Your search keyword '"Karjalainen AK"' showing total 2 results

1. Tolerance of whitefish (Coregonus lavaretus) early life stages to manganese sulfate is affected by the parents.

Author

Arola HE, Karjalainen J, Vehniäinen ER, Väisänen A, Kukkonen JVK, and Karjalainen AK

Subjects

Animals, Female, Gene Expression drug effects, Larva drug effects, Lethal Dose 50, Male, Manganese Compounds, Metallothionein metabolism, Ovum drug effects, Ovum metabolism, Paternal Exposure, Salmonidae growth & development, Drug Tolerance, Salmonidae metabolism, Sulfates toxicity

Abstract

European whitefish (Coregonus lavaretus) embryos and larvae were exposed to 6 different manganese sulfate (MnSO 4 ) concentrations from fertilization to the 3-d-old larvae. The fertilization success, offspring survival, larval growth, yolk consumption, embryonic and larval Mn tissue concentrations, and transcript levels of detoxification-related genes were measured in the long-term incubation. A full factorial breeding design (4 females × 2 males) allowed examination of the significance of both female and male effects, as well as female-male interactions in conjunction with the MnSO 4 exposure in terms of the observed endpoints. The MnSO 4 exposure reduced the survival of the whitefish early life stages. The offspring MnSO 4 tolerance also was affected by the female parent, and the female-specific mean lethal concentrations (LC50s) varied from 42.0 mg MnSO 4 /L to 84.6 mg MnSO 4 /L. The larval yolk consumption seemed slightly inhibited at the exposure concentration of 41.8 mg MnSO 4 /L. The MnSO 4 exposure caused a significant induction of metallothionein-A (mt-a) and metallothionein-B (mt-b) in the 3-d-old larvae, and at the exposure concentration of 41.8 mg MnSO 4 /L the mean larval mt-a and mt-b expressions were 47.5% and 56.6% higher, respectively, than at the control treatment. These results illustrate that whitefish reproduction can be impaired in waterbodies that receive Mn and SO 4 in concentrations substantially above the typical levels in boreal freshwaters, but the offspring tolerance can be significantly affected by the parents and in particular the female parent. Environ Toxicol Chem 2017;36:1343-1353. © 2016 SETAC., (© 2016 SETAC.)

Published

2017

2. Assessing ecotoxicity of biomining effluents in stream ecosystems by in situ invertebrate bioassays: A case study in Talvivaara, Finland.

Author

Salmelin J, Leppänen MT, Karjalainen AK, Vuori KM, Gerhardt A, and Hämäläinen H

Subjects

Animals, Behavior, Animal drug effects, Biological Assay, Ecosystem, Ecotoxicology, Finland, Insecta, Water Pollutants, Chemical analysis, Environmental Monitoring methods, Mining, Oligochaeta drug effects, Rivers chemistry, Water Pollutants, Chemical toxicity

Abstract

Mining of sulfide-rich pyritic ores produces acid mine drainage waters and has induced major ecological problems in aquatic ecosystems worldwide. Biomining utilizes microbes to extract metals from the ore, and it has been suggested as a new sustainable way to produce metals. However, little is known of the potential ecotoxicological effects of biomining. In the present study, biomining impacts were assessed using survival and behavioral responses of aquatic macroinvertebrates at in situ exposures in streams. The authors used an impedance conversion technique to measure quantitatively in situ behavioral responses of larvae of the regionally common mayfly, Heptagenia dalecarlica, to discharges from the Talvivaara mine (Sotkamo, Northern Finland), which uses a biomining technique. Behavioral responses measured in 3 mine-impacted streams were compared with those measured in 3 reference streams. In addition, 3-d survival of the mayfly larvae and the oligochaete Lumbriculus variegatus was measured in the study sites. Biomining impacts on stream water quality included increased concentrations of sulfur, sulfate, and metals, especially manganese, cadmium, zinc, sodium, and calcium. Survival of the invertebrates in the short term was not affected by the mine effluents. In contrast, apparent behavioral changes in mayfly larvae were detected, but these responses were not consistent among sites, which may reflect differing natural water chemistry of the study sites. Environ Toxicol Chem 2017;36:147-155. © 2016 SETAC., (© 2016 SETAC.)

Published

2017