Cell differentiation and morphogenesis in the colony-forming choanoflagellate Salpingoeca rosetta

Dayel, Mark J.; Alegado, Rosanna A.; Fairclough, Stephen R.; Levin, Tera C.; Nichols, Scott; McDonald, Kent L.; King, Nicole

doi:10.1016/j.ydbio.2011.06.003

Cited by 222 publications

(383 citation statements)

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“…Although the original stock of S. rosetta (ATCC50818) was established from a rosette colony (Dayel et al 2011), laboratory cultures consistently produced single cells, with small numbers of rosette colonies forming only sporadically (Figure 1A, Figure 1—figure supplement 1). Serendipitously, we discovered that the bacterial community influences rosette colony development.…”

Section: Resultsmentioning

confidence: 99%

A bacterial sulfonolipid triggers multicellular development in the closest living relatives of animals

Alegado

Brown

Cao

et al. 2012

eLife

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Bacterially-produced small molecules exert profound influences on animal health, morphogenesis, and evolution through poorly understood mechanisms. In one of the closest living relatives of animals, the choanoflagellate Salpingoeca rosetta, we find that rosette colony development is induced by the prey bacterium Algoriphagus machipongonensis and its close relatives in the Bacteroidetes phylum. Here we show that a rosette inducing factor (RIF-1) produced by A. machipongonensis belongs to the small class of sulfonolipids, obscure relatives of the better known sphingolipids that play important roles in signal transmission in plants, animals, and fungi. RIF-1 has extraordinary potency (femtomolar, or 10−15 M) and S. rosetta can respond to it over a broad dynamic range—nine orders of magnitude. This study provides a prototypical example of bacterial sulfonolipids triggering eukaryotic morphogenesis and suggests molecular mechanisms through which bacteria may have contributed to the evolution of animals.DOI: http://dx.doi.org/10.7554/eLife.00013.001

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Section: Resultsmentioning

confidence: 99%

A bacterial sulfonolipid triggers multicellular development in the closest living relatives of animals

Alegado

Brown

Cao

et al. 2012

eLife

Self Cite

222

228

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“…These SIT domains are not present in any of the sequenced non-siliceous choanoflagellate species [15,17,38,39], implying a correlation between their presence and lorica biomineralization.…”

Section: S Ac Usmentioning

confidence: 94%

A family of diatom-like silicon transporters in the siliceous loricate choanoflagellates

et al. 2013

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Biosilicification is widespread across the eukaryotes and requires concentration of silicon in intracellular vesicles. Knowledge of the molecular mechanisms underlying this process remains limited, with unrelated silicontransporting proteins found in the eukaryotic clades previously studied. Here, we report the identification of silicon transporter (SIT)-type genes from the siliceous loricate choanoflagellates Stephanoeca diplocostata and Diaphanoeca grandis. Until now, the SIT gene family has been identified only in diatoms and other siliceous stramenopiles, which are distantly related to choanoflagellates among the eukaryotes. This is the first evidence of similarity between SITs from different eukaryotic supergroups. Phylogenetic analysis indicates that choanoflagellate and stramenopile SITs form distinct monophyletic groups. The absence of putative SIT genes in any other eukaryotic groups, including non-siliceous choanoflagellates, leads us to propose that SIT genes underwent a lateral gene transfer event between stramenopiles and loricate choanoflagellates. We suggest that the incorporation of a foreign SIT gene into the stramenopile or choanoflagellate genome resulted in a major metabolic change: the acquisition of biomineralized silica structures. This hypothesis implies that biosilicification has evolved multiple times independently in the eukaryotes, and paves the way for a better understanding of the biochemical basis of silicon transport through identification of conserved sequence motifs.

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“…Choanoflagellates can form long actin-based protrusions resembling filopodia required for attachment to the substrate but only exhibit flagellar motility [52,90]. The ultrastructure of choanoflagellates is also highly reminiscent of choanocytes, the feeding cells of sponges, which also assemble a collar of microvilli around the flagellum.…”

Section: (I) Flagellated Fungimentioning

confidence: 99%

“…However, both Filasterea and animals exhibit actin-based motility, which suggests that their common ancestor was possibly undergoing amoeboid phases. In this scenario, choanoflagellates would have lost this trait secondarily, retaining filopodia only for attachment to the substrate [52,90]. The hypothesis that choanoflagellates are derived from ancestors with a more complex life cycle is not new [95,96].…”

Section: (I) Flagellated Fungimentioning

confidence: 99%

Exploring the evolutionary history of centrosomes

Azimzadeh

2014

Phil. Trans. R. Soc. B

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The centrosome is the main organizer of the microtubule cytoskeleton in animals, higher fungi and several other eukaryotic lineages. Centrosomes are usually located at the centre of cell in tight association with the nuclear envelope and duplicate at each cell cycle. Despite a great structural diversity between the different types of centrosomes, they are functionally equivalent and share at least some of their molecular components. In this paper, we explore the evolutionary origin of the different centrosomes, in an attempt to understand whether they are derived from an ancestral centrosome or evolved independently from the motile apparatus of distinct flagellated ancestors. We then discuss the evolution of centrosome structure and function within the animal lineage.

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Cell differentiation and morphogenesis in the colony-forming choanoflagellate Salpingoeca rosetta

Cited by 222 publications

References 54 publications

A bacterial sulfonolipid triggers multicellular development in the closest living relatives of animals

A bacterial sulfonolipid triggers multicellular development in the closest living relatives of animals

A family of diatom-like silicon transporters in the siliceous loricate choanoflagellates

Exploring the evolutionary history of centrosomes

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