High Diversity of Testate Amoebae (Amoebozoa, Arcellinida) Detected by HTS Analyses in a New England Fen using Newly Designed Taxon-specific Primers.

Testate (shell-building) amoebae, such as the Arcellinida (Amoebozoa), are useful bioindicators for climate change. Though past work has relied on morphological analyses to characterize Arcellinida diversity, genetic analyses revealed the presence of multiple cryptic species underlying morphospecies. Here, we design and deploy Arcellinida-specific primers for the SSU-rDNA gene to assess the community composition on the molecular level in a pilot study of two samplings from a New England fen: (1) 36-cm horizontal transects and vertical cores; and (2) 26-m horizontal transects fractioned into four size classes (2-10, 10-35, 35-100, and 100-300 µm). Analyses of these data show the following: (1) a considerable genetic diversity within Arcellinida, much of which comes from morphospecies lacking sequences on GenBank; (2) communities characterized by DNA (i.e. active + quiescent) are distinct from those characterized by RNA (i.e. active, indicator of biomass); (3) active communities on the surface tend to be more similar to one another than to core communities, despite considerable heterogeneity; and (4) analyses of communities fractioned by size find some lineages (OTUs) that are abundant in disjunct size categories, suggesting the possibility of life-history stages. Together, these data demonstrate the potential of these primers to elucidate the diversity of Arcellinida communities in diverse habitats.

Molecular identification of Vermamoeba vermiformis from freshwater fish in lake Taal, Philippines.

Free Living Amoebae (FLA) are considered ubiquitous. FLAs may infect various biological organisms which act as reservoir hosts. Infected freshwater fishes can pose a public health concern due to possible human consumption. This study aims to identify possible pathogenic FLAs present in freshwater fishes. Seventy five (75) Oreochromis niloticus were studied for the presence of FLAs. Fish organs were suspended in physiologic saline pelleted and cultured in non-nutrient agar (NNA) lawned with Escherichia coli and were incubated in 33 °C for 14 days. Eighteen (18) fish gills and nineteen (19) fish intestine samples presented with positive growth. Trophozoites and cystic stages of FLAs were subcultured until homogenous growth was achieved. Cells were harvested from cultured plates and DNA was extracted using Chelex resin. DNA was subjected to polymerase chain reaction using universal forward primer EukA and reverse primer EukB targeting the 18s RNA. Of the 37 plates that presented with positive amoebic growth, 9 samples showed the presence of DNAs and were sent for further purification and sequencing. Basic Local Alignment Search Tool (BLAST) results showed that protists isolated from fish organs in Lake Taal include: Eocercomonas (HM536152), Colpoda steinii (KJ607915) and Vermamoeba vermiformis (KC161965). The results showed that fresh-water fishes can harbour FLAs in the gut. It is proposed that freshwater reservoirs utilized for aquaculture be monitored for the presence of FLAs and extensive study be conducted on the pathogenicity of bacterial endosymbionts and infecting viruses to its mammalian and non-mammalian host.

Phylogeny and Systematics of Leptomyxid Amoebae (Amoebozoa, Tubulinea, Leptomyxida).

We describe four new species of Flabellula, Leptomyxa and Rhizamoeba and publish new SSU rRNA gene and actin gene sequences of leptomyxids. Using these data we provide the most comprehensive SSU phylogeny of leptomyxids to date. Based on the analyses of morphological data and results of the SSU rRNA gene phylogeny we suggest changes in the systematics of the order Leptomyxida (Amoebozoa: Lobosa: Tubulinea). We propose to merge the genera Flabellula and Paraflabellula (the genus Flabellula remains valid by priority rule). The genus Rhizamoeba is evidently polyphyletic in all phylogenetic trees; we suggest retaining the generic name Rhizamoeba for the group unifying R. saxonica, R.matisi n. sp. and R. polyura, the latter remains the type species of the genus Rhizamoeba. Based on molecular and morphological evidence we move all remaining Rhizamoeba species to the genus Leptomyxa. New family Rhizamoebidae is established here in order to avoid paraphyly of the family Leptomyxidae. With the suggested changes both molecular and morphological systems of the order Leptomyxida are now fully congruent to each other.