September 2015 archive

Characterization of a Deep-Branching Heterolobosean, Pharyngomonas turkanaensis n. sp., Isolated From a Non-Hypersaline Habitat, and Ultrastructural Comparison of Cysts and Amoebae Among Pharyngomonas Strains.

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Characterization of a Deep-Branching Heterolobosean, Pharyngomonas turkanaensis n. sp., Isolated From a Non-Hypersaline Habitat, and Ultrastructural Comparison of Cysts and Amoebae Among Pharyngomonas Strains.

J Eukaryot Microbiol. 2015 Aug 20;

Authors: Park JS, Simpson AG

Abstract
An unusual heterolobosean amoeba, isolate LO, was isolated recently from a sample with a salinity of ~4‰, from Lake Turkana in East Africa. 18S rDNA phylogenies confirm that isolate LO branches among halophilic amoeboflagellates assigned to Pharyngomonas. We examined the ultrastructure of the amoeba and cyst stages of isolate LO, as well as the amoebae and cysts of Pharyngomonas kirbyi (isolates AS12B and SD1A). The amoebae of all three isolates lacked discrete dictyosomes and had discoidal/flattened mitochondrial cristae, but the mitochondria were not enrobed by rough endoplasmic reticulum. The cysts of all three isolates showed a thick, bipartite cyst wall, and lacked cyst pores. The cysts of isolate LO were distinct in that the ectocyst was very loose-fitting, and could contain ‘crypts’. No flagellate form of isolate LO has been observed to date, and a salinity-for-growth experiment showed that isolate LO can grow at 15‰ to 100‰ salinity, indicating that it is halotolerant. By contrast, other studied Pharyngomonas isolates are amoeboflagellates and true halophiles. Therefore, we propose isolate LO as a new species, Pharyngomonas turkanaensis n. sp. It is possible that P. turkanaensis descended from halophilic ancestors, and represents a secondary reestablishment of a physiology adapted for moderate salinity. This article is protected by copyright. All rights reserved.

PMID: 26291784 [PubMed – as supplied by publisher]

Characterization of a Deep-Branching Heterolobosean, Pharyngomonas turkanaensis n. sp., Isolated From a Non-Hypersaline Habitat, and Ultrastructural Comparison of Cysts and Amoebae Among Pharyngomonas Strains.

Related Articles

Characterization of a Deep-Branching Heterolobosean, Pharyngomonas turkanaensis n. sp., Isolated From a Non-Hypersaline Habitat, and Ultrastructural Comparison of Cysts and Amoebae Among Pharyngomonas Strains.

J Eukaryot Microbiol. 2015 Aug 20;

Authors: Park JS, Simpson AG

Abstract
An unusual heterolobosean amoeba, isolate LO, was isolated recently from a sample with a salinity of ~4‰, from Lake Turkana in East Africa. 18S rDNA phylogenies confirm that isolate LO branches among halophilic amoeboflagellates assigned to Pharyngomonas. We examined the ultrastructure of the amoeba and cyst stages of isolate LO, as well as the amoebae and cysts of Pharyngomonas kirbyi (isolates AS12B and SD1A). The amoebae of all three isolates lacked discrete dictyosomes and had discoidal/flattened mitochondrial cristae, but the mitochondria were not enrobed by rough endoplasmic reticulum. The cysts of all three isolates showed a thick, bipartite cyst wall, and lacked cyst pores. The cysts of isolate LO were distinct in that the ectocyst was very loose-fitting, and could contain ‘crypts’. No flagellate form of isolate LO has been observed to date, and a salinity-for-growth experiment showed that isolate LO can grow at 15‰ to 100‰ salinity, indicating that it is halotolerant. By contrast, other studied Pharyngomonas isolates are amoeboflagellates and true halophiles. Therefore, we propose isolate LO as a new species, Pharyngomonas turkanaensis n. sp. It is possible that P. turkanaensis descended from halophilic ancestors, and represents a secondary reestablishment of a physiology adapted for moderate salinity. This article is protected by copyright. All rights reserved.

PMID: 26291784 [PubMed – as supplied by publisher]

Frailty and the Microbiome.

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Frailty and the Microbiome.

Interdiscip Top Gerontol Geriatr. 2015;41:54-65

Authors: Meehan CJ, Langille MG, Beiko RG

Abstract
From the moment of birth, the human body plays host to a rich diversity of microbes. Body sites such as the skin, the gut and the mouth support communities of microorganisms (collectively known as the microbiome) that are both numerous and diverse. As our understanding of the microbiome advances, it is evident that these microbial populations participate in a multitude of symbiotic associations with us. The disruption of these associations can lead to a range of diseases beyond mere pathogenesis as microbial nutrition, signaling, and immune defense break down. It is known that changes in microbial composition occur as the human host ages and that diet and living conditions influence the microbiome of older individuals. However, the link between the microbiome and frailty is as yet mostly unexplored. Although the microbiome is likely to influence health factors that contribute to frailty, further work is needed to determine whether overall microbial signatures of frailty exist and, if so, what the diagnostic and therapeutic utility of these signatures might be. © 2015 S. Karger AG, Basel.

PMID: 26301979 [PubMed – in process]

The evolution of genomic GC content undergoes a rapid reversal within the genus Plasmodium.

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The evolution of genomic GC content undergoes a rapid reversal within the genus Plasmodium.
Genome. 2014 Sep;57(9):507-11
Authors: Nikbakht H, Xia X, Hickey DA
Abstract
The genome …

Marine Isolates of Trimastix marina Form a Plesiomorphic Deep-branching Lineage within Preaxostyla, Separate from Other Known Trimastigids (Paratrimastix n. gen.).

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Marine Isolates of Trimastix marina Form a Plesiomorphic Deep-branching Lineage within Preaxostyla, Separate from Other Known Trimastigids (Paratrimastix n. gen.).

Protist. 2015 Jul 22;166(4):468-491

Authors: Zhang Q, Táborský P, Silberman JD, Pánek T, Čepička I, Simpson AG

Abstract
Trimastigids are free-living, anaerobic protists that are closely related to the symbiotic oxymonads, forming together the taxon Preaxostyla (Excavata: Metamonada). We isolated fourteen new strains morphologically corresponding to two species assigned to Trimastix (until now the only genus of trimastigids), Trimastix marina and Trimastix pyriformis. Unexpectedly, marine strains of Trimastix marina branch separately from freshwater strains of this morphospecies in SSU rRNA gene trees, and instead form the sister group of all other Preaxostyla. This position is confirmed by three-gene phylogenies. Ultrastructural examination of a marine isolate of Trimastix marina demonstrates a combination of trimastigid-like features (e.g. preaxostyle-like I fibre) and ancestral characters (e.g. absence of thickened flagellar vane margins), consistent with inclusion of marine T. marina within Preaxostyla, but also supporting its distinctiveness from ‘freshwater T. marina’ and its deep-branching position within Preaxostyla. Since these results indicate paraphyly of Trimastix as currently understood, we transfer the other better-studied trimastigids to Paratrimastix n. gen. and Paratrimastigidae n. fam. The freshwater form previously identified as T. marina is described as Paratrimastix eleionoma n. sp., and Trimastix pyriformis becomes Paratrimastix pyriformis n. comb. Because of its phylogenetic position, ‘true’ Trimastix is potentially important for understanding the evolution of mitochondrion-related organelles in metamonads.

PMID: 26312987 [PubMed – as supplied by publisher]

Paralytic shellfish toxin biosynthesis in cyanobacteria and dinoflagellates: a molecular overview.

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Paralytic shellfish toxin biosynthesis in cyanobacteria and dinoflagellates: a molecular overview.
J Proteomics. 2015 Aug 24;
Authors: Wang DZ, Zhang SF, Zhang Y, Lin L
Abstract
Para…