The cell biology and genome of Stentor pyriformis, a giant cell that embeds symbiotic algae in a microtubule meshwork Journal Article


Authors: Boudreau, V.; Albright, A. R.; Larson, B. T.; Gerbich, T. M.; Fadero, T.; Yan, V.; Lucas-DeMott, A.; Yung, J.; Moulin, S. L. Y.; Descovich, C. P.; Slabodnick, M. M.; Burlacot, A.; Wang, J. R.; Niyogi, K. K.; Marshall, W. F.
Article Title: The cell biology and genome of Stentor pyriformis, a giant cell that embeds symbiotic algae in a microtubule meshwork
Abstract: Endosymbiotic events in which an endosymbiont is retained within a cell that remains capable of phagocytosis, a situation known as mixotrophy, provide potentially important clues about the eukaryotic evolution. Here we describe the cell biology and genome of the giant mixotrophic ciliate Stentor pyriformis. We show that S. pyriformis contains Chlorella variabilis as an endosymbiont that retains the ability to live outside the host. Within the host, the Chlorella cells surrounded by microtubule “baskets” near the cell surface. Photosynthetic efficiency of the Chlorella is reduced inside the Stentor cell compared with outside the host, due to increased nonphotochemical quenching. S. pyriformis displays positive phototaxis via directed swimming that requires the presence of the Chlorella, implying a potential flow of information from the symbiont to direct the orientation and swimming of the host cell. We sequenced the S. pyriformis genome and found that it employs a standard genetic code, similar to other Stentor species but different from most other ciliates. We propose that S. pyriformis will serve as a useful model system for studying endosymbiosis, with unique advantages in terms of size and regenerative ability as well as distinct cellular and genomic features compared with other mixotrophic ciliate models. © 2025 Boudreau et al.
Keywords: controlled study; genetics; nonhuman; cytology; metabolism; physiology; genome; phagocytosis; microtubule; microtubules; giant cell; genetic code; pharmacology; phylogeny; cell surface; photosynthesis; symbiosis; chlorella; nonphotochemical quenching; symbiont; alga; female; article; regenerative ability; ciliate; swimming; endosymbiont; ciliophora; endosymbiosis; mixotroph; mixotrophy; phototaxis
Journal Title: Molecular Biology of the Cell
Volume: 36
Issue: 4
ISSN: 1059-1524
Publisher: The American Society for Cell Biology  
Date Published: 2025-04-01
Start Page: ar44
Language: English
DOI: 10.1091/mbc.E24-12-0571
PUBMED: 39937680
PROVIDER: scopus
PMCID: PMC12005096
DOI/URL:
Notes: Article -- Source: Scopus
Altmetric
Citation Impact
BMJ Impact Analytics
MSK Authors