Lada Filonova scite author profile

Programmed cell death (PCD) is indispensable for eukaryotic development. In animals, PCD is executed by the caspase family of cysteine proteases. Plants do not have close homologues of caspases but possess a phylogenetically distant family of cysteine proteases named metacaspases. The cellular function of metacaspases in PCD is unknown. Here we show that during plant embryogenesis, metacaspase mcII-Pa translocates from the cytoplasm to nuclei in terminally differentiated cells that are destined for elimination, where it colocalizes with the nuclear pore complex and chromatin, causing nuclear envelope disassembly and DNA fragmentation. The cell-death function of mcII-Pa relies on its cysteine-dependent arginine-specific proteolytic activity. Accordingly, mutation of catalytic cysteine abrogates the proteolytic activity of mcII-Pa and blocks nuclear degradation. These results establish metacaspase as an executioner of PCD during embryo patterning and provide a functional link between PCD and embryogenesis in plants. Although mcII-Pa and metazoan caspases have different substrate specificity, they serve a common function during development, demonstrating the evolutionary parallelism of PCD pathways in plants and animals.embryo suspensor ͉ metacaspase ͉ nuclear degradation P rogrammed cell death (PCD) is indispensable for normal embryo development both in animals and in plants, where temporary, surplus, or aberrantly formed tissues and organs are removed for correct pattern formation (1, 2). The key morphogenetic event in plant embryogenesis is formation of the apicalbasal pattern via establishment of the proliferating embryo proper (apical) and the terminally differentiated suspensor (basal). Developmental programs of the embryo proper and the suspensor are closely coordinated, and imbalance causes embryonic defects or lethality (2-4). While the embryo proper gives rise to the plant, the suspensor functions during a brief period as a conduit of growth factors to the developing embryo and is subsequently eliminated by PCD (2). The terminal differentiation of the embryo suspensor is the earliest manifestation of cellular suicide in plant ontogenesis. However, the molecular mechanisms that regulate PCD in plant embryos are unknown.The nucleus is the major target of cell degradation machinery during PCD. Nuclear degradation processes encompass chromatin events (i.e., chromatin condensation and DNA fragmentation) and nuclear envelope events (i.e., lobing of the nuclear surface and disassembly of nuclear pore complex) that occur simultaneously in the same cell (2, 5). The structural organization of plant and animal nuclei is conserved (6), explaining why the morphological pattern of nuclear degradation is also conserved (2). However, the molecular composition of plant and animal nuclear envelopes is not conserved (6), implying that different molecular mechanisms are responsible for nuclear envelope events during PCD in plants.In animals, nuclear degradation during PCD is executed by a caspase family of cysteine proteases...

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Developmental pathway of somatic embryogenesis in Picea abies as revealed by time‐lapse tracking

Filonova¹,

Bozhkov²,

Arnold³

2000

189

178

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Several coniferous species can be propagated via somatic embryogenesis. This is a useful method for clonal propagation, but it can also be used for studying how embryo development is regulated in conifers. However, in conifers it is not known to what extent somatic and zygotic embryos develop similarly, because there has been little research on the origin and development of somatic embryos. A time-lapse tracking technique has been set up, and the development of more than 2000 single cells and few-celled aggregates isolated from embryogenic suspension cultures of Norway spruce (Picea abies L. Karst.) and embedded in thin layers of agarose has been traced. Experiments have shown that somatic embryos develop from proembryogenic masses which pass through a series of three characteristic stages distinguished by cellular organization and cell number (stages I, II and III) to transdifferentiate to somatic embryos. Microscopic inspection of different types of structures has revealed that proembryogenic masses are characterized by high interclonal variation of shape and cellular constitution. In contrast, somatic embryos are morphologically conservative structures, possessing a distinct protoderm-like cell layer as well as embryonal tube cells and suspensor. The lack of staining of the arabinogalactan protein epitope recognized by the monoclonal antibody JIM13 was shown to be an efficient marker for distinguishing proembryogenic masses from somatic embryos. The vast majority of cells in proembryogenic masses expressed this epitope and none of cells in the early somatic embryos. The conditions that promote cell proliferation (i.e. the presence of exogenous auxin and cytokinin), inhibit somatic embryo formation; instead, continuous multiplication of stage I proembryogenic masses by unequal division of embryogenic cells with dense cytoplasm is the prevailing process. Once somatic embryos have formed, their further development to mature forms requires abscisic acid and shares a common histodifferentiation pattern with zygotic embryos. Although the earliest stages of somatic embryo development comparable to proembryogeny could not be characterized, the subsequent developmental processes correspond closely to what occurs in the course of early and late zygotic embryogeny. A model for somatic embryogenesis pathways in Picea abies is presented.

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Time-Lapse Tracking of Origin and Development of Somatic Embryos in a Gymnosperm, Norway Spruce

1999

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Metacaspase-dependent programmed cell death is essential for plant embryogenesis

et al. 2004

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In plants, as in animals, programmed cell death (PCD) is a key process responsible for the elimination of unneeded structures and for overall shape remodeling during development [1]; however, the molecular mechanisms remain poorly understood. Despite the absence of canonical caspases in plants, dying plant cells show an increased proteolytic caspase-like activity [2]. Moreover, the cell death can be suppressed using synthetic [2] or natural [3] caspase inhibitors. This raises the question of whether plants have specific cysteine proteases with a role similar to metazoan caspases in the execution of PCD. Metacaspases are the best candidates to perform this role, because they contain a caspasespecific catalytic diad of histidine and cysteine as well as conserved caspase-like secondary structure [4,5]. Here we show the first experimental evidence for metacaspase function in the activation and/or execution of PCD in plants, and also demonstrate the fundamental requirement of plant metacaspase for embryogenesis.We explored the role of plant metacaspases in PCD using a model system of somatic embryogenesis of Norway spruce (Picea abies), where the pathway of embryo development (Figure 1A) resembles zygotic embryogeny, even though the embryo origin is different in each case (i.e., somatic cells in proembryogenic mass

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Lada Filonova

Cysteine protease mcII-Pa executes programmed cell death during plant embryogenesis

Developmental pathway of somatic embryogenesis in Picea abies as revealed by time‐lapse tracking

Time-Lapse Tracking of Origin and Development of Somatic Embryos in a Gymnosperm, Norway Spruce

Metacaspase-dependent programmed cell death is essential for plant embryogenesis

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