Fungal succession in the needle litter of a montane Picea abies forest investigated through strain isolation and molecular fingerprinting

Precise knowledge of the fungal succession in the litter of coniferous forests will facilitate understanding litter decomposition, in which fungi play a major role. We investigated the development of a fungal community during 3 yr of Picea abies litter decomposition in three control forest sites and three sites where bark-beetle attacks had killed adult trees and stopped the yearly input of fresh litter, using both cultivation from needles and terminal restriction-fragment length polymorphism analysis. The two methods revealed similar dominant species during the fungal succession. Members of the Dothideales, Eurotiales and Helotiales predominated during the initial stage of decay, whereas members of Agaricales appeared only occasionally during this stage. The onset of the latter began from the seventh month, with a peak occurring after 1 yr. Bark-beetle attacks hastened litter decomposition and decreased fungal diversity only during the initial stages of decomposition.     

The red alga Bonnemaisonia asparagoides regulates epiphytic bacterial abundance and community composition by chemical defence

Ecological research on algal-derived metabolites with antimicrobial activity has recently received increased attention and is no longer only aimed at identifying novel natural compounds with potential use in applied perspectives. Despite this progress, few studies have so far demonstrated ecologically relevant antimicrobial roles of algal metabolites, and even fewer have utilized molecular tools to investigate the effects of these metabolites on the natural community composition of bacteria. In this study, we investigated whether the red alga Bonnemaisonia asparagoides is chemically defended against bacterial colonization of its surface by extracting surface-associated secondary metabolites and testing their antibacterial effects. Furthermore, we compared the associated bacterial abundance and community composition between B. asparagoides and two coexisting macroalgae. Surface extracts tested at natural concentrations had broad-spectrum effects on the growth of ecologically relevant bacteria, and consistent with this antibacterial activity, natural populations of B. asparagoides had significantly lower densities of epibacteria compared with the coexisting algae. Terminal restriction fragment length polymorphism analysis further showed that B. asparagoides harboured surface-associated bacteria with a community composition that was significantly different from those on coexisting macroalgae. Altogether, these findings demonstrate that B. asparagoides produces surface-bound antibacterial compounds with a significant impact on the abundance and composition of the associated bacterial community.