Microbial Hitchhikers on Intercontinental Dust: Catching a Lift in Chad

Overview

Journal ISME J

Publisher Oxford University Press

Specialties Environmental Health
Microbiology

Date 2012 Dec 21

PMID 23254516

Citations 26

Authors

Jocelyne Favet

Ales Lapanje

Adriana Giongo

Suzanne Kennedy

Yin-Yin Aung

Arlette Cattaneo

Austin G Davis-Richardson

Christopher T Brown

Renate Kort

Hans-Jurgen Brumsack

Bernhard Schnetger

Adrian Chappell

Jaap Kroijenga

Andreas Beck

Karin Schwibbert

Ahmed H Mohamed

Timothy Kirchner

Patricia Dorr de Quadros

Eric W Triplett

William J Broughton

Anna A Gorbushina

Affiliations

Soon will be listed here.

Abstract

Ancient mariners knew that dust whipped up from deserts by strong winds travelled long distances, including over oceans. Satellite remote sensing revealed major dust sources across the Sahara. Indeed, the Bodélé Depression in the Republic of Chad has been called the dustiest place on earth. We analysed desert sand from various locations in Chad and dust that had blown to the Cape Verde Islands. High throughput sequencing techniques combined with classical microbiological methods showed that the samples contained a large variety of microbes well adapted to the harsh desert conditions. The most abundant bacterial groupings in four different phyla included: (a) Firmicutes-Bacillaceae, (b) Actinobacteria-Geodermatophilaceae, Nocardiodaceae and Solirubrobacteraceae, (c) Proteobacteria-Oxalobacteraceae, Rhizobiales and Sphingomonadaceae, and (d) Bacteroidetes-Cytophagaceae. Ascomycota was the overwhelmingly dominant fungal group followed by Basidiomycota and traces of Chytridiomycota, Microsporidia and Glomeromycota. Two freshwater algae (Trebouxiophyceae) were isolated. Most predominant taxa are widely distributed land inhabitants that are common in soil and on the surfaces of plants. Examples include Bradyrhizobium spp. that nodulate and fix nitrogen in Acacia species, the predominant trees of the Sahara as well as Herbaspirillum (Oxalobacteraceae), a group of chemoorganotrophic free-living soil inhabitants that fix nitrogen in association with Gramineae roots. Few pathogenic strains were found, suggesting that African dust is not a large threat to public health.

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