Former land use affects the nitrogen and phosphorus concentrations and biomass of forest herbs

The colonization rates of understorey plants into forests growing on former agricultural land differ remarkably among species. Different dispersal and recruitment largely account for the contrasting colonization rates, but different effects of the soil legacies of former agricultural land use on plant performance may also play a role. Seven herbaceous forest species were sampled in paired post-agricultural and ancient forest stands to study whether land-use history has an effect on the aboveground nutrient concentrations (N, P and N:P ratios) and biomass of forest herbs and, if so, whether slow and fast colonizing species respond differently. Results showed that P concentrations were significantly affected by former land use with higher concentrations in the post-agricultural stands. N concentrations were unaffected and N:P ratios were significantly higher in the ancient stands. Nutrient concentrations varied considerably among species, but the variation was unrelated to their colonization capacity. Six out of the seven species had higher biomass in the post-agricultural stands relative to the ancient stands, and the degree to which the species increased biomass was positively related to their colonization capacity, i.e., the fast colonizing species showed the strongest increase. Such differential responses to past land use may contribute to the contrasting colonization capacity of forest plants. Land-use history thus affected both the nutrient concentrations and biomass of forest herbs, and only the biomass response was related to colonization capacity

Plant and soil microbe responses to light, warming and nitrogen addition in a temperate forest

1. Temperate forests across Europe and eastern North America have become denser since the 1950s due to less intensive forest management and global environmental changes such as nitrogen deposition and climate warming. Denser tree canopies result in lower light availability at the forest floor. This shade may buffer the effects of nitrogen deposition and climate warming on understorey plant communities. 2. We conducted an innovative in situ field experiment to study the responses of co-occurring soil microbial and understorey plant communities to nitrogen addition, enhanced light availability and experimental warming in a full-factorial design. 3. We determined the effects of multiple environmental drivers and their interactions on the soil microbial and understorey plant communities, and assessed to what extent the soil microbial and understorey plant communities covary. 4. High light led to lower biomass of the soil microbes (analysed by phospholipid fatty acids), but the soil microbial structure, i.e. the ratio of fungal biomass to bacterial biomass, was not affected by light availability. The composition of the soil bacterial community (analysed by high-throughput sequencing) was affected by both light availability and warming (and their interaction), but not by nitrogen addition. Yet, the number of unique operational taxonomic units was higher in plots with nitrogen addition, and there were significant interactive effects of light and nitrogen addition. Light availability also determined the composition of the plant community; no effects of nitrogen addition and warming were observed. The soil bacterial and plant communities were co-structured, and light availability explained a large part of the variance of this co-structure. 5. We provide robust evidence for the key role of light in affecting both the soil microbial and plant communities in forest understoreys. Our results advocate for more multifactor global change experiments that investigate the mechanism underlying the (in) direct effects of light on the plant-soil continuum in forests

Plasticity in response to phosphorus and light availability in four forest herbs

The differential ability of forest herbs to colonize secondary forests on former agricultural land is generally attributed to different rates of dispersal. After propagule arrival, however, establishing individuals still have to cope with abiotic soil legacies from former agricultural land use. We focused on the plastic responses of forest herbs to increased phosphorus availability, as phosphorus is commonly found to be persistently bioavailable in post-agricultural forest soils. In a pot experiment performed under field conditions, we applied three P levels to four forest herbs with contrasting colonization capacities: Anemone nemorosa, Primula elatior, Circaea lutetiana and Geum urbanum. To test interactions with light availability, half of the replicas were covered with shade cloths. After two growing seasons, we measured aboveground P uptake as well as vegetative and regenerative performance. We hypothesized that fast-colonizing species respond the most opportunistically to increased P availability, and that a low light availability can mask the effects of P on performance. All species showed a significant increase in P uptake in the aboveground biomass. The addition of P had a positive effect on the vegetative performances of two of the species, although this was unrelated to their colonization capacities. The regenerative performance was affected by light availability (not by P addition) and was related to the species' phenology. Forest herbs can obviously benefit from the increased availability of P in post-agricultural forests, but not all species respond in the same way. Such differential patterns of plasticity may be important in community dynamics, as they affect the interactions among species

Effects of mineral soil and forest floor on the regeneration of pedunculate oak, beech and red oak

Early regeneration is a critical life stage that affects the future species composition of forests. Knowledge about regeneration success under different environmental conditions allows better understanding of forest dynamics. We studied the effects of seedbed conditions on the establishment and performance of seedlings of pedunculate oak, beech and red oak. In 50 plots of a tree-diversity oriented research platform in mature forests in northern Belgium (TREEWEB), we installed a field experiment with three treatments (potting soil, mineral soil, mineral soil + forest floor), in which we sowed seeds of each species. We monitored early establishment and survival, height, root and shoot biomass of the seedlings after two growing seasons. Mineral soil negatively affected seedling establishment and performance relative to the potting soil. The negative soil effects did not vary with measured abiotic soil properties. In general, the forest floor did not deteriorate or mitigate the soil effects, and only for root biomass did the forest floor partly compensate the negative soil effects. Forest floor effects did not vary with the measured forest floor properties. In the studied forests, creating bare soil was not enough to promote regeneration; improving soil properties might be important for the success of natural regeneration.Fil: De Groote, Stefanie R. E.. University of Ghent; BélgicaFil: Vanhellemont, Margot. University of Ghent; BélgicaFil: Baeten, Lander. University of Ghent; BélgicaFil: Carón, María Mercedes. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Córdoba. Instituto Multidisciplinario de Biología Vegetal. Universidad Nacional de Córdoba. Facultad de Ciencias Exactas Físicas y Naturales. Instituto Multidisciplinario de Biología Vegetal; Argentina. Universidad Nacional de Salta; ArgentinaFil: Martel, An. University of Ghent; BélgicaFil: Bonte, Dries. University of Ghent; BélgicaFil: Lens, Luc. University of Ghent; BélgicaFil: Verheyen, Kris. University of Ghent; Bélgic

Contributions of a global network of tree diversity experiments to sustainable forest plantations

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Present and future population dynamics of Prunus serotina in forests in its introduced range

Prunus serotina, a North American tree species, is considered one of the 100 worst invaders in Europe. Although an increasing number of studies has focused on P. serotina in Europe, several aspects of the species have remained unstudied. Moreover, most studies focused on heavily invaded areas. We wanted to gain insight into the radial growth and the spatiotemporal variation in the regeneration of P. serotina in forest understories, the patterns of long-term spontaneous P. serotina colonization in areas where the species had not been introduced intentionally, and long-term forest development with P. serotina. Prunus serotina growth and regeneration were studied in seven Pinus sylvestris stands in Flanders. Growth was reduced by 50 % compared to growth in full light conditions and was related to tree age and diameter and competition with neighbouring trees. The seedling bank with high densities of seedlings smaller than 20 cm and up to 6 years old stabilized the erratic early regeneration of P. serotina. We also reconstructed the P. serotina invasion for a pine forest in the Netherlands and a deciduous forest in Flanders that had not been managed for over 60 years and were located in areas with an initially low propagule pressure of P. serotina. Long-distance dispersal events and windows of opportunity triggered the P. serotina invasion. Further colonization was directed by connectivity to seed sources and light availability. The presence of native shrub species, dense herb layers, and quick canopy closure seemed to hamper further P. serotina establishment while high herbivore densities may have favoured P. serotina over native species such as Quercus robur. We used the model SORTIE-ND to simulate 500 years of forest development for a pine forest with P. serotina. The output suggested that if Q. robur was able to regenerate, the longer lifespan of Q. robur may enable the species to become dominant over P. serotina. With this thesis, we demonstrated that the invasiveness of a species depends on the characteristics of the invaded ecosystem and that models of forest development such as SORTIE-ND can be useful to simulate the future role of invasive tree species in forests