Latitudinal gradient of cyanobacterial diversity in tidal flats.

Janina C Vogt,Katarzyna A Palinska,Dirk C Albach,Raeid M M Abed,Jean-François Humbert

doi:10.1371/journal.pone.0224444

Janina C Vogt, Katarzyna A Palinska + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0224444

Copy DOI

Abstract

Latitudinal diversity gradients are well-known for plants and animals, but only recently similar patterns have been described for some specific microbial communities in distinct habitats. Although microbial diversity is well-investigated worldwide, most of the studies are spatially too restricted to allow general statements about global diversity patterns. Additionally, methodological differences make it hard and often impossible to compare several studies. This study investigated the cyanobacterial diversity in tidal flats along geographical and ecological gradients based on high-throughput sequencing of 16S rRNA gene fragments (Illumina MiSeq) and environmental data on a large spatial scale from the subtropics to the Arctic. Latitude and strongly correlated environmental parameters (e.g. temperature) were identified as important drivers of cyanobacterial diversity on global scale resulting in a latitudinal diversity gradient similar to that known from plants and animals. Other non-correlated parameters (e.g. grain size) were shown to be more important on local scales, although no consistent pattern occurred across different locations. Among a total number of 989 operational taxonomic units (OTUs) only one cosmopolitan (classified as Coleofasciculus chthonoplastes), but many location-specific and putative endemic ones (78%) were detected. High proportions of rare members of the community (up to 86%) were found in all samples. Phylogenetic beta diversity was shown to be influenced by the developmental stage of the mat community becoming increasingly similar with increasing stabilization.

Highlights

Detailed analyses of microbial diversity have become common during the last years based on cost-efficient high-throughput sequencing (HTS) technologies, which allow deep insights into the community structure of environmental samples including the previously undetected ‘rare biosphere’
This study investigated the cyanobacterial diversity in tidal flats along geographical and ecological gradients based on high-throughput sequencing of 16S rRNA gene fragments (Illumina MiSeq) and environmental data on a large spatial scale from the subtropics to the Arctic
We examined the following hypotheses: 1) cyanobacterial species from tidal flats are cosmopolitan across latitude rather than forming climate zone-specific communities; 2) the diversity of cyanobacterial communities decrease with latitude similar to that of plants and animals; 3) environmental parameters such as grain size, salinity, total alkalinity and nutrients show similar effects on community diversity across different climate zones

Summary

Introduction

Detailed analyses of microbial diversity have become common during the last years based on cost-efficient high-throughput sequencing (HTS) technologies, which allow deep insights into the community structure of environmental samples including the previously undetected ‘rare biosphere’. Whereas studies focusing on local communities increased our knowledge of the microbial diversity worldwide [2; 3], biogeographical patterns only start to emerge with an increasing use of HTS technologies.

Methods

Results

Discussion

Conclusion