Abstract
Although plants rely on light to drive energy production via photosynthesis, excess light can be harmful. Plants have evolved photoprotective mechanisms to mitigate this threat, including thermal energy dissipation, the most common form of which involves de-epoxidized constituents of the xanthophyll cycle facilitating the conversion of excess excitation energy to heat. A role in photoprotection has also been proposed for red anthocyanins when they accumulate near the adaxial leaf surface. Here, we compared the response to experimental light stress of a red-leafed (anthocyanin rich) and a green-leafed variety of coleus [Solenostemon scutellarioides (L.) Codd], examining chlorophyll fluorescence emission and pigment composition. After experimentally imposed intense white light, red- and green-leafed coleus exhibited manifestations of light stress (decreased photosystem II quantum efficiency) of a similar magnitude. This, considered alone, could be interpreted as evidence that anthocyanins do not serve a photoprotective role. However, during excess light exposure, the green-leafed variety employed a greater level of thermal energy dissipation and possessed correspondingly higher xanthophyll cycle pool sizes and de-epoxidation states. During exposure to red light, which anthocyanins absorb very poorly, levels of thermal energy dissipation did not differ between coleus varieties. Taken together, our findings suggest that adaxial anthocyanins minimize stress associated with excess light absorption and that the green-leafed variety of coleus compensated for its much lower levels of adaxial anthocyanins by invoking higher levels of energy dissipation. Thus, anthocyanin accumulation should be considered alongside the suite of photoprotective mechanisms employed by photosynthetic tissues.
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References
Adams WW III, Demmig-Adams B (1992) Operation of the xanthophyll cycle in higher plants in response to diurnal changes in incident sunlight. Planta 186:390–398
Baker NR (2008) Chlorophyll fluorescence: a probe of photosynthesis in vivo. Annu Rev Plant Biol 59:89–113
Barker DH, Seaton GGR, Robinson SA (1997) Internal and external photoprotection in developing leaves of the CAM plant Cotyledon orbiculata. Plant, Cell Environ 20:617–624
Bilger W, Björkman O (1990) Role of the xanthophyll cycle in photoprotection elucidated by measurements of light-induced absorbance changes, fluorescence and photosynthesis in leaves of Hedera canariensis. Photosynth Res 25:173–185
Brugnoli E, Björkman O (1992) Chloroplast movements in leaves: influence on chlorophyll to measurements of light-induced absorbance changes related to ΔpH and zeaxanthin formation. Photosynth Res 32:23–35
Burger J, Edwards GE (1996) Photosynthetic efficiency, and photodamage by UV and visible radiation, in red versus green leaf Coleus varieties. Plant Cell Physiol 37:395–399
Close DC, Beadle CL (2003) The ecophysiology of foliar anthocyanin. Bot Rev 69:149–161
Demmig-Adams B, Cohu CM, Muller O, Adams WW III (2012) Modulation of photosynthetic energy conversion efficiency in nature: from seconds to seasons. Photosynth Res 113:75–88
Demmig-Adams B, Adams WW III (1992) Photoprotection and other responses of plants to high light stress. Annu Rev Plant Physiol Plant Mol Biol 43:599–626
Demmig-Adams B, Adams WW III (2006) Photoprotection in an ecological context: the remarkable complexity of thermal energy dissipation. New Phytol 172:11–21
Dodd IC, Critchley C, Woodall GS, Stewart GR (1998) Photoinhibition in differently coloured juvenile leaves of Syzygium species. J Exp Bot 49:1437–1445
Ehleringer J, Björkman O (1978) Pubescence and leaf spectral characteristics in a desert shrub, Encelia farinosa. Oecologia 36:151–162
Esteban R, Ferńandez-Maŕın B, Becerril JM, Garćıa-Plazaola JI (2008) Photoprotective implications of leaf variegation in E. dens-canis L. and P. officinalis L. J Plant Physiol 165:1255–1263
Field TS, Lee DW, Holbrook NM (2001) Why leaves turn red in autumn. The role of anthocyanins in senescing leaves of red-osier dogwood. Plant Physiol 127:566–574
Gilmore AM, Yamamoto HY (1991) Resolution of lutein and zeaxanthin using a non-endcapped, lightly carbon-loaded C-18 high-performance liquid-chromatographic column. J Chromatogr 543:137–145
Givnish TJ (1988) Adaptations to sun and shade: a whole plant perspective. Aust J Plant Physiol 15:63–92
Gould KS (2010) Muriel Wheldale Onslow and the rediscovery of anthocyanin function in plants. In: Santos-Buelga C, Escribano-Bailon MT, Lattanzio V (eds) Recent advances in polyphenols research, vol 2. Blackwell Publishing, New York, pp 206–225
Gould KS, Kuhn DN, Lee DW, Oberbauer SF (1995) Why leaves are sometimes red. Nature 378:241–242
Gould KS, Markham KR, Smith RH, Goris JJ (2000) Functional role of anthocyanins in the leaves of Quintinia serrata A. Cunn. J Exp Bot 51:1107–1115
Gould KS, Dudle DA, Neufeld HS (2010) Why some stems are red: cauline anthocyanins shield photosystem II against high light stress. J Exp Bot 61:2707–2717
Grace SC, Logan BA (1996) Acclimation of foliar antioxidant systems to growth irradiance in three broad-leaved evergreen species. Plant Physiol 112:1631–1640
Haupt W, Scheuerlein R (1990) Chloroplast movement. Plant Cell Environ 13:595–614
Hatier J-HB, Clearwater MJ, Gould KS (2013) The functional significance of black-pigmented leaves: photosynthesis, photoprotection, and productivity in Ophiopogon planiscapus ‘nigrescens’. PLoS One 8:e67850
Henry A, Chopra S, Clark DG, Lynch JP (2012) Responses to low phosphorus in high and low foliar anthocyanin coleus (Solenostemon scutellarioides) and maize (Zea mays). Funct Plant Biol 39:255–265
Hughes NM, Smith WK (2007) Attenuation of incident light in Galax urceolata (Diapensiaceae): concerted influence of adaxial and abaxial anthocyaninc layers of photoprotection. Am J Bot 94:784–790
Hughes NM, Neufeld HS, Burkey KO (2005) Functional role of anthocyanins in high-light winter leaves of the evergreen herb Galax urceolata. New Phytol 168:575–587
Hughes NM, Morley CB, Smith WK (2007) Coordination of anthocyanin decline and photosynthetic maturation in juvenile leaves of three deciduous tree species. New Phytol 175:675–685
Hughes NM, Burkey KO, Cavendar-Bares J, Smith WK (2012) Xanthophyll cycle pigment and antioxidant profiles of winter-red (anthocyanic) and winter-green (acyanic) angiosperm evergreen species. J Exp Bot 63:1895–1905
Jahns P, Holzwarth AR (2012) The role of the xanthophyll cycle and of lutein in photoprotection of photosystem II. Biochim Biophys Acta Bioenerg 1817:182–193
Kyparissis A, Grammatikopoulos G, Manetas Y (2007) Leaf morphological and physiological adjustments to the spectrally selective shade imposed by anthocyanins in Prunus cerasifera. Tree Physiol 27:849–857
Lee DW, O’Keefe J, Holbrook NM, Field TS (2003) Pigment dynamics and autumn leaf senescence in a New England deciduous forest, eastern USA. Ecol Res 18:677–694
Liakpoulos G, Spanorigas I (2012) Foliar anthicyanins in Pelargonium x hortorum are unable to alleviate light stress under photoinhibitory conditions. Photosynthetica 50:254–262
Liakopoulos G, Nikolopoulos D, Klouvatou A, Vekkos K-A, Manetas Y, Karabourniotis G (2006) The photoprotective role of epidermal anthocyanins and surface pubescence in young leaves of grapevine (Vitis vinifera). Ann Bot 98:257–265
Logan BA (2006) Oxygen metabolism and stress physiology. In: Wise RR, Hoober JK (eds) The structure and function of plastids. Kluwer Academic Publishers, Dorderecht, pp 539–553
Logan BA, Barker DH, Demmig-Adams B, Adams WW III (1996) Acclimation of leaf carotenoid composition and ascorbate levels to gradients in the light environment within an Australian rainforest. Plant Cell Environ 19:1083–1090
Logan BA, Demmig-Adams B, Adams WW III, Grace SC (1998) Antioxidation and xanthophyll cycle-dependent energy dissipation in Cucurbita pepo and Vinca major acclimated to four growth irradiances in the field. J Exp Bot 49:1869–1879
Logan BA, Demmig-Adams B, Adams WW III (1999) Acclimation of photosynthesis to the environment. In: Singhal GS, Renger G, Sopory SK, Irrgang K-D, Govindjee (eds) Concepts in photobiology: photosynthesis and photomorphogenesis. Narosa Publishing House, New Dehli, pp 477–512
Logan BA, Demmig-Adams B, Adams WW III, Bilger W (2014) Context, quantification, and measurement guide for non-photochemical quenching (NPQ) of chlorophyll fluorescence. In: Demmig-Adams B, Garab G, Adams WW III, Govindjee (eds) Non-photochemical fluorescence quenching and energy dissipation in plants, algae, and cyanobacteria. advances in photosynthesis and respiration, vol 40. Springer, Dordrecht, pp 187–201
Manetas Y, Drinia A, Petropoulou Y (2002) High contents of anthocyanins in young leaves are correlated with low pools of xanthophyll cycle components and low risk of photoinhibition. Photosynthetica 40:349–354
Manetas Y, Petropoulou Y, Psaras GK, Drinia A (2003) Exposed red (anthocyanic) leaves of Quercus coccifera display shade characteristics. Funct Plant Biol 30:265–270
Melis A (1999) Photosystem II damage and repair cycle in chloroplasts: what modulates the rate of photodamage in vivo? Trends Plant Sci 4:130–135
Mooney HA, Ehleringer J, Björkman O (1977) The leaf energy balance of leaves of the evergreen desert shrub Atriplex hymenelytra. Oecologia 29:301–310
Neill SO, Gould KS (2003) Anthocyanins in leaves: light attenuators or antioxidants? Funct Plant Biol 30:865–873
Neilsen SL, Simonsen A-M (2011) Photosynthesis and photoinhibition in two differently couloured varieties of oxalis triangularis—the effect of anthocyanin content. Photosynthetica 49:346–352
Nikiforou C, Manetas Y (2010) Strength of winter leaf redness as an indicator of stress vulnerable individuals in (degree symbol shows up here on my computer) Pistacia lentiscus. Flora Morphol Distrib Funct Ecol Plants 205:424–427
Pietrini F, Iannelli MA, Massacci A (2002) Anthocyanin accumulation in the illuminated surface of maize leaves enhances protection from photo-inhibitory risks at low temperature, without further limitation to photosynthesis. Plant Cell Environ 25:1251–1259
Ruban AV, Johnson MP, Duffy CDP (2012) The photoprotective molecular switch in the photosystem II antenna. Biochim Biophys Acta Bioenerg 1817:167–181
Schreiber U, Schliwa U, Bilger W (1986) Continuous recording of photochemical and nonphotochemical chlorophyll fluorescence quenching with a new type of modulation fluorometer. Photosynth Res 10:51–62
Solovchenko A (2010) Localization of screening pigments within plant cells and tissues. In: Martinac B (ed) Photoprotection in plants, springer series in biophysics, vol 14. Springer, Berlin, pp 67–88
Steyn WJ, Wand SJE, Jacobs G, Rosecrance RD, Roberts SC (2009) Evidence for a photoprotective function of low-temperature-induced anthocyanin accumulation in apple and pear peel. Physiol Plant 136:461–472
Thornber JP, Peter GF, Morishige DT, Gómez S, Anandan S, Welty BA, Lee A, Kerfeld C, Takeuchia T, Preiss S (1993) Light harvesting in photosystems I and II. Biochem Soc Trans 21:15–18
Valladares F, Pearcy RW (1998) The functional ecology of shoot architecture in sun and shade plants of Heteromeles arbutifolia M. Roem., a Californian chaparral shrub. Oecologia 114:1–10
Williams WE, Gorton HL, Witiak SM (2003) Chloroplast movements in the field. Plant Cell Environ 26:2005–2014
Zeliou K, Manetas Y, Petropoulou Y (2009) Transient winter leaf reddening in Cistus creticus characterizes weak (stress-sensitive) individuals, yet anthocyanins cannot alleviate the adverse effects on photosynthesis. J Exp Bot 60:3031–3042
Zhang K-M, Yu H-J, Shi K, Zhou Y-H, Yu J-Q, Xia X-J (2010) Photoprotective roles of anthocyanins in Begonia semperflorens. Plant Sci 179:202–208
Acknowledgments
This work was supported by the Bowdoin College, a Howard Hughes Medical Institute Summer Research Fellowship [to W.C.S.], United States Department of Agriculture [MER-2002–04818], and the National Science Foundation [DUE 0088517]. We thank an anonymous reviewer for helpful comments on our original submission.
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Logan, B.A., Stafstrom, W.C., Walsh, M.J.L. et al. Examining the photoprotection hypothesis for adaxial foliar anthocyanin accumulation by revisiting comparisons of green- and red-leafed varieties of coleus (Solenostemon scutellarioides). Photosynth Res 124, 267–274 (2015). https://doi.org/10.1007/s11120-015-0130-0
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DOI: https://doi.org/10.1007/s11120-015-0130-0