TY - JOUR
T1 - Insights into the evolution of the young Lake Ohrid ecosystem and vegetation succession from a southern European refugium during the Early Pleistocene
AU - Panagiotopoulos, Konstantinos
AU - Holtvoeth, Jens
AU - Kouli, Katerina
AU - Marinova, Elena
AU - Francke, Alexander
AU - Cvetkoska, Aleksandra
AU - Jovanovska, Elena
AU - Lacey, Jack H.
AU - Lyons, Emma T.
AU - Buckel, Connie
AU - Bertini, Adele
AU - Donders, Timme
AU - Just, Janna
AU - Leicher, Niklas
AU - Leng, Melanie J.
AU - Melles, Martin
AU - Pancost, Richard D.
AU - Sadori, Laura
AU - Tauber, Paul
AU - Vogel, Hendrik
AU - Wagner, Bernd
AU - Wilke, Thomas
PY - 2020/1/1
Y1 - 2020/1/1
N2 - Mediterranean mid-altitude sites are critical for the survival of plant species allowing for elevational vegetation shifts in response to high-amplitude climate variability. Pollen records from the southern Balkans have underlined the importance of the region in preserving plant diversity over at least the last half a million years. So far, there are no records of vegetation and climate dynamics from Balkan refugia with an Early Pleistocene age. Here we present a unique palynological archive from such a refugium, the Lake Ohrid basin, recording continuously floristic diversity and vegetation succession under obliquity-paced climate oscillations. Palynological data are complemented by biomarker, diatom, carbonate isotope and sedimentological data to identify the mechanisms controlling shifts in the aquatic and terrestrial ecosystems within the lake and its catchment. The study interval encompasses four complete glacial-interglacial cycles (1365–1165 ka; MIS 43–35). Within the first 100 kyr of lake ontogeny, lake size and depth increase before the lake system enters a new equilibrium state as observed in a distinct shift in biotic communities and sediment composition. Several relict tree genera such as Cedrus, Tsuga, Carya, and Pterocarya played an important role in ecological succession cycles, while total relict abundance accounts for up to half of the total arboreal vegetation. The most prominent biome during interglacials is cool mixed evergreen needleleaf and deciduous broadleaf forests, while cool evergreen needleleaf forests dominate within glacials. A rather forested landscape with a remarkable plant diversity provide unique insights into Early Pleistocene ecosystem resilience and vegetation dynamics.
AB - Mediterranean mid-altitude sites are critical for the survival of plant species allowing for elevational vegetation shifts in response to high-amplitude climate variability. Pollen records from the southern Balkans have underlined the importance of the region in preserving plant diversity over at least the last half a million years. So far, there are no records of vegetation and climate dynamics from Balkan refugia with an Early Pleistocene age. Here we present a unique palynological archive from such a refugium, the Lake Ohrid basin, recording continuously floristic diversity and vegetation succession under obliquity-paced climate oscillations. Palynological data are complemented by biomarker, diatom, carbonate isotope and sedimentological data to identify the mechanisms controlling shifts in the aquatic and terrestrial ecosystems within the lake and its catchment. The study interval encompasses four complete glacial-interglacial cycles (1365–1165 ka; MIS 43–35). Within the first 100 kyr of lake ontogeny, lake size and depth increase before the lake system enters a new equilibrium state as observed in a distinct shift in biotic communities and sediment composition. Several relict tree genera such as Cedrus, Tsuga, Carya, and Pterocarya played an important role in ecological succession cycles, while total relict abundance accounts for up to half of the total arboreal vegetation. The most prominent biome during interglacials is cool mixed evergreen needleleaf and deciduous broadleaf forests, while cool evergreen needleleaf forests dominate within glacials. A rather forested landscape with a remarkable plant diversity provide unique insights into Early Pleistocene ecosystem resilience and vegetation dynamics.
KW - Diatoms
KW - Lipid biomarkers
KW - Mediterranean region
KW - Microscopic charcoal
KW - Mid-altitude refugium
KW - Palynological richness
KW - Pollen-based biome reconstruction
KW - Relicts
KW - Stable isotopes
KW - Vegetation succession
UR - http://www.scopus.com/inward/record.url?scp=85075153203&partnerID=8YFLogxK
U2 - 10.1016/j.quascirev.2019.106044
DO - 10.1016/j.quascirev.2019.106044
M3 - Article
AN - SCOPUS:85075153203
SN - 0277-3791
VL - 227
JO - Quaternary Science Reviews
JF - Quaternary Science Reviews
M1 - 106044
ER -