The wound-inducible Lls1 gene from maize is an orthologue of the Arabidopsis Acd1 gene, and the LLS1 protein is present in non-photosynthetic tissues.

Previous studies indicated that the lethal leaf spot 1 lesion mimic locus of maize ( ZmLls1 ) encodes a novel cell protective function in plants. Here we show that the accelerated cell death 1 ( acd1 ) locus of Arabidopsis thaliana corresponds to gene At3g44880 on chromosome 3. Proof that the Acd1 gene is an orthologue of ZmLls1 is provided by in vivo complementation of the acd1 mutant by the ZmLls1 gene. The Atlls1 lesion mimic phenotype was delayed in a chlorophyll a oxygenase (CAO) mutant chlorina1 background which is deficient in chlorophyll b synthesis. The interpretation that the cell protective function of LLS1 is linked with the removal of a phototoxic chlorophyll intermediate is supported by the recent report that the maize Lls1 gene encodes pheophorbide a oxygenase (PaO). Western blot analysis demonstrates that the LLS1 protein is present constitutively in all photosynthetic plant tissues. A transient increase in Lls1 gene expression by about 50-fold upon physical wounding of maize leaves indicates that the function of Lls1 is regulated in response to stress. We show that the LLS1 protein is also present at low levels in non-photosynthetic tissues including etiolated leaves suggesting that the ability to degrade chlorophyll exists in a standby mode in plant cells.

A small family of LLS1-related non-heme oxygenases in plants with an origin amongst oxygenic photosynthesizers.

Conservation of Lethal-leaf spot 1 (Lls1) lesion mimic gene in land plants including moss is consistent with its recently reported function as pheophorbide a oxygenase (Pao) which catalyzes a key step in chlorophyll degradation (Pruzinska et al., 2003). A bioinformatics survey of complete plant genomes reveals that LLS1(PAO) belongs to a small 5-member family of non-heme oxygenases defined by the presence of Rieske and mononuclear iron-binding domains. This gene family includes chlorophyll a oxygenase (Cao), choline monooxygenase (Cmo), the gene for a 55 kDa protein associated with protein transport through the inner chloroplast membrane (Tic 55) and a novel 52 kDa protein isolated from chloroplasts (Ptc 52). Analysis of gene structure reveals that these genes diverged prior to monocot/dicot divergence. Homologues of LLS1(PAO), CAO, TIC55 and PTC52 but not CMO are found in the genomes of several cyanobacteria. LLS1(PAO), PTC52, TIC55 and a set of related cyanobacterial homologues share an extended carboxyl terminus containing a novel F/Y/W-x(2)-H-x(3)-C-x(2)-C motif not present in CAO. These proteins appear to have evolved during the transition to oxygenic photosynthesis to play various roles in chlorophyll metabolism. In contrast, CMO homologues are found only in plants and are most closely related to aromatic ring-hydroxylating enzymes from soil-dwelling bacteria, suggesting a more recent evolution of this enzyme, possibly by horizontal gene transfer. Our phylogenetic analysis of 95 extant non-heme dioxygenases provides a useful framework for the classification of LLS1(PAO)-related non-heme oxygenases.