Programmed cell death (PCD) is a genetically controlled cell death that is regulated during development and activated in response to environmental stresses or pathogen infection. The degree of conservation of PCD across kingdoms and phylum is not yet clear; however, whereas caspases are proteases that act as key components of animal apoptosis, plants have no orthologous caspase sequences in their genomes. The discovery of plant and fungi metacaspases as proteases most closely related to animal caspases led to the hypothesis that metacaspases are the functional homologues of animal caspases in these organisms. Arabidopsis thaliana has nine metacaspase genes, and so far it is unknown which members of the family if any are involved in the regulation of PCD. We show here that metacaspase-8 (AtMC8) is a member of the gene family strongly up-regulated by oxidative stresses caused by UVC, H 2 O 2 , or methyl viologen. This up-regulation was dependent of RCD1, a mediator of the oxidative stress response. Recombinant metacaspase-8 cleaved after arginine, had a pH optimum of 8, and complemented the H 2 O 2 no-death phenotype of a yeast metacaspase knock-out. Overexpressing AtMC8 up-regulated PCD induced by UVC or H 2 O 2 , and knocking out AtMC8 reduced cell death triggered by UVC and H 2 O 2 in protoplasts. Knock-out seeds and seedlings had an increased tolerance to the herbicide methyl viologen. We suggest that metacaspase-8 is part of an evolutionary conserved PCD pathway activated by oxidative stress.In some instances, programmed cell death (PCD) 4 in plants is comparable with animal apoptosis at the cellular level. However, sequencing the Arabidopsis genome revealed that very few of the animal PCD regulators are conserved in plants. This suggests a greater divergence of the PCD pathways across kingdoms than thought. Initial reports seemed to provide indirect evidence supporting the existence of caspase orthologues in plants, with several caspase-like activities detected in plant extracts and inhibitor studies that show them to be required for PCD (for review, see Ref. 1). Although several research groups reported the absence of orthologous caspase sequences in plant genomes, a more in depth analysis revealed a greater diversity of caspase-related proteases than previously suspected (2). In particular, two families of predicted proteases were identified that are more closely related to animal caspases than to other proteases: the paracaspases and metacaspases. Paracaspases and caspases appear animal specific, whereas metacaspases are present in other eukaryotes, including plants. Plant metacaspases are subdivided in type I and type II on the basis of their structure; type I have an N-terminal prodomain that is not present in type II. A role for metacaspases in plant PCD was proposed (3) for four reasons; 1) a common origin with caspases, 2) the absence of closer caspase homologues in plants, 3) the proliferation of the genes coding for metacaspases in plant genomes mirrors the pattern of the proliferation and speciali...
Plants, animals, and several branches of unicellular eukaryotes use programmed cell death (PCD) for defense or developmental mechanisms. This argues for a common ancestral apoptotic system in eukaryotes. However, at the molecular level, very few regulatory proteins or protein domains have been identified as conserved across all eukaryotic PCD forms. A very important goal is to determine which molecular components may be used in the execution of PCD in plants, which have been conserved during evolution, and which are plant-specific. Using Arabidopsis thaliana, we have shown that UV radiation can induce apoptosis-like changes at the cellular level and that a UV experimental system is relevant to the study of PCD in plants. We report here that UV induction of PCD required light and that a protease cleaving the caspase substrate Asp-GluVal-Asp (DEVDase activity) was induced within 30 min and peaked at 1 h. This DEVDase appears to be related to animal caspases at the biochemical level, being insensitive to broad-range cysteine protease inhibitors. In addition, caspase-1 and caspase-3 inhibitors and the pan-caspase inhibitor p35 were able to suppress DNA fragmentation and cell death. These results suggest that a YVADase activity and an inducible DEVDase activity possibly mediate DNA fragmentation during plant PCD induced by UV overexposure. We also report that At-DAD1 and At-DAD2, the two A. thaliana homologs of Defender against Apoptotic Death-1, could suppress the onset of DNA fragmentation in A. thaliana, supporting an involvement of the endoplasmic reticulum in this form of the plant PCD pathway.
Programmed cell death (PCD) is used by plants for development and survival to biotic and abiotic stresses. The role of caspases in PCD is well established in animal cells. Over the past 15 years, the importance of caspase-3-like enzymatic activity for plant PCD completion has been widely documented despite the absence of caspase orthologues. In particular, caspase-3 inhibitors blocked nearly all plant PCD tested. Here, we affinity-purified a plant caspase-3-like activity using a biotin-labelled caspase-3 inhibitor and identified Arabidopsis thaliana cathepsin B3 (AtCathB3) by liquid chromatography with tandem mass spectrometry (LC-MS/MS). Consistent with this, recombinant AtCathB3 was found to have caspase-3-like activity and to be inhibited by caspase-3 inhibitors. AtCathepsin B triple-mutant lines showed reduced caspase-3-like enzymatic activity and reduced labelling with activity-based caspase-3 probes. Importantly, AtCathepsin B triple mutants showed a strong reduction in the PCD induced by ultraviolet (UV), oxidative stress (H2O2, methyl viologen) or endoplasmic reticulum stress. Our observations contribute to explain why caspase-3 inhibitors inhibit plant PCD and provide new tools to further plant PCD research. The fact that cathepsin B does regulate PCD in both animal and plant cells suggests that this protease may be part of an ancestral PCD pathway pre-existing the plant/animal divergence that needs further characterisation.
Several studies have shown that protease inhibitors can suppress programmed cell death in various plant species and plant tissues. This is especially true of caspase inhibitors that can block programmed cell death and its marker DNA laddering. There are up to six different caspase‐like activities that can be measured in plant extracts, the most prominent being caspase1‐like and caspase3‐like. These activities can be located in vacuoles and also in the nucleus or the cytoplasm. This represents a striking apparent similarity with animal programmed cell death. Because there are no caspase orthologue in plant genomes, a major challenge is to identify these proteases. Recently two proteases with caspase‐like activities have been recognized as belonging to two different protease families that are not closely related to animal caspases. Various other protease families have been implicated and this suggests that complex protease networks have been recruited for the plant cell demise.
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