Photosynthetica 2025, 63(1):46-50 | DOI: 10.32615/ps.2025.004

Heat-induced F0-fluorescence rise is not an indicator of severe tissue necrosis in thermotolerance assays of young and mature leaves of a tropical tree species, Calophyllum inophyllum

K. WINTER, M. GARCIA, A. VIRGO
Smithsonian Tropical Research Institute, Panama City, Republic of Panama

In heating experiments with leaves, the temperature at which dark-level F0 chlorophyll a fluorescence begins to rise, Tcrit, is widely used as an indicator of photosystem II thermotolerance. However, little is known about how Tcrit correlates with irreversible leaf tissue damage. Young and mature leaves of the tropical tree species Calophyllum inophyllum were heated stepwise from 30 to 55°C, at 1°C min-1. Tcrit was 47°C in young leaves and 49°C in mature leaves. Contrary to the higher Tcrit in mature leaves, heating to 55°C elicited greater tissue damage in mature than in young leaves. Young and mature leaves heated to their respective Tcrit or Tcrit + 2°C exhibited no or little tissue necrosis after 14 d of post-culture. It is concluded that measurements of the temperature-dependent F0 fluorescence rise underestimate the thermal thresholds above which significant irreversible leaf damage occurs.

Additional key words: chlorophyll a fluorescence; global warming; heat tolerance; necrosis; tropical trees.

Received: September 27, 2024; Revised: January 27, 2025; Accepted: February 3, 2025; Prepublished online: February 27, 2025; Published: March 27, 2025  Show citation

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WINTER, K., GARCIA, M., & VIRGO, A. (2025). Heat-induced F0-fluorescence rise is not an indicator of severe tissue necrosis in thermotolerance assays of young and mature leaves of a tropical tree species, Calophyllum inophyllum. Photosynthetica63(1), 46-50. doi: 10.32615/ps.2025.004
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    References

    1. Arnold P.A., Briceño V.F., Gowland K.M. et al.: A high-throughput method for measuring critical thermal limits of leaves by chlorophyll imaging fluorescence. - Funct. Plant Biol. 48: 634-646, 2021. Go to original source...
    2. Berry J., Björkman O.: Photosynthetic response and adaptation to temperature in higher plants. - Annu. Rev. Plant Physiol. 31: 491-543, 1980. Go to original source...
    3. Bilger H.-W., Schreiber U., Lange O.L.: Determination of leaf heat resistance: comparative investigation of chlorophyll fluorescence changes and tissue necrosis methods. - Oecologia 63: 256-262, 1984. Go to original source...
    4. Braun V., Buchner U., Neuner G.: Thermotolerance of photosystem 2 of three alpine plant species under field conditions. - Photosynthetica 40: 587-595, 2002. Go to original source...
    5. Cunningham S.C., Read J.: Foliar temperature tolerance of temperate and tropical evergreen rain forest trees of Australia. - Tree Physiol. 26: 1435-1443, 2006. Go to original source...
    6. Didden-Zophy B., Nobel P.S.: High temperature tolerance and heat acclimation of Opuntia bigelovii. - Oecologia 52: 176-180, 1982. Go to original source...
    7. Doughty C.E., Goulden M.L.: Are tropical forests near a high temperature threshold? - J. Geophys. Res. 113: G00B07, 2008. Go to original source...
    8. Feeley K., Martinez-Villa J., Perez T. et al.: The thermal tolerances, distributions, and performances of tropical montane tree species. - Front. For. Glob. Change 3: 25, 2020. Go to original source...
    9. Frolec J., Ilík P, Krchňák P. et al.: Irreversible changes in barley leaf chlorophyll fluorescence detected by the fluorescence temperature curve in a linear heating/cooling regime. - Photosynthetica 46: 537-546, 2008. Go to original source...
    10. Gauthey A., Kahmen A., Limousin J.-M. et al.: High heat tolerance, evaporative cooling, and stomatal decoupling regulate canopy temperature and their safety margins in three European oak species. - Glob. Change Biol. 30: e17439, 2024. Go to original source...
    11. Guissé B., Srivastava A., Strasser R.J.: The polyphasic rise of the chlorophyll a fluorescence (O-K-J-I-P) in heat-stressed leaves. - Arch. Sci. 48: 147-160, 1995.
    12. Hüve K., Bichele I., Rasulov B., Niinemets Ü.: When is it too hot for photosynthesis: heat-induced instability of photosynthesis in relation to respiratory burst, cell permeability changes and H2O2 formation. - Plant Cell Environ. 34: 113-126, 2011. Go to original source...
    13. Chen S., Yang J., Zhang M. et al.: Classification and characteristics of heat tolerance in Ageratina adenophora populations using fast chlorophyll a fluorescence rise O-J-I-P. - Environ. Exp. Bot. 122: 126-140, 2016. Go to original source...
    14. Ilík P., Špundová M., Šicner M. et al.: Estimating heat tolerance of plants by ion leakage: a new method based on gradual heating. - New Phytol. 218: 1278-1287, 2018. Go to original source...
    15. Kautsky H., Hirsch A.: Neue Versuche zur Kohlensäureassimilation. [New experiments on carbonic acid assimilation.] - Naturwissenschaften 19: 964, 1931. [In German] Go to original source...
    16. Krause G.H., Cheesman A.W., Winter K. et al.: Thermal tolerance, net CO2 exchange and growth of a tropical tree species, Ficus insipida, cultivated at elevated daytime and nighttime temperatures. - J. Plant Physiol. 170: 822-827, 2013. Go to original source...
    17. Krause G.H., Winter K., Krause B. et al.: High-temperature tolerance of a tropical tree, Ficus insipida: methodological reassessment and climate change considerations. - Funct. Plant Biol. 37: 890-900, 2010. Go to original source...
    18. Krause G.H., Winter K., Krause B., Virgo A.: Light-stimulated heat tolerance in leaves of two neotropical tree species, Ficus insipida and Calophyllum longifolium. - Funct. Plant Biol. 42: 42-51, 2015. Go to original source...
    19. Kullberg A.T., Coombs L., Ahuanari R.D.S. et al.: Leaf thermal safety margins decline at hotter temperatures in a natural warming 'experiment' in the Amazon. - New Phytol. 241: 1447-1463, 2024. Go to original source...
    20. Lange O.L.: Die Hitzeresistenz einheimischer immer- und wintergrüner Pflanzen im Jahresverlauf. [Heat resistance of native ever- and wintergreen plants during the annual cycle.] - Planta 56: 666-683, 1961. [In German] Go to original source...
    21. Larcher W., Wagner J.: Temperaturgrenzen der CO2-Aufnahme und Temperaturresistenz der Blätter von Gebirgspflanzen im vegetationsaktiven Zustand. [Temperature limits of CO2-uptake and temperature resistance of leaves of mountain plants in the vegetation-active state.] - Oecol. Plantarum 11: 361-374, 1976. [In German]
    22. Lazár D., Ilík P.: High-temperature induced chlorophyll fluorescence changes in barley leaves. Comparison of the critical temperatures determined from fluorescence induction and from fluorescence temperature curve. - Plant Sci. 124: 159-164, 1997. Go to original source...
    23. Lazár D., Ilík P., Nauš J.: An appearance of K-peak in fluorescence induction depends on the acclimation of barley leaves to higher temperatures. - J. Lumin. 72-74: 595-596, 1997. Go to original source...
    24. Lorenz R.W.: High temperature tolerance of forest trees. Technical Bulletin No. 141. Pp. 25. University of Minnesota, Agricultural Experiment Station, St. Paul 1939.
    25. Middleby K.B., Cheesman A.W., Cernusak L.A.: Impacts of elevated temperature and vapour pressure deficit on leaf gas exchange and plant growth across six tropical rainforest tree species. - New Phytol. 243: 648-661, 2024. Go to original source...
    26. Murchie E.H., Lawson T.: Chlorophyll fluorescence analysis: a guide to good practice and understanding some new applications. - J. Exp. Bot. 64: 3983-3998, 2013. Go to original source...
    27. Nauš J., Dvořák R., Kuropatwa R., Mašláň M.: Transitions in the thylakoid membranes of barley leaves studied by chlorophyll fluorescence temperature curve. - Photosynthetica 27: 563-570, 1992b.
    28. Nauš J., Kuropatwa R., Klinkovskÿ T. et al.: Heat injury of barley leaves detected by the chlorophyll fluorescence temperature curve. - BBA-Bioenergetics 1101: 359-362, 1992a. Go to original source...
    29. Neuner G., Buchner O.: The dose makes the poison: the longer the heat lasts, the lower the temperature for functional damage and impairment. - Environ. Exp. Bot. 212: 105305, 2023. Go to original source...
    30. Niinemets Ü.: When leaves go over the thermal edge. - Plant Cell Environ. 41: 1247-1250, 2018. Go to original source...
    31. O'Sullivan O.S., Heskel M.A., Reich P.B. et al.: Thermal limits of leaf metabolism across biomes. - Glob. Change Biol. 23: 209-223, 2017. Go to original source...
    32. Posch B.C., Hammer J., Atkin O.K. et al.: Wheat photosystem II heat tolerance responds dynamically to short- and long-term warming. - J. Exp. Bot. 73: 3268-3282, 2022. Go to original source...
    33. POWO: Plants of the world online. Royal Botanic Gardens, Kew, 2024. Available at: https://powo.science.kew.org/.
    34. Sapper I.: Versuche zur Hitzeresistenz der Pflanzen. [Experiments on the heat resistance of plants.] - Planta 23: 518-556, 1935. [In German] Go to original source...
    35. Schreiber U., Berry J.A.: Heat-induced changes of chlorophyll fluorescence in intact leaves correlated with damage of the photosynthetic apparatus. - Planta 136: 233-238, 1977. Go to original source...
    36. Schreiber U., Schliwa U., Bilger W.: Continuous recording of photochemical and non-photochemical chlorophyll fluorescence quenching with a new type of modulation fluorometer. - Photosynth. Res. 10: 51-62, 1986. Go to original source...
    37. Slot M., Cala D., Aranda J. et al.: Leaf heat tolerance of 147 tropical forest species varies with elevation and leaf functional traits, but not with phylogeny. - Plant Cell Environ. 44: 2414-2427, 2021. Go to original source...
    38. Strasser R.J., Tsimilli-Michael M., Srivastava A.: Analysis of the chlorophyll a fluorescence transient. - In: Papageorgiou G.C., Govindjee (ed.): Chlorophyll a Fluorescence: A Signature of Photosynthesis. Advances in Photosynthesis and Respiration. Pp. 321-362. Springer, Dordrecht 2004. Go to original source...
    39. Tiwari R., Gloor E., da Cruz W.J.A. et al.: Photosynthetic quantum efficiency in south-eastern Amazonian trees may be already affected by climate change. - Plant Cell Environ. 44: 2428-2439, 2021. Go to original source...
    40. Weng J.-H., Lai M.-F.: Estimating heat tolerance among plant species by two chlorophyll fluorescence parameters. - Photosynthetica 43: 439-444, 2005. Go to original source...
    41. Winter K., Krüger Nuñez C.R., Slot M., Virgo A.: In thermotolerance tests of tropical tree leaves, the chlorophyll fluorescence parameter Fv/Fm measured soon after heat exposure is not a reliable predictor of tissue necrosis. - Plant Biol. 27: 146-153, 2025. Go to original source...
    42. Winter K.: Are tropical forests approaching critical temperature thresholds? - Plant Biol. 26: 495-498, 2024. Go to original source...
    43. Wright S.J., Muller-Landau H.C., Schipper J.: The future of tropical species on a warmer planet. - Conserv. Biol. 23: 1418-1426, 2009. Go to original source...
    44. Yeh D.M., Hsu P.Y.: Heat tolerance in English ivy as measured by an electrolyte leakage technique. - J. Hortic. Sci. Biotech. 79: 298-302, 2004. Go to original source...
    45. Zhu L., Bloomfield K.J., Hocart C.H. et al.: Plasticity of photosynthetic heat tolerance in plants adapted to thermally contrasting biomes. - Plant Cell Environ. 41: 1251-1262, 2018. Go to original source...
    46. Zhu L., Scafaro A.P., Vierling E. et al.: Heat tolerance of a tropical-subtropical rainforest tree species Polyscias elegans: time-dependent dynamic responses of physiological thermostability and biochemistry. - New Phytol. 241: 715-731, 2024. Go to original source...

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