Symbiosis research at the end of the millenium

The development of symbiosis research over the closing 50 years of the last millenium is reviewed. At the beginning of this period, there had been very little previous research into aquatic microbial symbiosis. The advent of new experimental techniques, combined with the developing acceptance of the symbiotic origin of eukaryotic cell structure (and especially that chloroplasts evolved from a symbiosis involving photosynthetic aquatic microbes) brought symbiosis research into much greater prominence for a time in the 1970s and 1980s. Nevertheless, at the end of the millenuim, symbiosis as a subject still lacks a clear and strong identity amongst biologists in general. Three reasons are identified for this: continuing absence of a generally accepted definition of the term; little or no representation in the academic structure of biology; and the current adverse climate of research funding in many countries. However, the growing importance of symbiosis in biotechnology and in conserving biodiversity makes future prospects much brighter.     

Production, turnover and mycorrhizal colonization of root systems of three Populus species grown under elevated CO2 (POPFACE)

A fast growing high density Populus plantation located in central Italy was exposed to elevated carbon dioxide for a period of three years. An elevated CO₂ treatment (550 ppm), of 200 ppm over ambient (350 ppm) was provided using a FACE technique. Standing root biomass, fine root turnover and mycorrhizal colonization of the following Populus species was examined: Populus alba L., Populus nigra L., Populus x euramericana Dode (Guinier). Elevated CO₂ increased belowground allocation of biomass in all three species examined, standing root biomass increased by 47–76% as a result of FACE treatment. Similarly, fine root biomass present in the soil increased by 35–84%. The FACE treatment resulted in 55% faster fine root turnover in P. alba and a 27% increase in turnover of roots of P. nigra and P. x euramericana. P. alba and P. nigra invested more root biomass into deeper soil horizon under elevated CO₂. Response of the mycorrhizal community to elevated CO₂ was more varied, the rate of infection increased only in P. alba for both ectomycorrhizal (EM) and arbuscular mycorrhizas (AM). The roots of P. nigra showed greater infection only by AM and the colonization of the root system of P. x euramericana was not affected by FACE treatment. The results suggest that elevated atmospheric CO₂ conditions induce greater belowground biomass investment, which could lead to accumulation of assimilated C in the soil profile. This may have implications for C sequestration and must be taken into account when considering long‐term C storage in the soil.     

Ectomycorrhizal morphotypes of naturally grownAbies firma seedlings

Ectomycorrhizas of naturally grown Momi fir (Abies firma) seedlings were characterized based on morphological features of fungal partners. A total of 128 seedlings were collected over three years (1995–1997) from a 10×30 m plot where occurrences of ectomycorrhizal fungal fruitbodies were monitored for the same period. Thirty-seven morphologically distinct ectomycorrhizal types were distinguished based mainly on the color of ectomycorrhizas and the characteristics of fungal mantles. Type 37 was thought to beCenococcum geophilum because of the jet-black mycorrhizas and the characteristic structure of mantle surfaces. For half of the classified morphotypes, fungal partners were inferred to be the generaLactarius, Russula, andTuber, and unidentified Basidiomycetes, based on earlier references.