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Cell morphological plasticity in response to substrate availability of a cosmopolitan polymorphic yeast from the open ocean

Cell morphological plasticity in response to substrate availability of a cosmopolitan polymorphic yeast from the open ocean
Cell morphological plasticity in response to substrate availability of a cosmopolitan polymorphic yeast from the open ocean

Polymorphic yeasts can switch between unicellular division and multicellular filamentous growth. Although prevalent in aquatic ecosystems, such as the open ocean, we have a limited understanding of the controlling factors on their morphological variation in an aquatic ecology context. Here we show that substrate concentration regulates cell morphogenesis in a cosmopolitan polymorphic yeast, Aureobasidium pullulans, isolated from the pelagic open ocean and analyzed in liquid batch culture. Filamentous cell development was triggered only under high initial substrate conditions, suggesting that hyphal growth could be more advantageous under eutrophic conditions and may influence pelagic fungal interactions with particulate organic matter. Filamentous growth proportionally declined before the exhaustion of substrate and before budding yeast-type cell division entered stationary phase, possibly modulated by quorum sensing as previously evidenced in other polymorphic yeasts. We also found that budding yeast-type unicells decreased in size and became more elongated in shape in response to substrate depletion, resulting in higher cell surface area to volume ratios, which could affect yeast dispersal and/or provide a nutrient uptake advantage under oligotrophic conditions. Our results demonstrate resource-responsive morphological plasticity in a marine-derived polymorphic yeast, providing mechanistic insight into the ability of fungi to survive fluctuating environmental conditions such as in the open ocean.

Aquatic, carbon, cell shape, cell size, fungi, marine
0027-5514
Diver, Poppy
584f5b12-4b30-46cb-a3ac-892c02211f78
Ward, Ben A.
9063af30-e344-4626-9470-8db7c1543d05
Cunliffe, Michael
e6498f5a-80c4-43f5-9cc0-f4a781d32ba9
Diver, Poppy
584f5b12-4b30-46cb-a3ac-892c02211f78
Ward, Ben A.
9063af30-e344-4626-9470-8db7c1543d05
Cunliffe, Michael
e6498f5a-80c4-43f5-9cc0-f4a781d32ba9

Diver, Poppy, Ward, Ben A. and Cunliffe, Michael (2024) Cell morphological plasticity in response to substrate availability of a cosmopolitan polymorphic yeast from the open ocean. Mycologia. (doi:10.1080/00275514.2024.2418784).

Record type: Article

Abstract

Polymorphic yeasts can switch between unicellular division and multicellular filamentous growth. Although prevalent in aquatic ecosystems, such as the open ocean, we have a limited understanding of the controlling factors on their morphological variation in an aquatic ecology context. Here we show that substrate concentration regulates cell morphogenesis in a cosmopolitan polymorphic yeast, Aureobasidium pullulans, isolated from the pelagic open ocean and analyzed in liquid batch culture. Filamentous cell development was triggered only under high initial substrate conditions, suggesting that hyphal growth could be more advantageous under eutrophic conditions and may influence pelagic fungal interactions with particulate organic matter. Filamentous growth proportionally declined before the exhaustion of substrate and before budding yeast-type cell division entered stationary phase, possibly modulated by quorum sensing as previously evidenced in other polymorphic yeasts. We also found that budding yeast-type unicells decreased in size and became more elongated in shape in response to substrate depletion, resulting in higher cell surface area to volume ratios, which could affect yeast dispersal and/or provide a nutrient uptake advantage under oligotrophic conditions. Our results demonstrate resource-responsive morphological plasticity in a marine-derived polymorphic yeast, providing mechanistic insight into the ability of fungi to survive fluctuating environmental conditions such as in the open ocean.

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More information

Accepted/In Press date: 11 October 2024
e-pub ahead of print date: 25 November 2024
Additional Information: P.D. was supported by the Natural Environment Research Council INSPIRE Doctoral Training Partnership [grant number NE/S007210/1]. P.D. and M.C. were supported by the European Research Council project MYCO-CARB [grant number 772584]. B.A.W. was funded by a Royal Society University Research Fellowship.
Keywords: Aquatic, carbon, cell shape, cell size, fungi, marine
Learn more about School of Ocean and Earth Science research

Identifiers

Local EPrints ID: 496734
URI: http://eprints.soton.ac.uk/id/eprint/496734
DOI: doi:10.1080/00275514.2024.2418784
ISSN: 0027-5514
PURE UUID: 0a834f86-570f-4295-a08f-08a9dceadfde
ORCID for Poppy Diver: ORCID iD orcid.org/0000-0002-9949-8392
ORCID for Ben A. Ward: ORCID iD orcid.org/0000-0003-1290-8270

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Date deposited: 07 Jan 2025 22:10
Last modified: 15 May 2025 01:57

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Contributors

Author: Poppy Diver ORCID iD
Author: Ben A. Ward ORCID iD
Author: Michael Cunliffe

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