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3. Using Spectral Indices Derived from Remote Sensing Imagery to Represent Arthropod Biodiversity Gradients in a European Sphagnum Peat Bog.

Author

Minor, Maria A., Ermilov, Sergey G., Joharchi, Omid, and Philippov, Dmitriy A.

Subjects
PEAT bogs, REMOTE sensing, SOIL mites, LANDSAT satellites, WATER table
Abstract

Monitoring of peatlands is an important conservation issue. We investigated communities of soil mites (Acari: Oribatida, Mesostigmata) inhabiting a relatively undisturbed European boreal mire characterized by a mosaic of oligotrophic and meso-eutrophic areas. We assess the potential of using remote sensing approach as a mapping and predictive tool for monitoring productivity and arthropod biodiversity in a peat bog. In georeferenced plots, Acari biodiversity, water table level, water pH and plot productivity class on the oligotrophic-eutrophic gradient were recorded. Data from the Landsat 8 OLI sensor were used to calculate several spectral indices known to represent productivity and surface moisture gradients in terrestrial ecosystems. We then explored the relationship between spectral indices, environmental gradients and biodiversity of mites. We found that several spectral indices were significantly and consistently correlated with local environmental variables and biodiversity of soil mites. The Excess Green Index performed best as a predictor of plot trophic class on the oligotrophic-eutrophic gradient and showed significant relationship with Oribatida diversity in 2016. However, following hot summer in 2019, there was no significant relationship between abundance and species richness of Oribatida and remotely sensed data; there was a weak correlation between abundance of Mesostigmata and spectral indices which represent surface moisture gradient (e.g., Normalised Difference Moisture Index). We discuss advantages and challenges of using spectral indices derived from remote sensing imagery to map biodiversity gradients in a peatland. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Figure 4 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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5. Figure 3 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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6. Figure 2 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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7. Figure 14 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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8. Figure 6 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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9. Figure 5 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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10. Figure 9 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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11. Figure 8 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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12. Figure 7 from: Philippov DA, Ivicheva KN, Makarenkova NN, Filonenko IV, Komarova AS (2022) Biodiversity of macrophyte communities and associated aquatic organisms in lakes of the Vologda Region (north-western Russia). Biodiversity Data Journal 10: e77626. https://doi.org/10.3897/BDJ.10.e77626

Author

Philippov, Dmitriy, primary, Ivicheva, Ksenya, additional, Makarenkova, Nadezhda, additional, Filonenko, Igor, additional, and Komarova, Aleksandra, additional

Published
2022
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24. Figure 5 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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25. Figure 4 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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26. Figure 7 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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27. Figure 8 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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28. Figure 2 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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29. Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia)

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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30. Figure 12 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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31. Figure 9 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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32. Figure 6 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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33. Figure 3 from: Philippov DA, Ermilov SG, Zaytseva VL, Pestov SV, Kuzmin EA, Shabalina JN, Sazhnev AS, Ivicheva KN, Sterlyagova IN, Leonov MM, Boychuk MA, Czhobadze AB, Prokina KI, Dulin MV, Joharchi O, Shabunov AA, Shiryaeva OS, Levashov AN, Komarova AS, Yurchenko VV (2021) Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, north-western Russia). Biodiversity Data Journal 9: e77615. https://doi.org/10.3897/BDJ.9.e77615

Author

Philippov, Dmitriy, primary, Ermilov, Sergey, additional, Zaytseva, Vera, additional, Pestov, Sergey, additional, Kuzmin, Eugeniy, additional, Shabalina, Julia, additional, Sazhnev, Alexey, additional, Ivicheva, Ksenya, additional, Sterlyagova, Irina, additional, Leonov, Mikhail, additional, Boychuk, Margarita, additional, Czhobadze, Andrey, additional, Prokina, Kristina, additional, Dulin, Mikhail, additional, Joharchi, Omid, additional, Shabunov, Aleksey, additional, Shiryaeva, Olga, additional, Levashov, Andrey, additional, Komarova, Aleksandra, additional, and Yurchenko, Victoria, additional

Published
2021
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34. Environmental drivers of Sphagnum growth in peatlands across the Holarctic region

Author

Bengtsson, Fia, Rydin, Hakan, Baltzer, Jennifer L., Bragazza, Luca, Bu, Zhao-Jun, Caporn, Simon J. M., Dorrepaal, Ellen, Flatberg, Kjell Ivar, Galanina, Olga, Galka, Mariusz, Ganeva, Anna, Goia, Irina, Goncharova, Nadezhda, Hajek, Michal, Haraguchi, Akira, Harris, Lorna I., Humphreys, Elyn, Jirousek, Martin, Kajukalo, Katarzyna, Karofeld, Edgar, Koronatova, Natalia G., Kosykh, Natalia P., Laine, Anna M., Lamentowicz, Mariusz, Lapshina, Elena, Limpens, Juul, Linkosalmi, Maiju, Ma, Jin-Ze, Mauritz, Marguerite, Mitchell, Edward A. D., Munir, Tariq M., Natali, Susan M., Natcheva, Rayna, Payne, Richard J., Philippov, Dmitriy A., Rice, Steven K., Robinson, Sean, Robroek, Bjorn J. M., Rochefort, Line, Singer, David, Stenoien, Hans K., Tuittila, Eeva-Stiina, Vellak, Kai, Waddington, James Michael, Granath, Gustaf, Bengtsson, Fia, Rydin, Hakan, Baltzer, Jennifer L., Bragazza, Luca, Bu, Zhao-Jun, Caporn, Simon J. M., Dorrepaal, Ellen, Flatberg, Kjell Ivar, Galanina, Olga, Galka, Mariusz, Ganeva, Anna, Goia, Irina, Goncharova, Nadezhda, Hajek, Michal, Haraguchi, Akira, Harris, Lorna I., Humphreys, Elyn, Jirousek, Martin, Kajukalo, Katarzyna, Karofeld, Edgar, Koronatova, Natalia G., Kosykh, Natalia P., Laine, Anna M., Lamentowicz, Mariusz, Lapshina, Elena, Limpens, Juul, Linkosalmi, Maiju, Ma, Jin-Ze, Mauritz, Marguerite, Mitchell, Edward A. D., Munir, Tariq M., Natali, Susan M., Natcheva, Rayna, Payne, Richard J., Philippov, Dmitriy A., Rice, Steven K., Robinson, Sean, Robroek, Bjorn J. M., Rochefort, Line, Singer, David, Stenoien, Hans K., Tuittila, Eeva-Stiina, Vellak, Kai, Waddington, James Michael, and Granath, Gustaf

Abstract

The relative importance of global versus local environmental factors for growth and thus carbon uptake of the bryophyte genusSphagnum-the main peat-former and ecosystem engineer in northern peatlands-remains unclear. We measured length growth and net primary production (NPP) of two abundantSphagnumspecies across 99 Holarctic peatlands. We tested the importance of previously proposed abiotic and biotic drivers for peatland carbon uptake (climate, N deposition, water table depth and vascular plant cover) on these two responses. Employing structural equation models (SEMs), we explored both indirect and direct effects of drivers onSphagnumgrowth. Variation in growth was large, but similar within and between peatlands. Length growth showed a stronger response to predictors than NPP. Moreover, the smaller and denserSphagnum fuscumgrowing on hummocks had weaker responses to climatic variation than the larger and looserSphagnum magellanicumgrowing in the wetter conditions. Growth decreased with increasing vascular plant cover within a site. Between sites, precipitation and temperature increased growth forS. magellanicum. The SEMs indicate that indirect effects are important. For example, vascular plant cover increased with a deeper water table, increased nitrogen deposition, precipitation and temperature. These factors also influencedSphagnumgrowth indirectly by affecting moss shoot density. Synthesis. Our results imply that in a warmer climate,S. magellanicumwill increase length growth as long as precipitation is not reduced, whileS. fuscumis more resistant to decreased precipitation, but also less able to take advantage of increased precipitation and temperature. Such species-specific sensitivity to climate may affect competitive outcomes in a changing environment, and potentially the future carbon sink function of peatlands.

Published
2021
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35. Environmental drivers of Sphagnum growth in peatlands across the Holarctic region

Author

Bengtsson, Fia, Rydin, Håkan, Baltzer, Jennifer L., Bragazza, Luca, Bu, Zhao Jun, Caporn, Simon J.M., Dorrepaal, Ellen, Flatberg, Kjell Ivar, Galanina, Olga, Gałka, Mariusz, Ganeva, Anna, Goia, Irina, Goncharova, Nadezhda, Hájek, Michal, Haraguchi, Akira, Harris, Lorna I., Humphreys, Elyn, Jiroušek, Martin, Kajukało, Katarzyna, Karofeld, Edgar, Koronatova, Natalia G., Kosykh, Natalia P., Laine, Anna M., Lamentowicz, Mariusz, Lapshina, Elena, Limpens, Juul, Linkosalmi, Maiju, Ma, Jin Ze, Mauritz, Marguerite, Mitchell, Edward A.D., Munir, Tariq M., Natali, Susan M., Natcheva, Rayna, Philippov, Dmitriy A., Rice, Steven K., Robinson, Sean, Robroek, Bjorn J.M., Rochefort, Line, Singer, David, Stenøien, Hans K., Tuittila, Eeva Stiina, Vellak, Kai, Waddington, James Michael, Granath, Gustaf, Payne, Richard J., Bengtsson, Fia, Rydin, Håkan, Baltzer, Jennifer L., Bragazza, Luca, Bu, Zhao Jun, Caporn, Simon J.M., Dorrepaal, Ellen, Flatberg, Kjell Ivar, Galanina, Olga, Gałka, Mariusz, Ganeva, Anna, Goia, Irina, Goncharova, Nadezhda, Hájek, Michal, Haraguchi, Akira, Harris, Lorna I., Humphreys, Elyn, Jiroušek, Martin, Kajukało, Katarzyna, Karofeld, Edgar, Koronatova, Natalia G., Kosykh, Natalia P., Laine, Anna M., Lamentowicz, Mariusz, Lapshina, Elena, Limpens, Juul, Linkosalmi, Maiju, Ma, Jin Ze, Mauritz, Marguerite, Mitchell, Edward A.D., Munir, Tariq M., Natali, Susan M., Natcheva, Rayna, Philippov, Dmitriy A., Rice, Steven K., Robinson, Sean, Robroek, Bjorn J.M., Rochefort, Line, Singer, David, Stenøien, Hans K., Tuittila, Eeva Stiina, Vellak, Kai, Waddington, James Michael, Granath, Gustaf, and Payne, Richard J.

Abstract

The relative importance of global versus local environmental factors for growth and thus carbon uptake of the bryophyte genus Sphagnum – the main peat-former and ecosystem engineer in northern peatlands – remains unclear. 2) We measured length growth and net primary production (NPP) of two abundant Sphagnum species across 99 Holarctic peatlands. We tested the importance of previously proposed abiotic and biotic drivers for peatland carbon uptake (climate, N deposition, water table depth, and vascular plant cover) on these two responses. Employing structural equation models, we explored both indirect and direct effects of drivers on Sphagnum growth. 3) Variation in growth was large, but similar within and between peatlands. Length growth showed a stronger response to predictors than NPP. Moreover, the smaller and denser Sphagnum fuscum growing on hummocks had weaker responses to climatic variation than the larger and looser S. magellanicum growing in the wetter conditions. Growth decreased with increasing vascular plant cover within a site. Between sites, precipitation and temperature increased growth for S. magellanicum. The structural equation models indicated that indirect effects are important. For example, vascular plant cover increased with a deeper water table, increased nitrogen deposition, precipitation and temperature. These factors also influenced Sphagnum growth indirectly by affecting moss shoot density. 4) Synthesis Our results imply that in a warmer climate, S. magellanicum will increase length growth as long as precipitation is not reduced, while S. fuscum is more resistant to decreased precipitation, but also less able to take advantage of increased precipitation and temperature. Such species-specific sensitivity to climate may affect competitive outcomes in a changing environment, and potentially the future carbon sink function of peatlands., The relative importance of global versus local environmental factors for growth and thus carbon uptake of the bryophyte genus Sphagnum – the main peat-former and ecosystem engineer in northern peatlands – remains unclear. 2) We measured length growth and net primary production (NPP) of two abundant Sphagnum species across 99 Holarctic peatlands. We tested the importance of previously proposed abiotic and biotic drivers for peatland carbon uptake (climate, N deposition, water table depth, and vascular plant cover) on these two responses. Employing structural equation models, we explored both indirect and direct effects of drivers on Sphagnum growth. 3) Variation in growth was large, but similar within and between peatlands. Length growth showed a stronger response to predictors than NPP. Moreover, the smaller and denser Sphagnum fuscum growing on hummocks had weaker responses to climatic variation than the larger and looser S. magellanicum growing in the wetter conditions. Growth decreased with increasing vascular plant cover within a site. Between sites, precipitation and temperature increased growth for S. magellanicum. The structural equation models indicated that indirect effects are important. For example, vascular plant cover increased with a deeper water table, increased nitrogen deposition, precipitation and temperature. These factors also influenced Sphagnum growth indirectly by affecting moss shoot density. 4) Synthesis Our results imply that in a warmer climate, S. magellanicum will increase length growth as long as precipitation is not reduced, while S. fuscum is more resistant to decreased precipitation, but also less able to take advantage of increased precipitation and temperature. Such species-specific sensitivity to climate may affect competitive outcomes in a changing environment, and potentially the future carbon sink function of peatlands.

Published
2020

37. Wide distribution of Phycisphaera ‐like planctomycetes from WD2101 soil group in peatlands and genome analysis of the first cultivated representative

Author

Dedysh, Svetlana N., primary, Beletsky, Alexey V., additional, Ivanova, Anastasia A., additional, Kulichevskaya, Irina S., additional, Suzina, Natalia E., additional, Philippov, Dmitriy A., additional, Rakitin, Andrey L., additional, Mardanov, Andrey V., additional, and Ravin, Nikolai V., additional

Published
2020
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38. Environmental drivers of Sphagnum growth in peatlands across the Holarctic region

Author

Bengtsson, Fia, primary, Rydin, Håkan, additional, Baltzer, Jennifer L., additional, Bragazza, Luca, additional, Bu, Zhao‐Jun, additional, Caporn, Simon J. M., additional, Dorrepaal, Ellen, additional, Flatberg, Kjell Ivar, additional, Galanina, Olga, additional, Gałka, Mariusz, additional, Ganeva, Anna, additional, Goia, Irina, additional, Goncharova, Nadezhda, additional, Hájek, Michal, additional, Haraguchi, Akira, additional, Harris, Lorna I., additional, Humphreys, Elyn, additional, Jiroušek, Martin, additional, Kajukało, Katarzyna, additional, Karofeld, Edgar, additional, Koronatova, Natalia G., additional, Kosykh, Natalia P., additional, Laine, Anna M., additional, Lamentowicz, Mariusz, additional, Lapshina, Elena, additional, Limpens, Juul, additional, Linkosalmi, Maiju, additional, Ma, Jin‐Ze, additional, Mauritz, Marguerite, additional, Mitchell, Edward A. D., additional, Munir, Tariq M., additional, Natali, Susan M., additional, Natcheva, Rayna, additional, Payne, Richard J., additional, Philippov, Dmitriy A., additional, Rice, Steven K., additional, Robinson, Sean, additional, Robroek, Bjorn J. M., additional, Rochefort, Line, additional, Singer, David, additional, Stenøien, Hans K., additional, Tuittila, Eeva‐Stiina, additional, Vellak, Kai, additional, Waddington, James Michael, additional, and Granath, Gustaf, additional

Published
2020
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41. Limnoglobus roseus gen. nov., sp. nov., a novel freshwater planctomycete with a giant genome from the family Gemmataceae

Author

Kulichevskaya, Irina S., primary, Naumoff, Daniil G., additional, Miroshnikov, Kirill K., additional, Ivanova, Anastasia A., additional, Philippov, Dmitriy A., additional, Hakobyan, Anna, additional, Rijpstra, W. Irene C., additional, Damsté, Jaap S. Sinninghe, additional, Liesack, Werner, additional, and Dedysh, Svetlana N., additional

Published
2020
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42. Biodiversity of a boreal mire, including its hydrographic network (Shichengskoe mire, northwestern Russia).

Author

Philippov, Dmitriy A., Ermilov, Sergey G., Zaytseva, Vera L., Pestov, Sergey V., Kuzmin, Eugeniy A., Shabalina, Julia N., Sazhnev, Alexey S., Ivicheva, Ksenya N., Sterlyagova, Irina N., Leonov, Mikhail M., Boychuk, Margarita A., Czhobadze, Andrey B., Prokina, Kristina I., Dulin, Mikhail V., Joharchi, Omid, Shabunov, Aleksey A., Shiryaeva, Olga S., Levashov, Andrey N., Komarova, Aleksandra S., and Yurchenko, Victoria V.

Subjects
SPECIES diversity, SPECIES distribution, INVERTEBRATES, WETLANDS, PEAT mosses
Abstract

Background The paper is based on the dataset whose purpose was to deliver, in the form of GBIFmediated data, diverse materials on the biodiversity of a large mire, Shichengskoe mire (Vologda Region, north-western Russia), including its various mire sites and intra-mire water bodies. The dataset was based on our materials collected for two decades (from 2000 to 2021) in different parts and biotopes of the Shichengskoe mire and complemented by scarce data obtained previously by other researchers. The data contain materials on the diversity of Animalia (2886 occurrences), Bacteria (22), Chromista (256), Fungi (111), Plantae (2463) and Protozoa (131). Within the study period, the most detailed and longterm biodiversity studies were carried out for higher plants and invertebrates. On the other hand, the data on the composition of lichens, protozoa, algae, basidiomycetes, some groups of invertebrates and, to a lesser extent, lichens and vertebrates are far less comprehensive and require further substantial research efforts. The list includes occurrences from both the peatland (mire sites and mire margins different in typology) and the objects of the mire hydrographic network. In a standardised form, this article summarises both already published (mainly in Russian) and unpublished materials. New information The paper summarises the results of long-term research on the biodiversity of a boreal mire, including its hydrographic network. A total of 5869 occurrences were included in the dataset published in the Global Biodiversity Information Facility (GBIF, gbif.org) for the first time. According to the GBIF taxonomic backbone, the dataset covers 1358 taxa, including 1250 lower-rank taxa (species, subspecies, varieties, forms) and 108 taxa identified to the genus level. Several species found in the Shichengskoe mire, mainly belonging to Bacteria, Chromista and Protozoa, have never been listed in GBIF for the territory of Russia before. The overwhelming majority of occurrences and identified species came from the territory of Shichengskiy Landscape Reserve. Due to our work, this Reserve is now the most studied regional reserve in the Vologda Region with respect to biodiversity. By the number of revealed species, it is close to two federal protected areas: Darwinskiy State Nature Biospheric Reserve and National Park "Russkiy Sever". [ABSTRACT FROM AUTHOR]

Published
2021
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47. Wide distribution of Phycisphaera‐like planctomycetes from WD2101 soil group in peatlands and genome analysis of the first cultivated representative.

Author

Dedysh, Svetlana N., Beletsky, Alexey V., Ivanova, Anastasia A., Kulichevskaya, Irina S., Suzina, Natalia E., Philippov, Dmitriy A., Rakitin, Andrey L., Mardanov, Andrey V., and Ravin, Nikolai V.

Subjects
PEATLANDS, PEAT bogs, MOUNTAIN soils, GENES, GENOMES, SOILS
Abstract

Summary: Phycisphaera‐like WD2101 'soil group' is one of the as‐yet‐uncultivated phylogenetic clades within the phylum Planctomycetes. Members of this clade are commonly detected in various terrestrial habitats. This study shows that WD2101 represented one of the major planctomycete groups in 10 boreal peatlands, comprising up to 76% and 36% of all Planctomycetes‐affiliated 16S rRNA gene reads in raised bogs and eutrophic fens respectively. These types of peatlands displayed clearly distinct intra‐group diversity of WD2101‐affiliated planctomycetes. The first isolate of this enigmatic planctomycete group, strain M1803, was obtained from a humic lake surrounded by Sphagnum peat bogs. Strain M1803 displayed 89.2% 16S rRNA gene similarity to Tepidisphaera mucosa and was represented by motile cocci that divided by binary fission and grew under micro‐oxic conditions. The complete 7.19 Mb genome of strain M1803 contained an array of genes encoding Planctomycetal type bacterial microcompartment organelle likely involved in l‐rhamnose metabolism, suggesting participation of M1803‐like planctomycetes in polysaccharide degradation in peatlands. The corresponding cellular microcompartments were revealed in ultrathin cell sections. Strain M1803 was classified as a novel genus and species, Humisphaera borealis gen. nov., sp. nov., affiliated with the formerly recognized WD2101 'soil group'. [ABSTRACT FROM AUTHOR]

Published
2021
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48. 100‐year‐old enigma solved: identification, genomic characterization and biogeography of the yet uncultured Planctomyces bekefii.

Author

Dedysh, Svetlana N., Henke, Petra, Ivanova, Anastasia A., Kulichevskaya, Irina S., Philippov, Dmitriy A., Meier‐Kolthoff, Jan P., Göker, Markus, Huang, Sixing, and Overmann, Jörg

Subjects
CYANOBACTERIAL toxins, FLUORESCENCE in situ hybridization, LAKES, CYANOBACTERIAL blooms, FRESHWATER habitats, BIOGEOGRAPHY, IN situ hybridization
Abstract

Summary: The first representative of the phylum Planctomycetes, Planctomyces bekefii, was described nearly one century ago. This morphologically conspicuous freshwater bacterium is a rare example of as‐yet‐uncultivated prokaryotes with validly published names and unknown identity. We report the results of molecular identification of this elusive bacterium, which was detected in a eutrophic boreal lake in Northern Russia. By using high‐performance cell sorting, P. bekefii‐like cell rosettes were selectively enriched from lake water. The retrieved 16S rRNA gene sequence was nearly identical to those in dozens of metagenomes assembled from freshwater lakes during cyanobacterial blooms and was phylogenetically placed within a large group of environmental sequences originating from various freshwater habitats worldwide. In contrast, 16S rRNA gene sequence similarity to all currently described members of the order Planctomycetales was only 83%–92%. The metagenome assembled for P. bekefii reached 43% genome coverage and showed the potential for degradation of peptides, pectins, and sulfated polysaccharides. Tracing the seasonal dynamics of P. bekefii by Illumina paired‐end sequencing of 16S rRNA gene fragments and by fluorescence in situ hybridization revealed that these bacteria only transiently surpass the detection limit, with a characteristic population peak of up to 104 cells ml−1 following cyanobacterial blooms. [ABSTRACT FROM AUTHOR]

Published
2020
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