Resource availability controls fungal diversity across a plant diversity gradient

Despite decades of research, the ecological determinants of microbial diversity remain poorly understood. Here, we test two alternative hypotheses concerning the factors regulating fungal diversity in soil. The first states that higher levels of plant detritus production increase the supply of limiting resources (i.e. organic substrates) thereby increasing fungal diversity. Alternatively, greater plant diversity increases the range of organic substrates entering soil, thereby increasing the number of niches to be filled by a greater array of heterotrophic fungi. These two hypotheses were simultaneously examined in experimental plant communities consisting of one to 16 species that have been maintained for a decade. We used ribosomal intergenic spacer analysis (RISA), in combination with cloning and sequencing, to quantify fungal community composition and diversity within the experimental plant communities. We used soil microbial biomass as a temporally integrated measure of resource supply. Plant diversity was unrelated to fungal diversity, but fungal diversity was a unimodal function of resource supply. Canonical correspondence analysis (CCA) indicated that plant diversity showed a relationship to fungal community composition, although the occurrence of RISA bands and operational taxonomic units (OTUs) did not differ among the treatments. The relationship between fungal diversity and resource availability parallels similar relationships reported for grasslands, tropical forests, coral reefs, and other biotic communities, strongly suggesting that the same underlying mechanisms determine the diversity of organisms at multiple scales.     

艾滋病合并侵袭性真菌感染35例临床分析

目的 分析艾滋病(AIDS)合并侵袭性真菌感染的发生情况及临床特点,为其诊治提供参考。方法 回顾性分析85例AIDS患者的临床资料,总结侵袭性真菌感染的发病情况及临床特点。结果 85例AIDS患者继发侵袭性真菌感染35例,感染率为41．2％,感染部位以消化道为主,占44．4％,致病菌以白念珠菌(白假丝酵母)为主,占57．4％,侵袭性真菌感染病例主要发生于CD4~+T淋巴细胞计数＜100个/μl的患者,占71．8％。35例患者中27例治愈,8例死亡。结论 侵袭性真菌感染是AIDS患者主要的机会性感染之一,其发生与CD4~+T淋巴细胞计数密切相关,临床上以消化道真菌感染多见,侵袭性真菌感染的病死率高。     

Natural variation in life history strategy of Arabidopsis thaliana determines stress responses to drought and insects of different feeding guilds

Plants are sessile organisms and, consequently, are exposed to a plethora of stresses in their local habitat. As a result, different populations of a species are subject to different selection pressures leading to adaptation to local conditions and intraspecific divergence. The annual brassicaceous plant Arabidopsis thaliana is an attractive model for ecologists and evolutionary biologists due to the availability of a large collection of resequenced natural accessions. Accessions of A. thaliana display one of two different life cycle strategies: summer and winter annuals. We exposed a collection of 308 European Arabidopsis accessions, that have been genotyped for 250K SNPs, to a range of stresses: one abiotic stress (drought), four biotic stresses (Pieris rapae caterpillars, Plutella xylostella caterpillars, Frankliniella occidentalis thrips and Myzus persicae aphids) and two combined stresses (drought plus P. rapae and Botrytis cinerea fungus plus P. rapae). We identified heritable genetic variation for responses to the different stresses, estimated by narrow‐sense heritability. We found that accessions displaying different life cycle strategies differ in their response to stresses. Winter annuals are more resistant to drought, aphids and thrips and summer annuals are more resistant to P. rapae and P. xylostella caterpillars. Summer annuals are also more resistant to the combined stresses of drought plus P. rapae and infection by the fungus Botryris cinerea plus herbivory by P. rapae. Adaptation to drought displayed a longitudinal gradient. Finally, trade‐offs were recorded between the response to drought and responses to herbivory by caterpillars of the specialist herbivore P. rapae.     

Cultivable Fungal Diversity in Deep-Sea Sediment of the East Pacific Ocean

The diversity of fungi in the marine environment has been extensively studied, but their denitrification activity has rarely been reported to date. In the present study, we used six different media to isolate fungi from 10 sediment samples collected at five different locations of the East Pacific Ocean with water depths ranging from 4545 to 7068?m. Fungal identification and phylogenetic diversity analysis were conducted based on morphological characteristics and internal transcribed spacers of ribosomal DNA (ITS-rRNA) sequencing. A total of 106 fungal isolates, belonging to 12 genera, including Aspergillus (five strains), Aureobasidium (three strains), Candida (two strains), Cladosporium (56 strains), Cystobasidium (one strain), Devriesia (nine strains), Knufia (one strain), Nigrospora (three strains), Penicillium (18 strains), Rhodotorula (four strains), Sarocladium (three strains), and unclassified Xylariales (one strain) were obtained. The most dominant culturable genus was Cladosporium. One possible novel fungal strains showed less than 97% similarity to their closest matches of unclassified Xylariales in the Genbank. In addition, we used nirK gene as the molecular marker to detect denitrifying fungi among the cultivable fungal isolates. The nirK gene was detected in Aspergillus niger and Penicillium chrysogenum. Our research indicated that diverse fungi from the deep sea sediments of the East Pacific Ocean and highlighted the involvement of these fungi in denitrification process.