Abstract
During leaf senescence, chlorophyll is removed from thylakoid membranes and converted in a multistep pathway to colorless breakdown products that are stored in vacuoles. Dephytylation, an early step of this pathway, increases water solubility of the breakdown products. It is widely accepted that chlorophyll is converted into pheophorbide via chlorophyllide. However, chlorophyllase, which converts chlorophyll to chlorophyllide, was found not to be essential for dephytylation in Arabidopsis thaliana. Here, we identify pheophytinase (PPH), a chloroplast-located and senescence-induced hydrolase widely distributed in algae and land plants. In vitro, Arabidopsis PPH specifically dephytylates the Mg-free chlorophyll pigment, pheophytin (phein), yielding pheophorbide. An Arabidopsis mutant deficient in PPH (pph-1) is unable to degrade chlorophyll during senescence and therefore exhibits a stay-green phenotype. Furthermore, pph-1 accumulates phein during senescence. Therefore, PPH is an important component of the chlorophyll breakdown machinery of senescent leaves, and we propose that the sequence of early chlorophyll catabolic reactions be revised. Removal of Mg most likely precedes dephytylation, resulting in the following order of early breakdown intermediates: chlorophyll --> pheophytin --> pheophorbide. Chlorophyllide, the last precursor of chlorophyll biosynthesis, is most likely not an intermediate of breakdown. Thus, chlorophyll anabolic and catabolic reactions are metabolically separated.
Highlights
Loss of green color is the most obvious sign of leaf senescence
Similar to other genes involved in chlorophyll catabolism (SGR1, NON-YELLOW COLORING1 (NYC1), and pheide a oxygenase (PAO)), expression of the candidates was expected to be rather high during senescence
Whereas red chlorophyll catabolites found in acd2-2 during senescence are localized inside the vacuole (Pruzinskaet al., 2007), pheide a accumulating in pao1 is retained in the plastid
Summary
Loss of green color is the most obvious sign of leaf senescence. A pathway of chlorophyll breakdown, comprising several enzymic reactions, has been elucidated in recent years (Hortensteiner, 2006; Krautler and Hortensteiner, 2006). The pathway starts with the removal of phytol and Mg by chlorophyllase (Willstatter and Stoll, 1913) and metalchelating substance (Suzuki et al, 2005), respectively, before the porphyrin ring of the resulting intermediate, pheophorbide (pheide), is oxygenolytically opened by pheide a oxygenase (PAO) (Hortensteiner et al, 1998). The product of this reaction is red chlorophyll catabolite, which, without release from PAO, is. The SGR genes encode a family of novel chloroplast-located proteins, which most likely are required for chlorophyll-protein complex dismantling as a prerequisite for chlorophyll degrading enzymes to access their substrate (Park et al, 1998)
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