Opportunities for, and limitations on, the functioning of very small cells, illustrated by the Chlorophyta and charophycean Streptophyta

John A. Raven, John Beardall

    Research output: Contribution to journalReview article

    Abstract

    The Chlorophyta have both the smallest known eukaryotic cell and the largest known photosynthetic cells, with a smaller size range being found in the algal (charophycean) Streptophyta. Focusing on the smallest cells, predictions of how the limits on miniaturization of essential cell structures (e.g. the occurrence of mitosis with 20, albeit small, chromosomes with high gene density) are related to the size of the smallest green algae, suggest that the smallest green alga is close to the lower limit of cell size. The properties of the smallest green algae agree with predictions based on how physics, chemistry and biochemistry interact with small size for photosynthetic properties such as light harvesting and processing in thylakoids, but do not align so clearly for nutrient acquisition and assimilation. The energetic cost of volume regulation in flagellates in freshwater flagellates may help rationalize the absence from fresh waters of flagellates as small as the marine Micromonas. The minimum size of essential algal cell structures and prey size may help explain why there are no photosynthetic phagomixotrophs smaller than Micromonas.
    Original languageEnglish
    Pages (from-to)1-12
    JournalPerspectives in Phycology
    Volume5
    Issue number1
    Early online date14 Mar 2018
    DOIs
    Publication statusPublished - 1 Jun 2018

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    Chlorophyta
    cell structures
    cells
    prediction
    physics
    thylakoids
    biochemistry
    mitosis
    eukaryotic cells
    assimilation (physiology)
    chemistry
    chromosomes
    nutrients
    genes

    Cite this

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    title = "Opportunities for, and limitations on, the functioning of very small cells, illustrated by the Chlorophyta and charophycean Streptophyta",
    abstract = "The Chlorophyta have both the smallest known eukaryotic cell and the largest known photosynthetic cells, with a smaller size range being found in the algal (charophycean) Streptophyta. Focusing on the smallest cells, predictions of how the limits on miniaturization of essential cell structures (e.g. the occurrence of mitosis with 20, albeit small, chromosomes with high gene density) are related to the size of the smallest green algae, suggest that the smallest green alga is close to the lower limit of cell size. The properties of the smallest green algae agree with predictions based on how physics, chemistry and biochemistry interact with small size for photosynthetic properties such as light harvesting and processing in thylakoids, but do not align so clearly for nutrient acquisition and assimilation. The energetic cost of volume regulation in flagellates in freshwater flagellates may help rationalize the absence from fresh waters of flagellates as small as the marine Micromonas. The minimum size of essential algal cell structures and prey size may help explain why there are no photosynthetic phagomixotrophs smaller than Micromonas.",
    author = "Raven, {John A.} and John Beardall",
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    Opportunities for, and limitations on, the functioning of very small cells, illustrated by the Chlorophyta and charophycean Streptophyta. / Raven, John A.; Beardall, John.

    In: Perspectives in Phycology, Vol. 5, No. 1, 01.06.2018, p. 1-12.

    Research output: Contribution to journalReview article

    TY - JOUR

    T1 - Opportunities for, and limitations on, the functioning of very small cells, illustrated by the Chlorophyta and charophycean Streptophyta

    AU - Raven, John A.

    AU - Beardall, John

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    Y1 - 2018/6/1

    N2 - The Chlorophyta have both the smallest known eukaryotic cell and the largest known photosynthetic cells, with a smaller size range being found in the algal (charophycean) Streptophyta. Focusing on the smallest cells, predictions of how the limits on miniaturization of essential cell structures (e.g. the occurrence of mitosis with 20, albeit small, chromosomes with high gene density) are related to the size of the smallest green algae, suggest that the smallest green alga is close to the lower limit of cell size. The properties of the smallest green algae agree with predictions based on how physics, chemistry and biochemistry interact with small size for photosynthetic properties such as light harvesting and processing in thylakoids, but do not align so clearly for nutrient acquisition and assimilation. The energetic cost of volume regulation in flagellates in freshwater flagellates may help rationalize the absence from fresh waters of flagellates as small as the marine Micromonas. The minimum size of essential algal cell structures and prey size may help explain why there are no photosynthetic phagomixotrophs smaller than Micromonas.

    AB - The Chlorophyta have both the smallest known eukaryotic cell and the largest known photosynthetic cells, with a smaller size range being found in the algal (charophycean) Streptophyta. Focusing on the smallest cells, predictions of how the limits on miniaturization of essential cell structures (e.g. the occurrence of mitosis with 20, albeit small, chromosomes with high gene density) are related to the size of the smallest green algae, suggest that the smallest green alga is close to the lower limit of cell size. The properties of the smallest green algae agree with predictions based on how physics, chemistry and biochemistry interact with small size for photosynthetic properties such as light harvesting and processing in thylakoids, but do not align so clearly for nutrient acquisition and assimilation. The energetic cost of volume regulation in flagellates in freshwater flagellates may help rationalize the absence from fresh waters of flagellates as small as the marine Micromonas. The minimum size of essential algal cell structures and prey size may help explain why there are no photosynthetic phagomixotrophs smaller than Micromonas.

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