Functional diversity can facilitate the collapse of an undesirable ecosystem state

Biodiversity may increase ecosystem resilience. However, we have limited understanding if this holds true for ecosystems that respond to gradual environmental change with abrupt shifts to an alternative state. We used a mathematical model of anoxic–oxic regime shifts and explored how trait diversity in three groups of bacteria influences resilience. We found that trait diversity did not always increase resilience: greater diversity in two of the groups increased but in one group decreased resilience of their preferred ecosystem state. We also found that simultaneous trait diversity in multiple groups often led to reduced or erased diversity effects. Overall, our results suggest that higher diversity can increase resilience but can also promote collapse when diversity occurs in a functional group that negatively influences the state it occurs in. We propose this mechanism as a potential management approach to facilitate the recovery of a desired ecosystem state.     

Entomopathogenic nematodes fail to parasitize the woolly apple aphid Eriosoma lanigerum as their symbiotic bacteria are suppressed

The restriction of effective insecticides has facilitated the woolly apple aphid (WAA) Eriosoma lanigerum to become a major pest in apple orchards in Western Europe. It has also promoted alternative control strategies such as the use of entomopathogenic nematodes (EPN). We evaluated the control capacity of six commercially available EPN, viz. Heterorhabditis bacteriophora, Heterorhabditis megidis, Steinernema carpocapsae, Steinernema feltiae, Steinernema glaseri and Steinernema kraussei. We assessed the potential of these EPN to colonize and parasitize E. lanigerum in an in vitro multiwell test. Only S. carpocapsae caused higher mortality (20–40%) than the control treatment (water). However, the mortality observed with S. carpocapsae was found to be a test artefact and not induced by its specific entomopathogenic activity. A similar mortality range was recorded when applying the non‐entomopathogenic nematode Pratylenchus thornei in the same multiwell test set‐up. This result warrants careful interpretation of parasitism in these artificial test conditions. The failure of EPN activity was supported in further experiments by frequently finding S. carpocapsae inside living WAA. The presence of the EPN had no effect on aphid reproduction as numbers of ‘large’ embryos in EPN‐colonized and non‐colonized females were similar. In addition, the dauer juveniles did not recover in E. lanigerum reflecting that S. carpocapsae could not develop inside the WAA. We further demonstrated that growth of the EPN‐symbiotic bacteria Xenorhabdus nematophila and Photorhabdus luminescens is inhibited by the body fluid of the WAA, and we speculate that this antibacterial activity is the cause of the unsuccessful parasitization of the WAA by the EPN. This antibiosis inside the body of E. lanigerum would prevent production of the endotoxins by the bacterial symbionts that are essential for entomopathogenicity and insect control.     

Micro-organisms in Trypanosoma cobitis

Bacteria-like micro-organisms have been found in the epimastigote and metacyclic trypomastigote stages of a fish trypanosome, Trypanosoma cobitis (Mitrophanow 1883), in both the leech vector, Hemiclepsis marginata and in culture, and also in the trypomastigote stage from the blood of infected fish.     

Molecular characterization of a novel,nuclear-encoded,NAD+-dependent glyceraldehyde-3-phosphate dehydrogenase in plastids of the gymnosperm Pinus sylvestris L.

Angiosperms and algae possess two distinct glyceraldehyde-3-phosphate dehydrogenase (GAPDH) enzymes, an NAD⁺-dependent tetramer involved in cytosolic glycolysis and an NADP⁺-dependent enzyme of the Calvin cycle in chloroplasts. We have found that the gymnosperm Pinus sylvestris possesses, in addition to these, a nuclear-encoded, plastid-specific, NAD⁺-dependent GAPDH, designated GapCp, which has not previously been described from any plant. Several independent full-size cDNAs for this enzyme were isolated which encode a functional transit peptide and mature subunit very similar to that of cytosolic GAPDH of angiosperms and algae. A molecular phylogeny reveals that chloroplast GapCp and cytosolic GapC arose through gene duplication early in chlorophyte evolution. The GapCp gene is expressed as highly as that for GapC in light-grown pine seedlings. These findings suggest that aspects of compartmentalized sugar phosphate metabolism may differ in angiosperms and gymnosperms and furthermore underscore the contributions of endosymbiotic gene transfer and gene duplication to the nuclear complement of genes for enzymes of plant primary metabolism.     

Determination of pH and oxygen status in the guts of lower and higher termites

The pH of the gut was determined in vitro in six species of termite by means of indicator dyes and a pH electrode. In the lower termite Zootermopsis nevadensis the pH was close to neutrality throughout, ranging 6.0–7.5, but in Reticulitermes lucifugus, acid conditions (pH 5.5–6.0) occurred in the crop and paunch. In the higher termites Nasutitermes costalis, Microcerotermes arboreus, Cubitermes severus and Procubitermes aburiensis, there was a common trend of incresing pH from the crop, which was slightly or moderately acidic, to the first proctodaeal segment (P1) where moderately (N. costalis) and strongly (M. arboreus, C. severus and P. aburiensis) alkaline conditions prevailed. A pH of 10.4 was measured in C. severus, equalling the highest recorded in any insect. In the posterior regions of the hindgut there was a return towards neutral or acidic conditions. When termite guts were homogenized with air-saturated Ringer's solution, the dissolved O₂ content of the Ringer's was reduced. This was shown to be largely attributable to an oxygen deficit generated within the gut in situ. The combined effects of strongly alkaline conditions and reduced oxygen tension on digestive processes and intestinal micro-organisms are discussed.     

Use of partially engorged female ticks as laboratory animals in microbiological research

Abstract. Partially engorged female ticks were used as laboratory animals in microbiological research. The ticks, which were inoculated intracoelomally, became a convenient substrate for the detection of viruses, rickettsiae and protozoal parasites. This research concerned the isolation of newly recovered micro-organisms, the study of development, structure and distribution of microbial agents in ticks, and the study of their interaction with other pathogens or symbionts during mixed infection in a tick body. The isolation and maintenance of Rickettsiella phytoseiuli , the organism not of tick-borne origin, was achieved. For use in Central Europe the tick Dermacentor reticulatus is recommended for the above investigations.     

Sizing up the genomic footprint of endosymbiosis

A flurry of recent publications have challenged consensus views on the tempo and mode of plastid (chloroplast) evolution in eukaryotes and, more generally, the impact of endosymbiosis in the evolution of the nuclear genome. Endosymbiont‐to‐nucleus gene transfer is an essential component of the transition from endosymbiont to organelle, but the sheer diversity of algal‐derived genes in photosynthetic organisms such as diatoms, as well as the existence of genes of putative plastid ancestry in the nuclear genomes of plastid‐lacking eukaryotes such as ciliates and choanoflagellates, defy simple explanation. Collectively, these papers underscore the power of comparative genomics and, at the same time, reveal how little we know with certainty about the earliest stages of the evolution of photosynthetic eukaryotes. Editor's suggested further reading in BioEssays Early steps in plastid evolution: current ideas and controversies Abstract Dinoflagellate mitochondrial genomes: stretching the rules of molecular biology Abstract