Biomonitoring of Heavy Metal Air Pollution in Warsaw Using Two Moss Species Pleurozium schreberi and Sphagnum palustre

The aim of the study was to assess air pollution with heavy metals in Warsaw, on the basis of the concentrations of selected elements in moss samples. The active biomonitoring method (moss-bag technique) was applied using two moss species Pleurozium schreberi and Sphagnum palustre. Moss samples were collected in the Kampinos National Park, and the prepared moss bags were distributed and exposed on seven sites in Warsaw. The analysis of metals accumulated in mosses was performed twice in 2020, after two (August-September) and four months (August-November) of exposure. The concentrations of seven heavy metals (Cr, Cu, Pb, Ni, Fe, Cd and Zn) in the mosses were determined, using an Inductively Coupled Plasma Optical Emission Spectrometer (ICP OES). Our results showed a clear dependence of heavy metal accumulation in the mosses on the location of the exposition site and the exposure period. Both species of mosses were found to accumulate the most metals in the vicinity of pollutant emitters, such as the ArcelorMittal Warsaw smelter, exit roads or roads in the city with heavy traffic, petrol stations, or construction works. After 4 months of exposure, in both moss species, the highest increases in the concentrations were found for four elements: Cr, Pb, Ni and Cd. Higher concentrations of some heavy metals in the mosses in 2020, as compared to previous studies, indicate a negative influence of progressing urbanisation on air pollution in Warsaw.

The vegetation of rich fens (Sphagno warnstorfii-Tomentypnion nitentis) at the southeastern margins of their European range

Question: Rich fens of the Sphagno warnstorfii-Tomentypnion nitentis alliance require a specific combination of base richness and climate to occur. Their rarity at the southeastern margins of their European range has previously prevented rigorous vegetation classification. We asked how many associations may be delimited here and whether some of them are restricted to the high Balkan Mountains showing high endemicity. Study area: Entire territories of Bulgaria and Romania. Methods: We compiled all available vegetation-plot records, including some hitherto unprocessed data. We classified them by both divisive (modified TWINSPAN) and agglomerative (beta-flexible clustering) numerical classification method, with OPTIMCLASS1 applied to set the number of clusters. A semi-supervised approach (k-means) was additionally applied to confirm the classification of Southern-Carpathian (Romania) rich fens, where some Balkan taxa occur. Differences in base richness and elevation were tested by one-way ANOVA with Tukey’s pairwise test. Results: Three associations were delimited and all three occur in Bulgaria, from where only one association had been previously reported. Two associations characterised by Sphagnum contortum and Balkan and Southern-European species occur in Bulgaria, but not in Romania, one at lower elevations around 1,200 m, and one at higher elevations around 2,000 m where pH is lower. One lower-elevation (around 1,300 m) association with S. warnstorfii and S. teres is shared between Romania, Bulgaria and Central Europe. Conclusions: We have described a new high-mountain association, with two subassociations that differ by successional stage and dominant peat moss species (S. contortum and S. warnstorfii, respectively). These subassociations could be reconsidered when more data from other Balkan countries are available. Rich fens in southeastern Europe are rare, have a diverse vegetation, and are deserving of the further attention of nature conservation authorities and vegetation scientists. Taxonomic reference: The nomenclature was harmonized following The Euro+Med PlantBase (Euro+Med 2021) for vascular plants and Hill et al. (2006) for bryophytes, except of Angelica pancicii that is accepted as a separate taxon in Bulgaria (Andreev et al. 1992; Delipavlov et al. 2003). Critical taxa, not always reliably differentiated in the field and in literary sources, were merged to aggregates: Alchemilla vulgaris agg. (all Alchemilla species), Anthoxanthum odoratum agg. (A. alpinum, A. odoratum), Molinia caerulea agg. (M. arundinacea subsp. arundinacea, M. arundinacea subsp. freyi, M. caerulea), Palustriella commutata agg. (P. commutata, P. falcata), Plagiomnium affine agg. (P. affine, P. elatum, P. ellipticum), Sphagnum palustre agg. (S. centrale, S. palustre). Syntaxonomic reference: Peterka et al. (2017) for alliances.

Novel application of mosses transplanted in bags as biointerceptors of airborne radioactive dusts after the Fukushima Dai-ichi Nuclear Power Station accident

<p>Nine years after the Fukushima Dai-ichi Nuclear Power Plant accident, in line with the strong efforts to devise ever more effective methods to monitor airborne radioactive dusts, in the present study we proposed for the first time the use of mosses transplanted in bags as biointerceptors of <sup>134</sup>Cs and <sup>137</sup>Cs in the evacuated zone of the Fukushima territory and according to a standardised protocol. The work aimed to investigate the ability of the moss transplants to accumulate radiocaesium and therefore to act as radiocaesium biointerceptors. To this purpose, the activity concentrations of radiocaesium were measured in moss bags filled with 3 widely studied moss species (<em>Sphagnum palustre, Hypnum cupressiforme, Hypnum plumaeforme</em>) and exposed for 3, 6 and 9 weeks at 5 residential sites within Fukushima area. The levels of radiocaesium found in moss bags were evaluated as function of different parameters (e.g. exposure time, site conditions, moss species). The moss bags were able to accumulate <sup>137</sup>Cs in all exposure sites and periods, with <em>Sphagnum palustre</em> acting as the most performant moss species. The <sup>137</sup>Cs activity concentrations (from 28 to 4700 Bq kg<sup>-1</sup>), could be explained by the Cs deposition levels and decontamination status of each exposure site, highlighting the sensitivity of the moss bags to discriminate among exposure sites according to their contamination level. Autoradiography and electron microscopy analysis of the distribution and the chemical composition of the particles entrapped by moss surfaces revealed a prevalence soil-derived radiocaesium. The linear dependency of Cs accumulation with the exposure time allowed a radiocaesium quantitative assessment by using location-specific (LF) and species-specific (SF) factors, with the latter susceptible to an “universal” applicability in future biomonitoring studies with the same experimental design.</p>

Source Locality Effects on Restoration Potential in Sphagnum palustre L. from 3 Ohio Sites

Understanding whether propagules from different donor sources differ in their performance at a site may be important for restoration of many habitats. This study aimed at evaluating source effects in Sphagnum palustre L, a peatland moss species, for potential use in a restoration setting. Tamarack Bog, a remnant peatland in Bath Township, Ohio, is being restored. One goal is to increase Sphagnum coverage. This study focused on the dominant species of peat moss at the bog, S. palustre. To test for source effects, S. palustre and water samples were collected from 3 different locations (Mentor Marsh, Tamarack Bog, and Singer Lake) and used in 2 experiments. Plant performance was assessed by measuring growth in length and increase in mass. In the first experiment, a full factorial test was conducted: moss sampled from each location was grown directly in water collected from each location. In the second experiment—also a full factorial test—moss sampled from each location was separately grown on a uniform, commercially harvested, peat substrate and supplied with water collected from each location. In the design of both experiments, local adaptation would be indicated by better performance (both experiments measured length change and mass change, plus capitulum counts in the second experiment) for plants grown in their home water source than for plants grown in water from other sites. Ultimately, the study team did not observe evidence for local adaptation in these experiments. However, there were strong plant source effects in both experiments and some indication of differences in response to the water from different sources. Interpreting these results from a restoration standpoint, using donor plants from several source sites may improve the success of restoration.