter macro-and microbiological communities (18,24). The known mechanisms of heavy metal toxicity include inducing oxidative stress and interfering with protein folding and function (30).…”

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confidence: 99%

Heavy Metal Resistance of Biofilm and Planktonic Pseudomonas aeruginosa

Teitzel

Parsek

2003

Appl Environ Microbiol

604

373

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A study was undertaken to examine the effects of the heavy metals copper, lead, and zinc on biofilm and planktonic Pseudomonas aeruginosa. A rotating-disk biofilm reactor was used to generate biofilm and freeswimming cultures to test their relative levels of resistance to heavy metals. It was determined that biofilms were anywhere from 2 to 600 times more resistant to heavy metal stress than free-swimming cells. When planktonic cells at different stages of growth were examined, it was found that logarithmically growing cells were more resistant to copper and lead stress than stationary-phase cells. However, biofilms were observed to be more resistant to heavy metals than either stationary-phase or logarithmically growing planktonic cells. Microscopy was used to evaluate the effect of copper stress on a mature P. aeruginosa biofilm. The exterior of the biofilm was preferentially killed after exposure to elevated concentrations of copper, and the majority of living cells were near the substratum. A potential explanation for this is that the extracellular polymeric substances that encase a biofilm may be responsible for protecting cells from heavy metal stress by binding the heavy metals and retarding their diffusion within the biofilm.Heavy metals are ubiquitous and persistent environmental pollutants that are introduced into the environment through anthropogenic activities, such as mining and smelting, as well as through other sources of industrial waste. In fact, over one-half the superfund sites in the United States are contaminated with at least one heavy metal (www.atsdr.cdc.gov). Heavy metals contaminate drinking water reservoirs and freshwater habitats and can alter macro-and microbiological communities (18, 24). The known mechanisms of heavy metal toxicity include inducing oxidative stress and interfering with protein folding and function (30).Bacteria have developed a variety of resistance mechanisms to counteract heavy metal stress. These mechanisms include the formation and sequestration of heavy metals in complexes, reduction of a metal to a less toxic species, and direct efflux of a metal out of the cell (30-33). Pseudomonas aeruginosa is a ubiquitous, environmentally important microbe that may employ many resistance mechanisms, such as the mer operon that reduces toxic Hg 2ϩ to volatile Hg 0 , which then diffuses out of the cell (33). However, in bacteria, efflux systems are a more common resistance mechanism for dealing with heavy metals. One such system is the cop system of Pseudomonas syringae, which contains the structural genes copABCD and is homologous to the pco system in Escherichia coli. The copB and copD genes are involved in the transport of copper across the membrane, while the products of the copA and copC genes are outer membrane proteins that bind Cu 2ϩ in the periplasm, protecting the cell from copper (6, 36). Other types of efflux systems simply pump toxic metal ions out of the cell; these systems include the P-type ATPase cadA, which was first identified in Staphylococcus aureus and...

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confidence: 99%

Heavy Metal Resistance of Biofilm and Planktonic Pseudomonas aeruginosa

Teitzel

Parsek

2003

Appl Environ Microbiol

604

373

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“…Poleo et al (2004) found that aluminum and zinc decreased the number of parasites in Atlantic salmon Salmo salar. Parasite diversity and intensity in 2 snail species (Physella columbiana and Lymnaea palustris) were lower in lakes polluted by heavy metals than in reference lakes, which may have influenced competitive interactions between the 2 snail species (Lefcort et al 2002). and studied the tapeworm Bothriocephalus acheilognathi in Gambusia affinis (mosquitofish), Notropis lutrensis (red shiners), and Pimophales promelus (fathead minnows) in a cooling pond receiving thermally and selenium-enriched fly ash from a coal-fired power plant in North Carolina, USA.…”

Section: Discussionmentioning

confidence: 98%

Effects of nitrate and the pathogenic water mold Saprolegnia on survival of amphibian larvae

Romansic¹,

Diez²,

Higashi³

et al. 2006

Dis. Aquat. Org.

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We tested for a synergism between nitrate and Saprolegnia, a pathogenic water mold, using larvae of 3 amphibian species: Ambystoma gracile (northwestern salamander), Hyla regilla (Pacific treefrog) and Rana aurora (red-legged frog). Each species was tested separately, using a 3 × 2 fully factorial experiment with 3 nitrate treatments (none, low and high) and 2 Saprolegnia treatments (Saprolegnia and control). Survival of H. regilla was not affected significantly by either experimental factor. In contrast, survival of R. aurora was affected by a less-than-additive interaction between Saprolegnia and nitrate. Survival of R. aurora was significantly lower in the Saprolegnia compared to the control treatment when nitrate was not added, but there was no significant difference in survival between Saprolegnia and control treatments in the low and high nitrate treatments, consistent with increased nitrate preventing Saprolegnia from causing mortality of R. aurora. Survival of A. gracile followed a similar pattern, but the difference between Saprolegnia and control treatments when nitrate was not added was not significant, nor was the nitrate × Saprolegnia interaction. Our study suggests that Saprolegnia can cause mortality in amphibian larvae, that there are interspecific differences in susceptibility and that the effects of Saprolegnia on amphibians are context-dependent. KEY WORDS: Pathogen · Saprolegnia · Amphibian Resale or republication not permitted without written consent of the publisherDis Aquat Org 68: [235][236][237][238][239][240][241][242][243] 2006 Saprolegnia, a water mold, is one important pathogen found in many amphibian populations (e.g. Strijbosch 1979, Banks & Beebee 1988, Blaustein et al. 1994. Furthermore, Saprolegnia-associated mortality appears to increase in the presence of abiotic stressors (Strijbosch 1979, Banks & Beebee 1988, Kiesecker & Blaustein 1995, Kiesecker et al. 2001a.Saprolegnia (family Saprolegniaceae) is both saprobic and parasitic, obtaining nutrition from decaying organic matter or living hosts (Seymour 1970). Saprolegnia infects a wide variety of organisms, including insects, turtles, fishes, and amphibians (MacGregor 1921, Seymour 1970. In amphibians, embryos and larvae can become infected (Bragg & Bragg 1958, Walls & Jaeger 1987, Blaustein et al. 1994. Saprolegnia-infected embryos of fishes and amphibians become covered with visible white hyphal filaments and usually do not hatch (Blaustein et al. 1994). Infection can spread via contact from growing hyphae (in the case of immobile hosts such as amphibian egg masses) or through colonization by free-swimming zoospores (Wood & Willoughby 1986). Transmission can occur between species, for example, between fishes and amphibians (Kiesecker et al. 2001b). Fishes and amphibians may also be infected by Saprolegnia via contact with infected soil (Kiesecker et al. 2001b). Host species show strong interspecific variation in their susceptibility to infection (Richards & Pickering 1978, Wood & Willoughby 1986, Kiesecker & Blau...

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“…Hence, pollution might influence the growth and reproduction of food-borne trematodes, resulting in lower parasite diversities and intensities at polluted sites. For example, snails exposed to metals had lower trematode infection intensities, and fewer species were found (64). In Henan province, China, low prevalences of paragonimiasis were found for two villages, where gold mining had contaminated streams and killed crabs, the second intermediate host of paragonimiasis (6).…”

Section: Epidemiological Patternsmentioning

confidence: 99%

Food-Borne Trematodiases

Keiser¹,

2009

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SUMMARY An estimated 750 million people are at risk of infections with food-borne trematodes, which comprise liver flukes (Clonorchis sinensis, Fasciola gigantica, Fasciola hepatica, Opisthorchis felineus, and Opisthorchis viverrini), lung flukes (Paragonimus spp.), and intestinal flukes (e.g., Echinostoma spp., Fasciolopsis buski, and the heterophyids). Food-borne trematodiases pose a significant public health and economic problem, yet these diseases are often neglected. In this review, we summarize the taxonomy, morphology, and life cycle of food-borne trematodes. Estimates of the at-risk population and number of infections, geographic distribution, history, and ecological features of the major food-borne trematodes are reviewed. We summarize clinical manifestations, patterns of infection, and current means of diagnosis, treatment, and other control options. The changing epidemiological pattern and the rapid growth of aquaculture and food distribution networks are highlighted, as these developments might be associated with an elevated risk of transmission of food-borne trematodiases. Current research needs are emphasized.

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Indirect Effects of Heavy Metals on Parasites May Cause Shifts in Snail Species Compositions

Cited by 40 publications

References 18 publications

Heavy Metal Resistance of Biofilm and Planktonic Pseudomonas aeruginosa

Heavy Metal Resistance of Biofilm and Planktonic Pseudomonas aeruginosa

Effects of nitrate and the pathogenic water mold Saprolegnia on survival of amphibian larvae

Food-Borne Trematodiases

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