Changes in plant species richness induce functional shifts in soil nematode communities in experimental grassland

Background

Changes in plant diversity may induce distinct changes in soil food web structure and accompanying soil feedbacks to plants. However, knowledge of the long-term consequences of plant community simplification for soil animal food webs and functioning is scarce. Nematodes, the most abundant and diverse soil Metazoa, represent the complexity of soil food webs as they comprise all major trophic groups and allow calculation of a number of functional indices.

Methodology/Principal Findings

We studied the functional composition of nematode communities three and five years after establishment of a grassland plant diversity experiment (Jena Experiment). In response to plant community simplification common nematode species disappeared and pronounced functional shifts in community structure occurred. The relevance of the fungal energy channel was higher in spring 2007 than in autumn 2005, particularly in species-rich plant assemblages. This resulted in a significant positive relationship between plant species richness and the ratio of fungal-to-bacterial feeders. Moreover, the density of predators increased significantly with plant diversity after five years, pointing to increased soil food web complexity in species-rich plant assemblages. Remarkably, in complex plant communities the nematode community shifted in favour of microbivores and predators, thereby reducing the relative abundance of plant feeders after five years.

Conclusions/Significance

The results suggest that species-poor plant assemblages may suffer from nematode communities detrimental to plants, whereas species-rich plant assemblages support a higher proportion of microbivorous nematodes stimulating nutrient cycling and hence plant performance; i.e. effects of nematodes on plants may switch from negative to positive. Overall, food web complexity is likely to decrease in response to plant community simplification and results of this study suggest that this results mainly from the loss of common species which likely alter plant – nematode interactions.     

Baeocytes in the cyanobacterium Pleurocapsa sp.: characterization of the differentiated cells produced by multiple fission

Electron microscopy of cyanobacteria Pleurocapsa sp. CALU 1126 revealed that multiple fission proceeds by successive binary fissions. The cultivation conditions were determined when the number of baeocytes (products of multiple fission) was comparable with that of macrocytes (products of binary fission), and cell sorting was achieved for the first time. Juvenile baeocytes were shown to differ from macrocytes in: (1) the absence of sheath; (2) the linear-peripheral configuration of their lamellar system; (3) lower content of phycobiliproteins and higher content of carotenoids; (4) the set of PSII polypeptides. Baeocytes can therefore be considered differentiated cells characterized by the uncoupling between energy and biosynthetic metabolism.     

Identification of Chlorella viruses in Paramecium bursaria clones by pulse-field electrophoresis

The ciliates Paramecium bursaria contain endosymbiotic green algae Chlorella spp. in their cytoplasm. The algae isolated from P. bursaria are sensitive to large DNA-containing viruses of the family Phycodnaviridae. The type virus of this family is PBCV-1 (Paramecium bursaria Chlorella virus). Investigation of the total DNA of P. bursaria clones by pulse-field electrophoresis (PEGE) revealed a pronounced band on PEGE profiles of some P. bursaria clones; the band was formed by DNA molecules of approx. 300 kb. This band probably contained the DNA of Chlorella virus. Two approaches were used in the present work to confirm this hypothesis. Microbiological tests were used to scan a collection of P. bursaria clones for specific types of viruses; the 300-kb band was revealed only in the PEGE profiles of virus-containing clones. Blot hybridization of P. bursaria total DNA separated by pulse-field electrophoresis with the virus-specific probe revealed that the band under study was formed by the DNA of a Chlorella virus. Paramecium clones were shown to contain approx. 10⁵ copies of nonintegrated viral DNA.