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<p>Since the Last Glacial Maximum (LGM; end ca. 19&thinsp;000&thinsp;cal&thinsp;BP) central European plant communities have been shaped by changing climatic and anthropogenic disturbances. Understanding long-term ecosystem reorganizations in response to past environmental changes is crucial to draw conclusions about the impact of future climate change. So far, it has been difficult to address the post-deglaciation timing and ecosystem dynamics due to a lack of well-dated and continuous sediment sequences covering the entire period after the LGM. Here, we present a new paleoecological study with exceptional chronological time control using pollen, spores and microscopic charcoal from Moossee (Swiss Plateau, 521&thinsp;m&thinsp;a.s.l.) to reconstruct the vegetation and fire history over the last ca. 19&thinsp;000 years. After lake formation in response to deglaciation, five major pollen-inferred ecosystem rearrangements occurred at ca. 18&thinsp;800&thinsp;cal&thinsp;BP (establishment of steppe tundra), 16&thinsp;000&thinsp;cal&thinsp;BP (spread of shrub tundra), 14&thinsp;600&thinsp;cal&thinsp;BP (expansion of boreal forests), 11&thinsp;600&thinsp;cal&thinsp;BP (establishment of the first temperate deciduous tree stands composed of, e.g., <i>Quercus, Ulmus, Alnus</i>) and 8200&thinsp;cal&thinsp;BP (first occurrence of mesophilous <i>Fagus sylvatica</i> trees). These vegetation shifts were caused by climate changes at ca. 19&thinsp;000, 16&thinsp;000, 14&thinsp;700, 11&thinsp;700 and 8200&thinsp;cal&thinsp;BP. Vegetation responses occurred with no apparent time lag to climate change when the mutual chronological uncertainties are considered. This finding is in agreement with further evidence from southern and central Europe and might be explained by the proximity to the refugia of boreal and temperate trees (<span class="inline-formula">&lt;400</span>&thinsp;km) and rapid species spreads. Our palynological record sets the beginning of millennial-scale land use with periodically increased fire and agricultural activities of the Neolithic period at ca. 7000&thinsp;cal&thinsp;BP. Subsequently, humans rather than climate triggered changes in vegetation composition and structure. We conclude that <i>Fagus sylvatica</i> forests were resilient to long-term anthropogenic and climatic impacts of the Mid and the Late Holocene. However, future climate warming and in particular declining moisture availability may cause unprecedented reorganizations of central European beech-dominated forest ecosystems.</p>