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Abstract

Cd and Pb concentrations were measured in water, sediment and plant organs collected from selective sites located along the Bogdanka river (Poznań, Poland) in the 2012 growing season. The aim of the investigations was to monitor changes in heavy metal (HM) concentrations in different media over the periods, as well as to evaluate potential of two littoral plants, Phragmites australis and Typha angustifolia, for phytoremediation under natural conditions. Investigations revealed differences in HM concentrations in water and sediments. Higher values were observed in sediments than in water. The decrease in concentrations of both HMs in sediments was noted in two of the three selected water reservoirs during growing seasons, which suggests the possibility of their adsorption and accumulation by aquatic plants. Both investigated plant species accumulated ample amount of Cd and Pb in underground and aboveground plant tissues, however T. angustifolia revealed higher Cd translocation potential than P. australis. The latter revealed higher Pb accumulation in two lakes. Moreover, the translocation ratio was usually higher in spring, especially for Pb, in both plant species. Increasing level of pollution load index in sediment along the Bogdanka watercourse indicates accumulation of measured HMs.

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Authors and Affiliations

Jolanta Kanclerz
Klaudia Borowiak
Marta Lisiak
Mirosław Mleczek
Kinga Drzewiecka
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Abstract

In this paper, we consider the development of reliable tools to assess the water quality and state of aquatic ecosystems in dynamic conditions a crucial need to address. One of such tools could be devised by monitoring the taxonomic structure of reservoirs’ microbiomes. Microbial taxa’s ecological and metabolic characteristics suggest their essential roles in maintaining the water ecosystem’s environmental equilibrium. The study aimed to explainthe role of diversity and seasonal variability of the microbial communities in the ecosystem stability on the example of Goczałkowice Reservoir (Poland). The structure of the reservoir microbiome was studied using bioinformatics and modeling techniques. Water was sampled periodically in July & November 2010, and April 2011 at four representative sites. The abundance and relative fraction of the limnetic taxonomic units were determined in respectto the physicochemical indices. Significant seasonal variations in the number of operational taxonomic units (OTU)were observed within the reservoir basin’s main body but not at the main tributary’s mouth. The highest valuesof the correlation coefficients between OTU and physicochemical variables were obtained for Burkholderiales,Pseudoanabenales, Rickettsiales, Roseiflexales, Methylophilales, Actinomycetales, and Cryptophyta. Thesemicroorganisms are proposed as indicators of environmental conditions and water quality. Metataxonomic analyses of the fresh water microbiome in the reservoir, showed that microorganisms constitute conservative communities that undergo seasonal and local changes regarding the relative participation of the identified taxa. Therefore, we propose that monitoring those variations could provide a reliable measure of the state of aquatic ecosystems.
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Authors and Affiliations

Andrzej Woźnica
1
Mirosław Kwaśniewski
2
Karolina Chwiałkowska
2
Bartosz Łozowski
1
Damian Absalon
1
Marcin Libera
3
Michał Krzyżowski
1
Agnieszka Babczyńska
1

  1. University of Silesia in Katowice, Faculty of Natural Sciences, Katowice, Poland
  2. Medical University of Bialystok, Faculty of Medicine, Bialystok, Poland
  3. University of Silesia in Katowice, Faculty of Science and Technology, Katowice, Poland
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Abstract

In this article we investigate diatom assemblages in surface sediments of the subarctic Lake Imandra. We examine taxonomic composition and ecological structure and describe spatial variations of diatoms over the lake area. The diatom flora described here are characterized by abundance of planktonic centric species. The habitats of diatoms in the different stretches of Lake Imandra reflect local environmental conditions and are determined by the type and intensity of the anthropogenic impact. Stephanodiscus minutulus, S. alpinus, Aulacoseira islandica are the most abundant species in the area of the lake affected by industrial effluents and eutrophication, while Pantocsekiella comensis is most typical in the background sites of the lake. Diatoms’ taxonomic diversity is high in shallow bays where aquatic vegetation is common. Abundance of diatoms in areas affected by anthropogenic eutrophication reflects the high intensity of plankton primary production. Differences in the ecological structure of the diatom assemblages in different parts of Lake Imandra are caused by significant hydrochemical heterogeneity of the water quality.
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Authors and Affiliations

Sofia Vokueva
1
ORCID: ORCID
Dmitrii Denisov
1
ORCID: ORCID

  1. Institute of the North Industrial Ecology Problems, Federal Research Center “Kola Science Center of RAS”, 8a Akademgorodok Street, 184209, Apatity, Murmansk region, Russia

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