Metacaspases in plants, fungi, and protozoa constitute new members of a conserved superfamily of caspase-related proteases. A yeast caspase-1 protein (Yca1p), which is the single metacaspase in Saccharomyces cerevisiae, was shown to mediate apoptosis triggered by oxidative stress or aging in yeast. To examine whether plant metacaspase genes are functionally related to YCA1, we carried out analyses of AtMCP1b and AtMCP2b, representing the two subtypes of the Arabidopsis metacaspase family, utilizing yeast strains with wild-type and the disrupted YCA1 gene (yca1⌬). Inducible expression of AtMCP1b and AtMCP2b significantly promoted yeast apoptosis-like cell death of both the wild-type and yca1⌬ strains, relative to the vector controls, during oxidative stress and early aging process. Mutational analysis of the two AtMCPs revealed that their cell-death-inducing activities depend on their catalytic center cysteine residues as well as caspaselike processing. In addition, the phenotype induced by the expression of two AtMCPs was effectively prevented when the cells were pretreated with a broad-spectrum caspase inhibitor N-benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone. These results suggest that the two subtypes of Arabidopsis metacaspases are functionally related to Yca1p with caspase-like characteristics. However, we found that bacterial and yeast extracts containing AtMCP1b, AtMCP2b, or Yca1p exhibit arginine/lysine-specific endopeptidase activities but cannot cleave caspasespecific substrates. Together, the results strongly implicate that expression of metacaspases could result in the activation of downstream protease(s) with caspase-like activities that are required to mediate cell death activation via oxidative stress in yeast. Metacaspases from higher plants may serve similar functions.
Apoptosis or programmed cell death (PCD)1 is a conserved and genetically controlled process in multicellular organisms during development, homeostasis, and in response to pathogens and stress signals (1, 2). Activation of caspases (cysteinecontaining aspartate-specific proteases) represents a central core execution switch for apoptosis in animal cells (reviewed in Refs. 3-5). Similarly, accumulating evidence in recent years suggest the involvement of caspase-like proteases during the activation of various types of PCD in plants (reviewed in Refs. 6 -9). At present, no caspase gene has been identified in the available plant genome sequences, including Arabidopsis and rice, but recent studies have revealed the presence of a family of genes encoding proteins with distant homology to mammalian caspases, designated metacaspases, in plants, fungi, and protozoa (10).In the Arabidopsis thaliana genome, there are nine predicted metacaspase genes: three of these A. thaliana genes belong to the type-I class (AtMCP1a-1c), containing predicted N-terminal prodomain consisted of a zinc finger motif followed by a proline-rich region (AtMCP1b and AtMCP1c) or by a glutamine-and proline-rich region (AtMCP1a) and a C-terminal caspase-like domain, ...
