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Flechten gehören zu den herausragenden Indikatorgruppen für Veränderungen in Wäldern. Im Rahmen des Forschungsprojektes „Biodiversität und Klima“ (BIOKLIM) wurden im Jahr 2007 im Nationalpark Bayerischer Wald entlang von 4 Forschungslinien 125 baumbewohnende Flechten, 5 lichenicole Pilze sowie 1 nicht lichenisierter Ascomycet festgestellt. Alte Wälder und Prozessschutzwälder wiesen dabei signifikant die größte Artendiversität und die höchste Anzahl an bedrohten Arten im Vergleich mit den noch gemanagten Wäldern auf. Die herausragende Bedeutung von alten Wäldern und Prozessschutzflächen für den Erhalt und die Ausbreitung gefährdeter Flechten und lichenicoler Pilze für den ostbayerischen Mittelgebirgsraum wird dargestellt. Die sehr seltenen und hochgradig gefährdeten lichenicolen Pilze Chaenothecopsis viridialba, Sphinctrina anglica und Sphinctrina turbinata und die Flechte Mycobilimbia sphaeroides werden als Neufunde für den Bayerischen Wald genannt. Der in der Bundesrepublik Deutschland als verschollen geltende Flechtenpilz Sphinctrina tubiformis wurde im „Rachelseeurwald“ wiederentdeckt. Für alte naturnahe Wälder des Bayerischen und Böhmischen Waldes werden folgende Zeigerarten beschrieben: Lecanactis abietina, Pyrenula nitida, Micarea cinerea, Microcalicium disseminatum, Loxospora cismonica und Thelotrema lepadinum. Abschließend werden für das Management montaner und hochmontaner Wälder Mitteleuropas Empfehlungen abgeleitet.
Fungi and prokaryotes are dominant colonizers of wood and mediate its decomposition. Much progress has been achieved to unravel these communities and link them to specific wood properties. However, comparative studies considering both groups of organisms and assessing their relationships to wood resources are largely missing. Bipartite interaction networks provide an opportunity to investigate this colonizer-resource relationship more in detail and aim to directly compare results between different biotic groups. The main questions were as follows. Are network structures reflecting the trophic relationship between fungal and prokaryotic colonizers and their resources? If so, do they reflect the critical role of these groups, especially that of fungi, during decomposition? We used amplicon sequencing data to analyze fungal and prokaryotic interaction networks from deadwood of 13 temperate tree species at an early to middle stage of decomposition. Several diversity- and specialization-related indices were determined and the observed network structures were related to intrinsic wood traits. We hypothesized nonrandom bipartite networks for both groups and a higher degree of specialization for fungi, as they are the key players in wood decomposition. The results reveal highly modular and specialized interaction networks for both groups of organisms, demonstrating that many fungi and prokaryotes are resource-specific colonizers. However, as the level of specialization of fungi significantly surpassed that of prokaryotes, our findings reflect the strong association between fungi and their host. Our novel approach shows that the application of bipartite interaction networks is a useful tool to explore, quantify, and compare the deadwood-colonizers relationship based on sequencing data.
IMPORTANCE Deadwood is important for our forest ecosystems. It feeds and houses many organisms, e.g., fungi and prokaryotes, with many different species contributing to its decomposition and nutrient cycling. The aim of this study was to explore and quantify the relationship between these two main wood-inhabiting organism groups and their corresponding host trees. Two independent DNA-based amplicon sequencing data sets (fungi and prokaryotes) were analyzed via bipartite interaction networks. The links in the networks represent the interactions between the deadwood colonizers and their deadwood hosts. The networks allowed us to analyze whether many colonizing species interact mostly with a restricted number of deadwood tree species, so-called specialization. Our results demonstrate that many prokaryotes and fungi are resource-specific colonizers. The direct comparison between both groups revealed significantly higher specialization values for fungi, emphasizing their strong association to respective host trees, which reflects their dominant role in exploiting this resource.
Mountains, with their isolated position and altitudinal belts, are hotspots of biodiversity. Their flora and fauna have been observed worldwide since the days of Alexander von Humboldt, which has led to basic knowledge and understanding of species composition and the most important driving forces of ecosystem differentiation in such altitudinal gradients. Systematically designed analyses of changes in species composition with increasing elevation have been increasingly implemented since the 1990s. Since global climate change is one of the most important problems facing the world this century, a focus on such ecosystem studies is urgently needed. To identify the main future needs of such research we analyze the studies dealing with species changes of diverse taxonomical groups along altitudinal gradients (0 to 6,400 m a.s. l.) on all continents, published during the past one to two decades. From our study we can conclude that although mountains are powerful for climate change research most studies have to face the challenge of separating confounding effects driving species assemblages along altitudinal gradients. Our study therefore supports the view of the need of a global altitudinal concept including that (1) not only one or a few taxonomical groups should be analyzed, but rather different taxonomical groups covering all ecosystem functions simultaneously; (2) relevant site conditions should be registered to reveal direct environmental variables responsible for species distribution patterns and to resolve inconsistent effects along the altitudinal gradients; (3) transect design is appropriate for analyzing ecosystem changes in site gradients and over time; (4) both the study design and the individual methods should be standardized to compare the data collected worldwide; and (5) a long-term perspective is important to quantify the degree and direction of species changes and to validate species distribution models. (6) Finally we suggest to develop experimental altitudinal approaches to overcome the addressed problems of biodiversity surveys.