Evidence that inducible C-4-type photosynthesis is a chloroplastic CO2-concentrating mechanism in Hydrilla, a submersed monocot

JB Reiskind, TV Madsen, LC VanGinkel, G Bowes

    Research output: Contribution to journalArticleAcademicpeer-review

    Abstract

    Hydrilla verticillata (L.f.) Royle exhibits an inducible C-4- type photosynthetic cycle, but lacks Kranz anatomy. Leaves in the C-4-type state (but not C-3-type) contained up to 5-fold higher internal dissolved inorganic carbon (DIG) concentrations than the medium, indicating that they possessed a CO2-concentrating mechanism (CCM). Several lines of evidence indicated that the chloroplast was the likely site of CO2 generation. From C-4-type leaf [DIC] measurements, the estimated chloroplastic free [CO2] was 400 mmol m(-3). This gave a calculated 2% O-2 inhibition of photosynthesis, which was identical to the measured value, and provided independent evidence that the estimated [CO2] was close to the true value. A homogeneous distribution of DIC in the C-4-type leaf could not account for such a high [CO2], or the resultant low O-2 inhibition. For C-3-type leaves the estimated chloroplastic [CO2] was only 7 mmol m(-3), which gave high, and similar, calculated and measured O-2 inhibition values of 22 and 26%, respectively. The CCM did not appear to be located at the plasma membrane, as it operated at low and high pH, indicating that it was independent of use of HCO3- from the medium. Also, both C-3- and C-4-type Hydrilla leaves showed pH polarity in the light, with abaxial and adaxial boundary layer values of about pH 4.0 and 10.5, respectively. Thus, pH polarity was not a direct component of the CCM, though it probably improved access to HCO3. Additionally, iodoacetamide and methyl viologen greatly reduced abaxial acidification, but not the steady-state CCM. Inhibitor studies suggested that the CCM required photosynthetically generated ATP, but Calvin cycle activity was not essential. Both leaf types accumulated DIC in the dark by an ATP-requiring process, possibly respiration, and C-4-type leaves fixed CO2 at 11.8% of the light rate. The operation of a CCM to minimize photorespiration, and the ability to recapture respiratory CO2 at night, would conserve DIC in a densely vegetated lake environment where daytime [CO2] is severely limiting, while [O-2] and temperatures are high.

    Original languageEnglish
    Pages (from-to)211-220
    Number of pages10
    JournalPlant cell and environment
    Volume20
    Issue number2
    Publication statusPublished - Feb-1997

    Keywords

    • Hydrilla verticillata
    • Hydrocharitaceae
    • bicarbonate use
    • C-3 photosynthesis
    • C-4 photosynthesis
    • inorganic carbon
    • O-2 inhibition
    • pH polarity
    • AQUATIC MACROPHYTES
    • PLANTS
    • CARBOXYLASES
    • ANGIOSPERMS
    • TRANSPORT
    • ELODEA
    • LEAVES
    • CELLS
    • STATE
    • POOL

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