Your search keyword '"Bernhard Klarner"' showing total 14 results

1. Earthworm invasion causes declines across soil fauna size classes and biodiversity facets in northern North American forests

Author

Lee E. Frelich, Madhav P. Thakur, Malte Jochum, Edward A. Johnson, Nico Eisenhauer, Olga Ferlian, Jörg Alfred Salamon, Bernhard Klarner, and Marcel Ciobanu

Subjects

2. Zero hunger, 0106 biological sciences, 0303 health sciences, Biomass (ecology), Ecology, Soil biology, Biodiversity, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Ecosystem engineer, 03 medical and health sciences, Abundance (ecology), Microfauna, 570 Life sciences, biology, Ecosystem, Species richness, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology

Abstract

Anthropogenic pressures alter the biodiversity, structure and organization of biological communities with severe consequences for ecosystem processes. Species invasion is such a human-induced ecosystem change with pronounced impacts on recipient ecosystems. Around the globe, earthworms invade habitats and impact abiotic soil conditions and a wide range of above- and belowground organisms. In northern North America, where earthworms have been largely absent since the last glaciation period and most earthworm species present today have only been (re-)introduced a few hundred years ago, invasion impacts have been intensively studied. However, despite several studies assessing impacts of invasive earthworms on soil fauna, studies have rarely investigated the simultaneous responses of different soil-fauna size groups and biodiversity facets which might respond differently to earthworm invasion and independently affect ecosystem processes. Our study goes beyond previously-established knowledge on earthworm-invasion effects by simultaneously assessing differences in four biodiversity facets, namely the abundance, biomass, richness and Shannon index of soil invertebrate macro-, meso- and microfauna communities between high- and low-invasion status plots (n = 80) and in relation to invasion intensity measured as earthworm biomass across four northern North American forests sampled between 2016 and 2017. Across forests and soil-fauna groups, we found reduced abundance (−33 to −45%) and richness (−18 to −25%) in high compared to low-invasion status areas. Additionally, meso- (−14%) and microfauna biomass (−38%) and macro- (−7%) and microfauna Shannon index (−8%) were reduced. Higher invasion intensity (earthworm biomass) was additionally related to reduced soil-fauna biodiversity. While the studied biodiversity facet was important for the soil fauna response, soil-fauna size group was comparably unimportant. Given the global ubiquity of earthworm invasion and the importance of soil fauna for key ecosystem processes, our observational results help to assess future impacts of this invasion and the consequences for anthropogenically-altered ecosystem functioning.

Published

2021

2. Aboveground impacts of a belowground invader: how invasive earthworms alter aboveground arthropod communities in a northern North American forest

Author

Malte Jochum, Lise Thouvenot, Olga Ferlian, Romy Zeiss, Bernhard Klarner, Ulrich Pruschitzki, Edward A. Johnson, and Nico Eisenhauer

Subjects

Canada, Animals, Forests, Oligochaeta, Plants, General Agricultural and Biological Sciences, Agricultural and Biological Sciences (miscellaneous), Arthropods

Abstract

Declining arthropod communities have recently gained a lot of attention, with climate and land-use change among the most frequently discussed drivers. Here, we focus on a seemingly underrepresented driver of arthropod community decline: biological invasions. For approximately 12 000 years, earthworms have been absent from wide parts of northern North America, but they have been re-introduced with dramatic consequences. Most studies investigating earthworm-invasion impacts focus on the belowground world, resulting in limited knowledge on aboveground-community changes. We present observational data on earthworm, plant and aboveground arthropod communities in 60 plots, distributed across areas with increasing invasion status (low, medium and high) in a Canadian forest. We analysed how earthworm-invasion status and biomass impact aboveground arthropod community abundance, biomass and species richness, and how earthworm impacts cascade across trophic levels. We sampled approximately 13 000 arthropods, dominated by Hemiptera, Diptera, Araneae, Thysanoptera and Hymenoptera. Total arthropod abundance, biomass and species richness declined significantly from areas of low to those with high invasion status, with reductions of 61, 27 and 18%, respectively. Structural equation models suggest that earthworms directly and indirectly impact arthropods across trophic levels. We show that earthworm invasion can alter aboveground multi-trophic arthropod communities and suggest that belowground invasions might be underappreciated drivers of aboveground arthropod decline.

Published

2022

3. Linking size spectrum, energy flux and trophic multifunctionality in soil food webs of tropical land‐use systems

Author

Rahayu Widyastuti, Stefan Scheu, Anton M. Potapov, Dorothee Sandmann, and Bernhard Klarner

Subjects

2. Zero hunger, 0106 biological sciences, Biomass (ecology), Food Chain, Rainforest, Ecology, 010604 marine biology & hydrobiology, Biodiversity, 15. Life on land, 010603 evolutionary biology, 01 natural sciences, Decomposer, Food web, Soil, Indonesia, Animals, Environmental science, Animal Science and Zoology, Ecosystem, Ecology, Evolution, Behavior and Systematics, Intraguild predation, Trophic level, Tropical rainforest

Abstract

Many ecosystem functions depend on the structure of food webs, which heavily relies on the body size spectrum of the community. Despite that, little is known on how the size spectrum of soil animals responds to agricultural practices in tropical land-use systems and how these responses affect ecosystem functioning. We studied land-use-induced changes in below-ground communities in tropical lowland ecosystems in Sumatra (Jambi province, Indonesia), a hot spot of tropical rainforest conversion into rubber and oil palm plantations. The study included ca. 30,000 measured individuals from 33 high-order taxa of meso- and macrofauna spanning eight orders of magnitude in body mass. Using individual body masses, we calculated the metabolism of trophic guilds and used food web models to calculate energy fluxes and infer ecosystem functions, such as decomposition, herbivory, primary and intraguild predation. Land-use change was associated with reduced abundance and taxonomic diversity of soil invertebrates, but strong increase in total biomass and moderate changes in total energy flux. These changes were due to increased biomass of large-sized decomposers in soil, in particular earthworms, with their share in community metabolism increasing from 11% in rainforest to 59%-76% in jungle rubber, and rubber and oil palm plantations. Decomposition, that is the energy flux to decomposers, stayed unchanged, but herbivory, primary and intraguild predation decreased by an order of magnitude in plantation systems. Intraguild predation was very important, being responsible for 38% of the energy flux in rainforest according to our model. Conversion of rainforest into monoculture plantations is associated by an uneven loss of size classes and trophic levels of soil invertebrates resulting in sequestration of energy in large-sized primary consumers and restricted flux of energy to higher trophic levels. Pronounced differences between rainforest and jungle rubber reflect sensitivity of rainforest soil animal communities to moderate land-use changes. Soil communities in plantation systems sustained high total energy flux despite reduced biodiversity. The high energy flux into large decomposers but low energy fluxes into other trophic guilds suggests that trophic multifunctionality of below-ground communities is compromised in plantation systems.

Published

2019

4. Ground Spider Communities Under Tropical Land‐Use Change

Author

Malte Jochum, Ulrich Brose, Nadine Dupérré, Andrew D. Barnes, Danilo Harms, Katja Rembold, Valentyna Krashevska, Rahayu Widyastuti, Kerstin Dreczko, Stefan Scheu, Anton M. Potapov, Bernhard Klarner, and Holger Kreft

Subjects

Geography, biology, Agroforestry, Land use, land-use change and forestry, Ground spider, General Medicine, biology.organism_classification

Published

2020

5. Micro-decomposer communities and decomposition processes in tropical lowlands as affected by land use and litter type

Author

Mark Maraun, Stefan Scheu, Bernhard Klarner, Rahayu Widyastuti, Valentyna Krashevska, Yuri Mazei, and Elena Malysheva

Subjects

Rainforest, 010504 meteorology & atmospheric sciences, Microorganism, Fungi, Community structure, 04 agricultural and veterinary sciences, Biology, 01 natural sciences, Food web, Decomposer, Agronomy, Indonesia, 040103 agronomy & agriculture, Litter, 0401 agriculture, forestry, and fisheries, Monoculture, Amoeba, Testate amoebae, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

We investigated how the land-use change from rainforest into jungle rubber, intensive rubber and oil palm plantations affects decomposers and litter decomposition in Sumatra, Indonesia. Litterbags containing three litter types were placed into four land-use systems and harvested after 6 and 12 months. Litter mass loss and litter element concentrations were measured, and different microbial groups including bacteria, fungi and testate amoebae were studied. After 12 months 81, 65, 63 and 53% of litter exposed in rainforest, jungle rubber in oil palm and rubber plantations was decomposed. In addition to land use, litter decomposition varied strongly with litter type and short-term effects differed markedly from long-term effects. After 6 months, oil palm and rubber litter decomposed faster than rainforest litter, but after 12 months, decomposition of rainforest litter exceeded that of oil palm and rubber litter, reflecting adaptation of bacteria and fungi to decompose structural compounds in rainforest litter but not (or less) in rubber and oil palm litter. Bacterial and fungal community composition and testate amoeba species number and density varied strongly with litter type, but little with land use. However, community composition of testate amoebae was mainly affected by land use. Generally, changes in bacteria, fungi and testate amoebae were linked to changes in litter element concentrations, suggesting that element ratios of litter material as basal resource for the decomposer food web shape the structure of decomposer communities and decomposition processes via bottom-up forces. Overall, changing rainforest to monoculture plantations shifts the decomposer community structure and negatively affects litter decomposition.

Published

2018

6. Functional losses in ground spider communities due to habitat structure degradation under tropical land-use change

Author

Danilo Harms, Katja Rembold, Kerstin Dreczko, Nadine Dupérré, Andrew D. Barnes, Ulrich Brose, Bernhard Klarner, Stefan Scheu, Rahayu Widyastuti, Malte Jochum, Anton M. Potapov, Valentyna Krashevska, and Holger Kreft

Subjects

0106 biological sciences, Rainforest, Biodiversity, 580 Plants (Botany), Southeast asian, 010603 evolutionary biology, 01 natural sciences, Predation, Animals, Ecology, Evolution, Behavior and Systematics, Ecosystem, 2. Zero hunger, biology, Ecology, 010604 marine biology & hydrobiology, Ground spider, Agriculture, Spiders, Understory, 15. Life on land, biology.organism_classification, Habitat destruction, Indonesia, Species richness

Abstract

Deforestation and land-use change in tropical regions result in habitat loss and extinction of species that are unable to adapt to the conditions in agricultural landscapes. If the associated loss of functional diversity is not compensated by species colonizing the converted habitats, extinctions might be followed by a reduction or loss of ecosystem functions including biological control. To date, little is known on how land-use change in the tropics alters the functional diversity of invertebrate predators and which key environmental factors may mitigate the decline in functional diversity and predation in litter and soil communities. We applied litter sieving and heat extraction to study ground spider communities and assessed structural characteristics of vegetation and parameters of litter in rainforest and agricultural land-use systems (jungle rubber, rubber and oil palm monocultures) in a Southeast Asian hotspot of rainforest conversion: Sumatra, Indonesia. We found that (1) spider density, species richness, functional diversity and community predation (energy flux to spiders) were reduced by 57-98% from rainforest to oil palm monoculture; (2) jungle rubber and rubber monoculture sustained relatively high diversity and predation in ground spiders, but small cryptic spider species strongly declined; (3) high species turnover compensated losses of some functional trait combinations, but did not compensate for the overall loss of functional diversity and predation per unit area; (4) spider diversity was related to habitat structure such as amount of litter, understory density and understory height, while spider predation was better explained by plant diversity. Management practices that increase habitat structural complexity and plant diversity such as mulching, reduced weeding, and intercropping monocultures with other plants may contribute to maintaining functional diversity of and predation services provided by ground invertebrate communities in plantations.

Published

2019

7. Trophic niche differentiation and utilisation of food resources in collembolans based on complementary analyses of fatty acids and stable isotopes

Author

Stefan Scheu, Annika E. Langeneckert, Olga Ferlian, and Bernhard Klarner

Subjects

Ecological niche, Habitat, Ecology, Litter, Soil Science, 15. Life on land, Biology, Generalist and specialist species, Microbiology, Decomposer, Predation, Trophic level, Isotope analysis

Abstract

Feeding on a variety of resources, collembolans have been assumed to be food generalists. However, recent stable isotope analyses documented that collembolan species occupy different trophic levels, but detailed studies on species-specific food resources are sparse. Further, it still is little understood whether food resources of collembolan species are constant or shift, e.g., with habitats. Fatty acid (FA) and stable isotope analysis allow insight into utilisation of basal resources and trophic levels of consumers, respectively. We combined these methods to investigate variations in trophic niches of six collembolan species (Lepidocyrtus lanuginosus, Folsomia quadrioculata, Parisotoma notabilis, Ceratophysella denticulata, Isotomiella minor and Protaphorura armata) in beech and spruce forests. We correlated collembolan FAs with that of litter microorganisms at the respective study sites to identify links to resources. FA composition and stable isotope signatures in collembolan species did not differ significantly between forest types but between species suggesting pronounced trophic niche differentiation between species. The trophic niche of C. denticulata and P. armata was similar and significantly differed from the other species with 13C and 15N signatures being least depleted. We suggest that C. denticulata has a predatory life style feeding on nematodes. Due to intermediate to low 13C and 15N levels and specific FA compositions the other collembolan species could be ascribed to secondary decomposers with I. minor being more closely associated with bacterial resources and F. quadrioculata, L. lanuginosus and P. notabilis with fungal resources. However, dietary niches presumably comprise a mixture of resources rather than single resources. FAs in collembolan species correlated poorly with those in litter suggesting that the diet of collembolan species is rather independent of the structure of microbial communities in bulk litter. The results suggest that collembolans consume resources of microsites rather than bulk material thereby benefitting from the small-scale heterogeneity in resource distribution in soil. Low variation in trophic niches with forest type suggests that these microsites are similar across different forests and provide similar food resources despite marked differences in e.g., litter materials and humus structure.

Published

2015

8. The structure of salt marsh soil mesofauna food webs - The prevalence of disturbance

Author

Kristin Haynert, Mirijam Kiggen, Bernhard Klarner, Mark Maraun, and Stefan Scheu

Subjects

Composite Particles, Atoms, Food Chain, lcsh:Medicine, Marine and Aquatic Sciences, Predation, Soil Science, Marshes, Soil, Community structure, Stable isotopes, Food web structure, Invertebrates, Food, Soil ecology, Isotopes, Germany, Food Web Structure, Medicine and Health Sciences, Animals, Humans, lcsh:Science, Particle Physics, Community Structure, Nutrition, Ecology, Physics, Stable Isotopes, lcsh:R, Ecology and Environmental Sciences, Organisms, Aquatic Environments, Biology and Life Sciences, Eukaryota, Biodiversity, Soil Ecology, Trophic Interactions, Diet, Community Ecology, Predatory Behavior, Wetlands, Physical Sciences, Earth Sciences, lcsh:Q, Research Article, Freshwater Environments

Abstract

Mesofauna taxa fill key trophic positions in soil food webs, even in terrestrial-marine boundary habitats characterized by frequent natural disturbances. Salt marshes represent such boundary habitats, characterized by frequent inundations increasing from the terrestrial upper to the marine pioneer zone. Despite the high abundance of soil mesofauna in salt marshes and their important function by facilitating energy and carbon flows, the structure, trophic ecology and habitat-related diet shifts of mesofauna species in natural salt marsh habitats is virtually unknown. Therefore, we investigated the effects of natural disturbance (inundation frequency) on community structure, food web complexity and resource use of soil mesofauna using stable isotope analysis (15N, 13C) in three salt marsh zones. In this intertidal habitat, the pioneer zone is exposed to inundations twice a day, but lower and upper salt marshes are less frequently inundated based on shore height. The mesofauna comprised 86 species / taxa dominated by Collembola, Oribatida and Mesostigmata. Shifts in environmental disturbances influenced the structure of food webs, diversity and density declined strongly from the land to the sea pointing to the importance of increasing levels of inundation frequency. Accordingly, the reduced diversity and density was associated by a simplification of the food web in the pioneer zone as compared to the less inundated lower and upper salt marsh with a higher number of trophic levels. Strong variations in δ15N signatures demonstrated that mesofauna species are feeding at multiple trophic levels. Primary decomposers were low and most mesofauna species functioned as secondary decomposers or predators including second order predators or scavengers. The results document that major decomposer taxa, such as Collembola and Oribatida, are more diverse than previously assumed and predominantly dwell on autochthonous resources of the respective salt marsh zone. The results further suggest that Mesostigmata mostly adopt an intraguild predation lifestyle. The high trophic position of a large number of predators suggests that intraguild predation is of significant importance in salt marsh food webs. Presumably, intraguild predation contributes to stabilizing the salt marsh food web against disturbances.

Published

2017

9. Litter elemental stoichiometry and biomass densities of forest soil invertebrates

Author

Melanie M. Pollierer, Björn C. Rall, Mark Maraun, Stefan Scheu, Gesine Seelig, Ulrich Brose, David Ott, Christoph Digel, and Bernhard Klarner

Subjects

2. Zero hunger, 0106 biological sciences, Abiotic component, Biomass (ecology), education.field_of_study, Ecology, Population, Temperate forest, 04 agricultural and veterinary sciences, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, 13. Climate action, Ecological stoichiometry, 040103 agronomy & agriculture, Litter, 0401 agriculture, forestry, and fisheries, Ecosystem, education, Ecology, Evolution, Behavior and Systematics, Trophic level

Abstract

To maintain constant chemical composition, i.e. elemental homeostasis, organisms have to consume resources of sufficient quality to meet their own specific stoichiometric demand. Therefore, concentrations of elements indicate resource quality, and rare elements in the environment may act as limiting factors for individual organisms scaling up to constrain population densities. We investigated how the biomass densities of invertebrate populations of temperate forest soil communities depend on 1) the stoichiometry of the basal litter according to ecological stoichiometry concepts and 2) the population average body mass as predicted by metabolic theory. We used a large data set on biomass densities of 4959 populations across 48 forests in three regions of Germany. Following various ecological stoichiometry hypotheses, we tested for effects of the carbon-to-element ratios of 10 elements. Additionally, we included the abiotic litter characteristics habitat size (represented by litter depth), litter diversity and pH, as well as forest type as an indicator for human management. Across 12 species groups, we found that the biomass densities scaled significantly with population-averaged body masses thus supporting metabolic theory. Additionally, 10 of these allometric scaling relationships exhibited interactions with stoichiometric and abiotic co-variables. The four most frequent co-variables were 1) forest type, 2) the carbon-to-phosphorus ratio (C:P), 3) the carbon-to-sodium ratio (C:Na), and the carbon-to-nitrogen ratio (C:N). Hence, our analyses support the sodium shortage hypothesis for microbi-detritivores, the structural elements hypothesis for some predator groups (concerning N), and the secondary productivity hypothesis (concerning P) across all trophic groups in our data. In contrast, the ecosystem size hypothesis was only supported for some meso- and macrofauna detritivores. Our study is thus providing a comprehensive analysis how the elemental stoichiometry of the litter as the basal resource constrain population densities across multiple trophic levels of soil communities.

Published

2014

10. Unravelling the complex structure of forest soil food webs: higher omnivory and more trophic levels

Author

Alva Curtsdotter, Ulrich Brose, Jens O. Riede, Christoph Digel, and Bernhard Klarner

Subjects

2. Zero hunger, Food chain, Trophic species, Land use, Ecology, Community structure, Soil food web, Ecosystem, 15. Life on land, Biology, Ecology, Evolution, Behavior and Systematics, Food web, Trophic level

Abstract

Food web topologies depict the community structure as distributions of feeding interactions across populations. Although the soil ecosystem provides important functions for aboveground ecosystems, data on complex soil food webs is notoriously scarce, most likely due to the difficulty of sampling and characterizing the system. To fill this gap we assembled the complex food webs of 48 forest soil communities. The food webs comprise 89 to 168 taxa and 729 to 3344 feeding interactions. The feeding links were established by combining several molecular methods (stable isotope, fatty acid and molecular gut content analyses) with feeding trials and literature data. First, we addressed whether soil food webs (n = 48) differ significantly from those of other ecosystem types (aquatic and terrestrial aboveground, n = 77) by comparing 22 food web parameters. We found that our soil food webs are characterized by many omnivorous and cannibalistic species, more trophic chains and intraguild-predation motifs than other food webs and high average and maximum trophic levels. Despite this, we also found that soil food webs have a similar connectance as other ecosystems, but interestingly a higher link density and clustering coefficient. These differences in network structure to other ecosystem types may be a result of ecosystem specific constraints on hunting and feeding characteristics of the species that emerge as network parameters at the food-web level. In a second analysis of land-use effects, we found significant but only small differences of soil food web structure between different beech and coniferous forest types, which may be explained by generally strong selection effects of the soil that are independent of human land use. Overall, our study has unravelled some systematic structures of soil food-webs, which extends our mechanistic understanding how environmental characteristics of the soil ecosystem determine patterns at the community level.

Published

2014

11. Trophic shift of soil animal species with forest type as indicated by stable isotope analysis

Author

Melanie M. Pollierer, Mark Maraun, Roswitha B. Ehnes, Bernhard Klarner, Georgia Erdmann, Stefan Scheu, and Bernhard Eitzinger

Subjects

biology, Ecology, Stable isotope ratio, Litter, 15. Life on land, Plant litter, biology.organism_classification, Beech, Ecology, Evolution, Behavior and Systematics, Food web, Decomposer, Trophic level, Isotope analysis

Abstract

Anthropogenic land use shapes the dynamics and composition of central European forests and changes the quality and availability of resources of the decomposer system. These changes likely alter the structure and functioning of soil animal food webs. Using stable isotope analysis (13C, 15N) we investigated the trophic position and resource use of soil animal species in each of four forest types (coniferous, young managed beech, old managed beech and unmanaged beech forests) across three regions in Germany. Twenty-eight species of soil invertebrates were analyzed covering three consumer levels and a representative spectrum of feeding types and morphologies. Data on stable isotope signatures of leaf litter, fine roots and soil were included to evaluate to which extent signatures of soil animals vary with those of local resources. Soil animal d15N and d13C signatures varied with the respective signatures of leaf litter and fine roots. After calibration to leaf litter signatures, soil animal stable isotope signatures of the different beech forests did not differ significantly. However, thick leaf litter layers, such as those in coniferous forests, were associated with low animal stable isotope signatures presumably due to reduced access of decomposer animals to root-derived resources, suggesting that the decomposer food web is shifted towards leaf litter based energy pathways with the shift affecting all consumer levels. Variation in stable isotope signatures of soil animal species with litter quality parameters suggests that nutrition of third level but not first and second level consumers is related to litter quality, potentially due to microorganisms locking up litter resources thereby hampering their propagation to higher trophic levels.

Published

2014

12. Lack of energetic equivalence in forest soil invertebrates

Author

Mark Maraun, Bernhard Eitzinger, Georgia Erdmann, Ulrich Brose, Roswitha B. Ehnes, Stefan Scheu, Melanie M. Pollierer, David Ott, Christoph Digel, and Bernhard Klarner

Subjects

Population Density, Biomass (ecology), education.field_of_study, Range (biology), Ecology, Population, Biodiversity, Biology, Invertebrates, Food web, Trees, Soil, Abundance (ecology), Animals, Biomass, Allometry, Energy Metabolism, education, Ecosystem, Phylogeny, Ecology, Evolution, Behavior and Systematics, Demography, Trophic level

Abstract

Ecological communities consist of small abundant and large non-abundant species. The energetic equivalence rule is an often-observed pattern that could be explained by equal energy usage among abundant small organisms and non-abundant large organisms. To generate this pattern, metabolism (as an indicator of individual energy use) and abundance have to scale inversely with body mass, and cancel each other out. In contrast, the pattern referred to as biomass equivalence states that the biomass of all species in an area should be constant across the body-mass range. In this study, we investigated forest soil communities with respect to metabolism, abundance, population energy use, and biomass. We focused on four land-use types in three different landscape blocks (Biodiversity Exploratories). The soil samples contained 870 species across 12 phylogenetic groups. Our results indicated positive sublinear metabolic scaling and negative sublinear abundance scaling with species body mass. The relationships varied mainly due to differences among phylogenetic groups or feeding types, and only marginally due to land-use type. However, these scaling relationships were not exactly inverse to each other, resulting in increasing population energy use and biomass with increasing body mass for most combinations of phylogenetic group or feeding type with land-use type. Thus, our results are mostly inconsistent with the classic perception of energetic equivalence, and reject the biomass equivalence hypothesis while documenting a specific and nonrandom pattern of how abundance, energy use, and biomass are distributed across size classes. However, these patterns are consistent with two alternative predictions: the resource-thinning hypothesis, which states that abundance decreases with trophic level, and the allometric degree hypothesis, which states that population energy use should increase with population average body mass, due to correlations with the number of links of consumers and resources. Overall, our results suggest that a synthesis of food web structures with metabolic theory may be most promising for predicting natural patterns of abundance, biomass, and energy use.

Published

2014

13. Trophic diversity and niche partitioning in a species rich predator guild – Natural variations in stable isotope ratios (13C/12C, 15N/14N) of mesostigmatid mites (Acari, Mesostigmata) from Central European beech forests

Author

Stefan Scheu, Bernhard Klarner, and Mark Maraun

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, Ecology, Niche differentiation, Soil Science, 04 agricultural and veterinary sciences, 15. Life on land, Biology, Old-growth forest, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Microbiology, Decomposer, Predation, Abundance (ecology), Guild, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Mesostigmata, Trophic level

Abstract

A large number of predatory mesostigmatid mite species populate forest soils in high densities. The present study investigates the trophic structure of the Mesostigmata community of old growth beech stands in Central Germany and identifies potential prey groups using natural variations in stable isotope ratios ( 13 C/ 12 C and 15 N/ 14 N). Data on relative abundances and body mass were included for each of the 40 species studied to analyze functional aspects in Mesostigmata feeding ecology. The results indicate that Mesostigmata predominantly feed on secondary decomposers, whereas primary decomposer and intra-guild prey are of minor importance. Dominant species featured high δ 13 C signatures suggesting that they predominantly feed on species relying on root derived resources such as bacterial feeding nematodes. Less abundant species where characterized by lower δ 13 C values suggesting that they predominantly feed on prey relying on litter derived resources such as fungal feeding Collembola. Related taxa often had distinctively different isotope ratios suggesting that trophic niche partitioning facilitates coexistence of morphologically similar species. Unexpectedly, the trophic position of Mesostigmata species was not related to body size reflecting the varying trophic position of their main prey, nematodes and Collembola, suggesting that body size is a poor predictor of trophic position in soil food webs.

Published

2013

14. Contributions to the knowledge of oribatid mites (Acari, Oribatida) of Indonesia. 3. The genus Galumna (Galumnidae) with description of a new subgenus and seven new species

Author

Sergey G, Ermilov, Dorothee, Sandmann, Bernhard, Klarner, Rahaju, Widyastuti, and Stefan, Scheu

Subjects

Oribatida, Indinesia, Galumnidae, new subgenus and species, morphology, record, Animalia, Oribatid mites, systematics, fauna, Research Article, Galumna

Abstract

Seven new species of oribatid mites of the genus Galumna are described from litter and soil materials of Sumatra, Indonesia. A new subgenus, Galumna (Atypicogalumna) subgen. n., is proposed; it differs from all galumnid genera and subgenera by the simultaneous presence of porose areas and sacculi on the notogaster (vs. either porose areas or sacculi present). Galumna (Galumna) calva Starý, 1997 is recorded for the first time in the Oriental region, and Galumna (Galumna) sabahna Mahunka, 1995 is recorded for the first time in the Indonesian fauna.

Published

2015