Abstract
A study was made of linolenic acid-dependent oxidative chlorophyll bleaching (CHLOX) by thylakoid membranes from senescing leaf tissue of a normal cultivar (cv. Rossa) and a non-yellowing mutant genotype (Bf 993) of Festuca pratensis Huds. To overcome the problem of variation in levels of endogenous chlorophyll substrate in membranes from different sources, light-harvesting complex (LHC) was used to supplement thylakoid pigment. It was shown that CHLOX is associated with both Photosystem I and LHC-rich thylakoid subfractions but that purified LHC has negligible associated CHLOX activity and stimulates the rate of bleaching by isolated entire chloroplast membranes. Non-senescent tissue of Bf 993 and Rossa had essentially identical thylakoid CHLOX levels, which subsequently declined during senescence in darkness. The half-life of CHLOX from the mutant was three times greater than that of the normal genotype. In both cultivars, the amount of CHLOX assayed in thylakoids isolated at different times during senescence was more than adequate to support the corresponding in-vivo rate of pigment degradation as calculated from the half-life for chlorophyll. It was concluded that the non-yellowing mutation is not expressed through a lack of CHLOX activity. The role of linolenic acid metabolism in the regulation of thylakoid structure and function during senescence, and as a likely site of the non-yellowing lesion, are discussed.
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Abbreviations
- CHLOX:
-
linolenic acid-dependent oxidative chlorophyll bleaching activity
- CHLPX:
-
chlorophyll peroxidase
- CPI:
-
chlorophyll-protein complex I
- LHC:
-
light-harvesting complex
- LNA:
-
linolenic acid
- PSI:
-
photosystem I
- PSII:
-
photosystem II
- S:
-
relative senescence rate
- t 1/2 :
-
lialf time for degradation
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Thomas, H., Lüthy, B. & Matile, P. Leaf senescence in a non-yellowing mutant of Festuca pratensis Huds.. Planta 164, 400–405 (1985). https://doi.org/10.1007/BF00402953
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DOI: https://doi.org/10.1007/BF00402953