Ultrastructure, CO[sub.2] Assimilation and Chlorophyll Fluorescence Kinetics in Photosynthesizing IGlycine max/I Callus and Leaf Mesophyll Tissues

The ultrastructural and functional features of photosynthesizing callus cells are poorly known. Electron microscopy studies on green, compact Glycine max calluses have shown that they are composed of photosynthesizing cells characterized by clear ultrastructural signs of senescence. Studies on chlor...

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Veröffentlicht in:	Horticulturae 2023-11, Vol.9 (11)
Hauptverfasser:	Lysenko, Vladimir, Kirichenko, Evgenya, Logvinov, Alexandr, Azarov, Anatoly, Rajput, Vishnu D, Chokheli, Vasiliy, Chalenko, Elizaveta, Yadronova, Olga, Varduny, Tatyana, Krasnov, Vladimir, Karaseva, Tatyana
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Sprache:	eng
Schlagworte:	Carbon sequestration Chlorophyll Environmental aspects Methods Optical properties Physiological aspects Soybean
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creator	Lysenko, Vladimir Kirichenko, Evgenya Logvinov, Alexandr Azarov, Anatoly Rajput, Vishnu D Chokheli, Vasiliy Chalenko, Elizaveta Yadronova, Olga Varduny, Tatyana Krasnov, Vladimir Karaseva, Tatyana
description	The ultrastructural and functional features of photosynthesizing callus cells are poorly known. Electron microscopy studies on green, compact Glycine max calluses have shown that they are composed of photosynthesizing cells characterized by clear ultrastructural signs of senescence. Studies on chlorophyll fluorescence and CO[sub.2] assimilation kinetics have shown that such cells were still able to maintain photosynthesis but could not compensate for the respiratory CO[sub.2] uptake. Having a one-step CO[sub.2] assimilation kinetics, photosynthesis in calluses differed from photosynthesis in leaves, which had a two-step CO[sub.2] assimilation kinetics. In contrast to leaves, the fluorescence induction curves in G. max calluses strongly differed in shape depending on the color of actinic light (red or blue). Red (in contrast to blue) light excitation did not lead to CO[sub.2] assimilation in the calluses, thus suggesting anoxygenic photosynthesis in this case. In particular, the data obtained indicate that the actinic light spectrum should be considered when cultivating calluses for micropropagation of plants and for callus tissue research.
doi_str_mv	10.3390/horticulturae9111211
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Electron microscopy studies on green, compact Glycine max calluses have shown that they are composed of photosynthesizing cells characterized by clear ultrastructural signs of senescence. Studies on chlorophyll fluorescence and CO[sub.2] assimilation kinetics have shown that such cells were still able to maintain photosynthesis but could not compensate for the respiratory CO[sub.2] uptake. Having a one-step CO[sub.2] assimilation kinetics, photosynthesis in calluses differed from photosynthesis in leaves, which had a two-step CO[sub.2] assimilation kinetics. In contrast to leaves, the fluorescence induction curves in G. max calluses strongly differed in shape depending on the color of actinic light (red or blue). Red (in contrast to blue) light excitation did not lead to CO[sub.2] assimilation in the calluses, thus suggesting anoxygenic photosynthesis in this case. 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subjects	Carbon sequestration Chlorophyll Environmental aspects Methods Optical properties Physiological aspects Soybean
title	Ultrastructure, CO[sub.2] Assimilation and Chlorophyll Fluorescence Kinetics in Photosynthesizing IGlycine max/I Callus and Leaf Mesophyll Tissues
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