Abstract
Processes putatively dependent on the galactolipid monogalactosyldiacylglycerol (MGDG) were recently studied using the knockdown monogalactosyldiacylglycerol synthase 1 (mgd1-1) mutant (∼40% reduction in MGDG). Surprisingly, targeting of chloroplast proteins was not affected in mgd1-1 mutants, suggesting they retain sufficient MGDG to maintain efficient targeting. However, in dark-grown mgd1-1 plants the photoactive to photoinactive protochlorophyllide (Pchlide) ratio was increased, suggesting that photoprotective responses are induced in them. Nevertheless, mgd1-1 could not withstand high light intensities, apparently due to impairment of another photoprotective mechanism, the xanthophyll cycle (and hence thermal dissipation). This was mediated by increased conductivity of the thylakoid membrane leading to a higher pH in the thylakoid interior, which impaired the pH-dependent activation of violaxanthin de-epoxidase (VDE) and PsbS. These findings suggest that MGDG contribute directly to the regulation of photosynthesis-related processes.
Key words: conductivity, galactolipid, light stress, photosynthesis, plastid, xanthophyll
The galactolipid monogalactosyldiacylglycerol (MGDG), the major lipid in plastids,1 is mainly synthesised in inner plastid envelopes,2 where monogalactosyldiacylglycerol synthase 1 (MGD1) catalyses the last step of its production.3 Two MGDG-deficient mutants are known: the knockdown mgd1-1 mutant, which accumulates ∼40% less MGDG than wild type,4 and the null mutant mgd1-2, which displays extremely severe defects in chloroplast and plant development.5 Thus, the mgd1-1 mutant is more suitable for assessing putative roles of MGDG in processes such as protein targeting and photoprotection.
There are conflicting indications regarding the involvement of galactolipids in chloroplast protein targeting: some suggest they play an important role,6–10 but not all.11,12 The data recently collected for mgd1-1 do not support MGDG's involvement in protein targeting, since (inter alia) the level of MGDG in mgd1-1 mutants is clearly sufficient for efficient targeting.13 Further, the galactolipid associated with the TOC complex12 is digalactosyldiacylglycerol (DGDG) and the digalactosyldiacylglycerol synthase 1 (dgd1) mutant,14 which has ∼10% of wild-type levels of DGDG, has impaired import efficiency.15,16 Hence, this may indicate that DGDG is relatively more important for chloroplast import than MGDG.
The prolamellar bodies (PLBs) of etioplasts have high lipid-to-protein ratios compared to thylakoids. Their major lipid and protein are MGDG and NADPH:Pchlide oxidoreductase (POR), respectively,17 and MGDG putatively plays an important role, interactively with POR, in the formation of PLBs.18–20 The transformation of PLBs into thylakoids involves phototransformation of photoactive Pchlide (F656), a precursor of chlorophyll. Non-photoactive Pchlide (F631) is susceptible to photooxidative damage, but POR is believed to suppress this.21,22 After excitation at 440 nm, mgd1-1 mutants display distinctly higher fluorescence emission peaks corresponding to photoactive Pchlide than wild type counterparts and (hence) higher photoactive:non-photoactive Pchlide ratios.13 These changes may be photoprotective responses that favour formation of photoactive Pchlide and optimize the plants' opportunities to use light for chlorophyll production, enabling the transformation of etioplasts into chloroplasts.
Interestingly,the xanthophyll cycle, another photoprotective mechanism, is impaired in mgd1-1.13 Normally, the xanthophyll cycle pigment violaxanthin is de-epoxidized into antheraxanthin, and then into zeaxanthin, by the enzyme VDE (Fig. 1), which is dependent on MGDG.23 MGDG is also an integral component of photosynthetic complexes.24–26 Thus, since mgd1-1 mutants have reduced total amounts of xanthophyll and chlorophyll pigments, but increased chlorophyll a/b ratios, their photosynthesis capacity is unsurprisingly reduced, even though the organization of their electron transport chains is not strongly affected by the MGDG deficiency.13
Figure 1.
Reactions of the xanthophyll cycle (adapted from ref. 29). VDE, violaxanthin de-epoxidase; ZE, zeaxanthin epoxidase.
During short-term high light stress, antheraxanthin and zeaxanthin are thought to facilitate dissipation of excess light energy in the PSII antenna bed by non-photochemical quenching.27,28 Upon high light stress the pH decreases, triggering photoprotective mechanisms via changes in the PSII antenna system. The PsbS protein, which is involved in thermal dissipation, is protonated and initiates a conformational change in the PSII antenna bed. This change is further stabilized by the de-epoxidation of violaxanthin to zeaxanthin by the luminal VDE.28 However, the thermal dissipation is impaired in mgd1-1 mutants at high light intensities (>1000 µmol m−2 s−1) making them more susceptible to light stress. Surprisingly, this is not mediated by direct effects on VDE and PsbS activities, but by changes in the proton conductivity of the thylakoid membrane.13
The steady-state capacity of the xanthophyll cycle is reduced in mgd1-1 mutants, due to a ∼40% reduction in the proton motive force (pmf) across their thylakoid membranes, indicating that they have impaired capacities to energize these membranes. Nevertheless, the pmf is more or less equal to wild type under light-limited conditions (200 µmol m−2 s−1 light); it is only the increase in pmf in high light intensities that is impaired in the mutants.13 This leads to the thylakoid lumen being less acidic in mgd1-1 than in wild type, hampering full activation of VDE and PsbS. Thus, the thylakoid lumen pH is above the threshold level required for full activation of PsbS and VDE under steady-state conditions and so de-epoxidation rates are retarded and the equilibrium between zeaxanthin and violaxanthin starts to shift slightly towards violaxanthin (Fig. 2).13 Thus, increased conductivity of the thylakoid membranes is probably responsible for the diminished non-photochemical quenching in mgd1-1, and the findings strongly indicate that MGDG is required for efficient photosynthesis and photoprotection, in addition to being a physical membrane constituent.
Figure 2.
Schematic diagram illustrating the normal mode of action of the xanthophyll cycle. In standard light conditions, V is bound to the photosynthetic complexes and harvests light. In strong light, V is released from the complexes and converted to Z by VDE, which is unable to access V when it is associated with the photosynthetic complexes. The newly formed Z then binds to the photosynthetic complexes (at the PsbS protein), where it dissipates excess energy through NPQ. V, violaxanthin; A, antheraxanthin; Z, zeaxanthin; VDE, violaxanthin de-epoxidase; ZE, zeaxanthin epoxidase. Arrows indicate the directions of reactions.
Footnotes
Previously published online as a Plant Signaling & Behavior E-publication: http://www.landesbioscience.com/journals/psb/article/6908
References
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