A matrix metalloproteinase gene is expressed at the boundary of senescence and programmed cell death in cucumber.

Cell-cell and extracellular cell matrix (ECM) interactions provide cells with information essential for controlling morphogenesis, cell-fate specification, and cell death. In animals, one of the major groups of enzymes that degrade the ECM is the matrix metalloproteinases (MMPs). Here, we report the characterization of the cucumber (Cucumis sativus L. cv Marketmore) Cs1-MMP gene encoding such an enzyme likely to play a role in plant ECM degradation. Cs1-MMP has all the hallmark motif characteristics of animal MMPs and is a pre-pro-enzyme having a signal peptide, propeptide, and zinc-binding catalytic domains. Cs1-MMP also displays functional similarities with animal MMPs. For example, it has a collagenase-like activity that can cleave synthetic peptides and type-I collagen, a major component of animal ECM. Cs1-MMP activity is completely inhibited by a hydroxamate-based inhibitor that binds at the active site of MMPs in a stereospecific manner. The Cs1-MMP gene is expressed de novo at the end stage of developmental senescence, prior to the appearance of DNA laddering in cucumber cotyledons leaf discs and male flowers. As the steady-state level of Cs1-MMP mRNA peaks late in senescence and the pro-enzyme must undergo maturation and activation, the protease is probably not involved in nutrient remobilization during senescence but may have another function. The physiological substrates for Cs1-MMP remain to be determined, but the enzyme represents a good candidate for plant ECM degradation and may be involved in programmed cell death (PCD). Our results suggest that PCD occurs only at the culmination of the senescence program or that the processes are distinct with PCD being triggered at the end of senescence.

Programmed cell death in cell cultures.

In plants most instances of programmed cell death (PCD) occur in a number of related, or neighbouring, cells in specific tissues. However, recent research with plant cell cultures has demonstrated that PCD can be induced in single cells. The uniformity, accessibility and reduced complexity of cell cultures make them ideal research tools to investigate the regulation of PCD in plants. PCD has now been induced in cell cultures from a wide range of species including many of the so-called model species. We will discuss the establishment of cell cultures, the fractionation of single cells and isolation of protoplasts, and consider the characteristic features of PCD in cultured cells. We will review the wide range of methods to induce cell death in cell cultures ranging from abiotic stress, absence of survival signals, manipulation of signal pathway intermediates, through the induction of defence-related PCD and developmentally induced cell death.

Translocation of cytochrome c from the mitochondria to the cytosol occurs during heat-induced programmed cell death in cucumber plants.

In mammals mitochondria play a critical role in the activation of programmed cell death (PCD). One mechanism by which mitochondria can commit a cell to death is by translocating cytochrome c into the cytosol where it activates cell death caspases. However, release of cytochrome c does not appear to be a feature of caspase activation in nematodes or insects, similarly, there is no evidence for cytochrome c release during the caspase-independent PCD that can occur in Dictyostelium cells. In an attempt to understand the underlying regulation of PCD in plants we investigated if mitochondrial components were released into the cytosol when plant cells are induced to undergo PCD. PCD was triggered in cucumber cotyledons by subjecting them to a short 55 degrees C heat treatment. This heat treatment has previously been shown to trigger PCD in other plant species and cell death was confirmed in cucumber using morphological (cellular condensation) and molecular (DNA 'laddering') markers of PCD. We present evidence that, unlike Dictyostelium and invertebrate PCDs, cytochrome c release is an early event in plant PCD. The mitochondrial release of cytochrome c following a PCD-inducing stimulus in both plants and mammals suggests the pathways have been conserved during evolution, having been derived from ancestral unicellular death programmes.

Oxidative cross-linking of plasma membrane arabinogalactan proteins.

Monoclonal antibodies which recognize carbohydrate in arabinogalactan proteins (AGPs) have revealed that certain carbohydrate epitopes at the outer plasma membrane surface are developmentally regulated. Some epitopes are expressed according to cell position, and AGPs are thought to play a role in cell-cell interaction during development. This study demonstrates that sugar beet plasma membranes contain two subfamilies of AGPs, with apparent molecular masses of 82 and 97 kDa, and that each subfamily consists of a small number of acidic AGP isoforms. Excision of leaves generates three additional AGP complexes with apparent molecular masses of 120, 170 and 210 kDa, with the 170 kDa complex being the major form induced by excision. The addition of millimolar concentrations of H2O2 to a partially purified fraction of the 82 and 97 kDa AGPs also generates AGP complexes, with the 170 kDa complex as the major form. These results indicate that the plasma membrane AGPs are a target for endogenous H2O2.

Soluble Signals from Cells Identified at the Cell Wall Establish a Developmental Pathway in Carrot.

Cells in a plant differentiate according to their positions and use cell-cell communication to assess these positions. Similarly, single cells in suspension cultures can develop into somatic embryos, and cell-cell communication is thought to control this process. The monoclonal antibody JIM8 labels an epitope on cells in specific positions in plants. JIM8 also labels certain cells in carrot embryogenic suspension cultures. We have used JIM8 and secondary antibodies coupled to paramagnetic beads to label and immunomagnetically sort single cells in a carrot embryogenic suspension culture into pure populations. Cells in the JIM8(+) population develop into somatic embryos, whereas cells in the JIM8(-) population do not form somatic embryos. However, certain cells in JIM8(+) cultures (state B cells) undergo asymmetric divisions, resulting in daughter cells (state C cells) that do not label with JIM8 and that sort to JIM8(-) cultures. State C cells are competent to form somatic embryos, and we show here that a conditioned growth medium from a culture of JIM8(+) cells allows state C cells in a JIM8(-) culture to go on and develop into somatic embryos. JIM8 labels cells in suspension cultures at the cell wall. Therefore, a cell with a role in cell-cell communication and early cell fate selection can be identified by an epitope in its cell wall.

Cell-context signalling.

In plants, cells differentiate according to their position with relation to their cell neighbours. Monoclonal antibody (MAb) probes to polysaccharide epitopes, present at the surfaces of all plant cells, have defined a family of proteoglycan antigens which signify cellular position. These MAbs have been used to sort the single cells present in carrot somatic cell cultures on the basis of the presence or absence of specific polysaccharide epitopes. This sorting allows embryo initial cells to be cultured among different cell collectives (based on their polysaccharide epitope expression) and thus in altered contextual backgrounds. These experiments have shown that specific populations of embryo initial precursor cells induce and sustain the early development of the embryo initials, revealing that the populations of different cell collectives which are defined by different polysaccharide epitopes (cell-context) serves important regulatory function in early plant development. Somatic embryo initials deprived of the influence of the cell collective-defined by the presence of the polysaccharide epitope recognised by the MAb JIM8-establish unorganised first divisions and develop as callus. However, in the presence of the JIM8-reactive cell collective, or medium conditioned by the collective, the initials develop into somatic embryos. This demonstrates that the cells defined by the JIM8 polysaccharide epitope are necessary to sustain the meristematic activity which drives the renewed development. Transfer of a cell-wall signal from the JIM8-reactive cells to cellular situations in carrot seedlings in which they would not normally occur (out-of-context signals) stimulates lateral root production, thus demonstrating that the inductive signal operative in suspension cultures can be reinterpreted by specific cells later in development and reinitiate meristematic activity. The communication between the precursor cells defined by JIM8 and embryo initials defines an early cell-cell interaction in developing carrot plants. Labelling of flower sections suggests that the same interaction exists between embryo apical and basal cells early in normal development.

Mutations conferring lincomycin, spectinomycin, and streptomycin resistance in Solanum nigrum are located in three different chloroplast genes.

A number of Solanum nigrum mutants resistant to the antibiotics spectinomycin, streptomycin and lincomycin have been isolated from regenerating leaf strips after mutagenesis with nitroso-methylurea. Selection of streptomycin- and spectinomycin-resistant mutants has been described earlier. Lincomycin-resistant mutants show resistance to higher levels of the antibiotic than used in the initial selection, and in the most resistant mutant (L17A1) maternal inheritance of the trait was demonstrated. The lincomycin-resistant mutant L17A1 and a streptomycin plus spectinomycin resistant double mutant (StSp1) were chosen for detailed molecular characterisation. Regions of the plastid DNA, within the genes encoding 16S and 23S rRNA and rps12 (3') were sequenced. For spectinomycin and lincomycin resistance, base changes identical to those in similar Nicotiana mutants were identified. Streptomycin resistance is associated with an A-->C change at codon 87 of rps12 (converting a lysine into a glutamine), three codons upstream from a mutation earlier reported for Nicotiana. This site has not previously been implicated in streptomycin resistance mutations of higher plants, but has been found in Escherichia coli. The value of these mutants for studies on plastid genetics is discussed.

T-DNA-tagged chromosome 12 in donor Lycopersicon esculentum × L. pennellii is retained in asymmetric somatic hybrids with recipient Solanum lycopersicoides.

Asymmetric somatic hybrid plants were recovered after fusing irradiated mesophyll protoplasts of donor Lycopersicon esculentum × L. pennellii (EP) interspecific hybrid with callus-derived protoplasts of recipient Solanum lycopersicoides. EP plant A54 had been previously transformed by an agrobacterium vector, and the T-DNA insert mapped to the L. esculentum chromosome 12. The T-DNA insert conferred kanamycin resistance to EP that was subsequently used to select cell fusion products and recover asymmetric hybrid plants that retained tagged chromosome 12. Doses of 50- and 100-Gy irradiation promoted the elimination of only a few donor chromosomes. At 200 Gy, the regenerated plants had ploidy levels higher than tetraploid. However, the T-DNA tagged chromosome 12 was always retained in the asymmetric hybrid plants tested. Likewise, all plants from the 100-Gy series, with the exception of number 160, were mixoploid in the root-tip cells. Such mixoploid asymmetric somatic hybrids could be stabilized by inducing adventitious shoots on leaf strips cultured on shoot regeneration medium containing kanamycin. The asymmetric hybrid plants did not produce viable seed when self-pollinated or backcrossed to tomato or S. lycopersicoides.

Selection of chloroplast mutants.

The chloroplast genome encodes a number of proteins, including thylakoid proteins and the large subunit of ribulose biphosphate carboxylase, associated with the structure and function of the chloroplast (1-2). In addition, many components of the chloroplast translational machinery, such as all of the RNAs and some of the ribosomal proteins, are coded by the chloroplast DNA. Although there have been numerous investigations into the genetics of algal chloroplasts, similar studies with higher plants have been hampered by the uniparental (maternal) pattern of transmission of chloroplasts observed in most species, and the shortage of suitable genetic markers (3,4).