Phylogenetic Diversity, Distribution, and Cophylogeny of Giant Bacteria (Epulopiscium) with their Surgeonfish Hosts in the Red Sea
KAUST DepartmentBiological and Environmental Sciences and Engineering (BESE) Division
Marine Microbial Ecology Research Group
Marine Science Program
Red Sea Research Center (RSRC)
Permanent link to this recordhttp://hdl.handle.net/10754/608627
MetadataShow full item record
AbstractEpulopiscium is a group of giant bacteria found in high abundance in intestinal tracts of herbivorous surgeonfish. Despite their peculiarly large cell size (can be up to 600 μm), extreme polyploidy (some with over 100,000 genome copies per cell) and viviparity (whereby mother cells produce live offspring), details about their diversity, distribution or their role in the host gut are lacking. Previous studies have highlighted the existence of morphologically distinct Epulopiscium cell types (defined as morphotypes A to J) in some surgeonfish genera, but the corresponding genetic diversity and distribution among other surgeonfishes remain mostly unknown. Therefore, we investigated the phylogenetic diversity of Epulopiscium, distribution and co-occurrence in multiple hosts. Here, we identified eleven new phylogenetic clades, six of which were also morphologically characterized. Three of these novel clades were phylogenetically and morphologically similar to cigar-shaped type A1 cells, found in a wide range of surgeonfishes including Acanthurus nigrofuscus, while three were similar to smaller, rod-shaped type E that has not been phylogenetically classified thus far. Our results also confirmed that biogeography appears to have relatively little influence on Epulopiscium diversity, as clades found in the Great Barrier Reef and Hawaii were also recovered from the Red Sea. Although multiple symbiont clades inhabited a given species of host surgeonfish and multiple host species possessed a given symbiont clade, statistical analysis of host and symbiont phylogenies indicated significant cophylogeny, which in turn suggests co-evolutionary relationships. A cluster analysis of Epulopiscium sequences from previously published amplicon sequencing dataset revealed a similar pattern, where specific clades were consistently found in high abundance amongst closely related surgeonfishes. Differences in abundance may indicate specialization of clades to certain gut environments reflected by inferred differences in the host diets. Overall, our analysis identified a large phylogenetic diversity of Epulopiscium (up to 10% sequence divergence of 16S rRNA genes), which lets us hypothesize that there are multiple species that are spread across guts of different host species.
CitationPhylogenetic Diversity, Distribution, and Cophylogeny of Giant Bacteria (Epulopiscium) with their Surgeonfish Hosts in the Red Sea 2016, 7 Frontiers in Microbiology
SponsorsThe research reported here was supported by King Abdullah University of Science and Technology (KAUST). We would like to thank Dr. John Howard Choat and Dr. William D. Robbins (James Cook University, Australia) for providing us with the host fish diet information and discussions related to the host diet. We also thank Dr. Matthew Cahill on his invaluable input and expertise, and Professor Michael L. Berumen, Dr. Joseph DiBattista, and Tane H. Sinclair-Taylor for assistance with fish sampling. We also extend our thanks to the KAUST Coastal and Marine Resources Core Lab and the Bioscience Core Lab for their technical assistance.
PublisherFrontiers Media SA
JournalFrontiers in Microbiology
- Diet strongly influences the gut microbiota of surgeonfishes.
- Authors: Miyake S, Ngugi DK, Stingl U
- Issue date: 2015 Feb
- Nocturnal production of endospores in natural populations of epulopiscium-like surgeonfish symbionts.
- Authors: Flint JF, Drzymalski D, Montgomery WL, Southam G, Angert ER
- Issue date: 2005 Nov
- Challenges Faced by Highly Polyploid Bacteria with Limits on DNA Inheritance.
- Authors: Angert ER
- Issue date: 2021 Jun 8
- An unusual symbiont from the gut of surgeonfishes may be the largest known prokaryote.
- Authors: Clements KD, Bullivant S
- Issue date: 1991 Sep
- Recombination contributes to population diversification in the polyploid intestinal symbiont Epulopiscium sp. type B.
- Authors: Arroyo FA, Pawlowska TE, Choat JH, Clements KD, Angert ER
- Issue date: 2019 Apr