Abstract
Diatoms are important contributors to aquatic primary production, and can dominate phytoplankton communities under variable light regimes. We grew two marine diatoms, the small Thalassiosira pseudonana and the large Coscinodiscus radiatus, across a range of temperatures and treated them with a light challenge to understand their exploitation of variable light environments. In the smaller T. pseudonana, photosystem II (PSII) photoinactivation outran the clearance of PSII protein subunits, particularly in cells grown at sub- or supraoptimal temperatures. In turn the absorption cross section serving PSII photochemistry was down-regulated in T. pseudonana through induction of a sustained phase of nonphotochemical quenching that relaxed only slowly over 30 min of subsequent low-light incubation. In contrast, in the larger diatom C. radiatus, PSII subunit turnover was sufficient to counteract a lower intrinsic susceptibility to photoinactivation, and C. radiatus thus did not need to induce sustained nonphotochemical quenching under the high-light treatment. T. pseudonana thus incurs an opportunity cost of sustained photosynthetic down-regulation after the end of an upward light shift, whereas the larger C. radiatus can maintain a balanced PSII repair cycle under comparable conditions.
Highlights
N Diatoms are important contributors to aquatic primary production, and can dominate phytoplankton communities under variable light regimes
Depending on the rate of water mixing and e depth of the upper mixed layer, diatoms can be exposed to episodic excess light, generating stressful conditions is that impair photosynthesis through photoinactivation, down-regulation, or oxidative stress (Long et al, 1994; Lavaud, 2007; Dubinsky and Stambler, 2009; Janknegt et al, 2009)
In comparison with other marine phytoplankton groups, including cyanobacteria and prasinophyte green algae (Six et al, 2007, 2009), diatoms show a lower susceptibility to primary photoinactivation (Key et al, 2010), and distinctive clearance patterns for the PsbA (D1), PsbD (D2), and PsbB (CP47) photosystem II (PSII) subunits upon an increase in light, in comparison with most other taxa examined to date (Wu et al, 2011)
Summary
464 Plant PhysiologyÒ, September 2012, Vol 160, pp. 464–476, www.plantphysiol.org Ó 2012 American Society of Plant Biologists. In T. pseudonana cells maintaining a PSII repair cycle, FV/FM dropped significantly (P , 0.05) during the 90-min high-light exposure, but recovered (P , 0.05). Compared with cells growing at 18°C, the sub- and supraoptimal io growth temperatures of 12°C and 24°C led to significantly larger declines (P , 0.05) in FV/FM over 30 to 60 min before stabilizing late in the high-light treatment. We earlier showed that the primary susceptibility to the photoinactivation of PSII is inversely is proportional to cell volume in diatoms (Key et al., 2010), so small and large diatoms have different balances between light-dependent photoinactivation and the counteracting temperature-dependent metabolic rev pair of PSII. C. radiatus showed lower susceptibility to high-light treatments, with smaller, still significant (P , 0.05), decreases in FV/FM in the cells treated without or with lincomycin at both 18°C and 24°C (Fig. 1, D and E)
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