An introduction is given to the literature concerning methods and objectives for cytometric DNA analysis of plant nuclei. This area has gained relevance with applications in plant breeding and seed production industries, where laboratories unfamiliar with cytometry are adopting the method. An extensive graphical guide to interpreting DNA histograms and their problems is given. Conversely, cytometry laboratories unfamiliar with plant sciences will find herein a guide, and references, to adapt their methods to plant material. A table of 2C values reassessed by flow cytometry for 70 plant species, plus the genome composition (GC%) in many instances, is also included.
Activation of cell division in the root apical meristem after germination is essential for postembryonic root development. Arabidopsis plants homozygous for a mutation in the ROOT MERISTEMLESS1 (RML1) gene are unable to establish an active postembryonic meristem in the root apex. This mutation abolishes cell division in the root but not in the shoot. We report the molecular cloning of the RML1 gene, which encodes the first enzyme of glutathione (GSH) biosynthesis, gamma-glutamylcysteine synthetase, and which is allelic to CADMIUM SENSITIVE2. The phenotype of the rml1 mutant, which was also evident in the roots of wild-type Arabidopsis and tobacco treated with an inhibitor of GSH biosynthesis, could be relieved by applying GSH to rml1 seedlings. By using a synchronized tobacco cell suspension culture, we showed that the G(1)-to-S phase transition requires an adequate level of GSH. These observations suggest the existence of a GSH-dependent developmental pathway essential for initiation and maintenance of cell division during postembryonic root development.
Plant organs originate from meristems where stem cells are maintained to produce continuously daughter cells that are the source of different cell types. The cell cycle switch gene CCS52A, a substrate specific activator of the anaphase promoting complex/ cyclosome (APC/C), controls the mitotic arrest and the transition of mitotic cycles to endoreduplication (ER) cycles as part of cell differentiation. Arabidopsis, unlike other organisms, contains 2 CCS52A isoforms. Here, we show that both of them are active and regulate meristem maintenance in the root tip, although through different mechanisms. The CCS52A1 activity in the elongation zone of the root stimulates ER and mitotic exit, and contributes to the border delineation between dividing and expanding cells. In contrast, CCS52A2 acts directly in the distal region of the root meristem to control identity of the quiescent center (QC) cells and stem cell maintenance. Cell proliferation assays in roots suggest that this control involves CCS52A2 mediated repression of mitotic activity in the QC cells. The data indicate that the CCS52A genes favor a low mitotic state in different cell types of the root tip that is required for meristem maintenance, and reveal a previously undescribed mechanism for APC/C mediated control in plant development.CDH1 ͉ cell differentiation ͉ endoreduplication ͉ quiescent center ͉ stem cells P lant growth and development depend on the persistent activity of meristems, allowing continuous postembryonic organogenesis. In the root tip, meristem maintenance is controlled by different mechanisms that involve the maintenance of stem cells in the root meristem (RM) and spatial control over mitotic exit at the RM-elongation zone (EZ) border.In the distal RM, stem cells are maintained in an undifferentiated state by the quiescent center (QC) cells (1). The QC represents a center of mitotic inactive cells resting in an extended G 1 phase (2). The stem cells around the QC divide according to strict spatial rules, and provide cell progenies that detach from the QC and differentiate into different root cell types (3). The auxin-PLETHORA (PLT) pathway provides positional information to set up the QC and surrounding stem cells whose activities depend on WOX5 and SHORT ROOT (SHR)-SCARECROW (SCR) transcription factors (4-7).As cells reach the RM-EZ border, they start to expand and terminally differentiate. Recently, it has been demonstrated that the spatial boundary of the RM and EZ is controlled by the rate of meristematic cell differentiation at this border (8). The transition involves exit from the mitotic cycle to the endocycle (9). In eukaryotes, endoreduplication (ER) onset requires inhibition of mitotic cyclin-dependent kinase (cdk) activities (10-12). This inhibition can be achieved by multiple mechanisms, but mostly by the degradation of mitotic cyclins by the anaphase promoting complex/cyclosome (APC/C) (13-15). The APC/C is an ubiquitin ligase that regulates cell cycle progression from metaphase to S phase by targeted degradation of numerous ce...
SummaryA majority of the cells in the Arabidopsis hypocotyl undergo endoreduplication. The number of endocycles in this organ is partially controlled by light. Up to two cycles occur in light-grown hypocotyls, whereas in the dark about 30% of the cells go through a third cycle. Is the inhibition of the third endocycle in the light an indirect result of the reduced cell size in the light-grown hypocotyl, or is it under independent light control? To address this question, the authors examined the temporal and spacial patterns of endoreduplication in light-or dark-grown plants and report here on the following observations: (i) during germination two endocycles take place prior to any significant cell expansion; (ii) in the dark the third cycle is completed very early during cell growth; and (iii) a mutation that dramatically reduces cell size does not interfere with the third endocycle. The authors then used mutants to study the way light controls the third endocycle and found that the third endocycle is completely suppressed in far red light through the action of phytochrome A and, to a lesser extent, in red light by phytochrome B. Furthermore, no 16C nuclei were observed in dark-grown constitutive photomorphogenic 1 seedlings. And, finally the hypocotyl of the cryptochrome mutant, hy4, grown in blue light was about three times longer than that of the wild-type without a significant difference in ploidy levels. Together, the results support the view that the inhibition of the third endocycle in light-grown hypocotyls is not the consequence of a simple feed-back mechanism coupling the number of cycles to the cell volume, but an integral part of the phytochrome-controlled photomorphogenic program.
SUMMARYEndopolyploidy is a widespread process that corresponds to the amplification of the genome in the absence of mitosis. In tomato, very high ploidy levels (up to 256C) are reached during fruit development, concomitant with very large cell sizes. Using cellular approaches (fluorescence and electron microscopy) we provide a structural analysis of endoreduplicated nuclei at the level of chromatin and nucleolar organisation, nuclear shape and relationship with other cellular organelles such as mitochondria. We demonstrate that endopolyploidy in pericarp leads to the formation of polytene chromosomes and markedly affects nuclear structure. Nuclei manifest a complex shape, with numerous deep grooves that are filled with mitochondria, affording a fairly constant ratio between nuclear surface and nuclear volume. We provide the first direct evidence that endopolyploidy plays a role in increased transcription of rRNA and mRNA on a per-nucleus basis. Overall, our results provide quantitative evidence in favour of the karyoplasmic theory and show that endoreduplication is associated with complex cellular organisation during tomato fruit development.
The spatial organization of chromatin can be subject to extensive remodeling in plant somatic cells in response to developmental and environmental signals. However, the mechanisms controlling these dynamic changes and their functional impact on nuclear activity are poorly understood. Here, we determined that light perception triggers a switch between two different nuclear architectural schemes during Arabidopsis postembryonic development. Whereas progressive nucleus expansion and heterochromatin rearrangements in cotyledon cells are achieved similarly under light and dark conditions during germination, the later steps that lead to mature nuclear phenotypes are intimately associated with the photomorphogenic transition in an organ-specific manner. The light signaling integrators DE-ETIOLATED 1 and CONSTITUTIVE PHOTOMORPHOGENIC 1 maintain heterochromatin in a decondensed state in etiolated cotyledons. In contrast, under light conditions cryptochrome-mediated photoperception releases nuclear expansion and heterochromatin compaction within conspicuous chromocenters. For all tested loci, chromatin condensation during photomorphogenesis does not detectably rely on DNA methylation-based processes. Notwithstanding, the efficiency of transcriptional gene silencing may be impacted during the transition, as based on the reactivation of transposable element-driven reporter genes. Finally, we report that global engagement of RNA polymerase II in transcription is highly increased under light conditions, suggesting that cotyledon photomorphogenesis involves a transition from globally quiescent to more active transcriptional states. Given these findings, we propose that light-triggered changes in nuclear architecture underlie interplays between heterochromatin reorganization and transcriptional reprogramming associated with the establishment of photosynthesis. plant development | photomorphogenesis | light signaling | nuclear organization | heterochromatin C hromatin allows dense packaging of chromosomal DNA into a small and constrained nuclear space. It also serves as a structural framework for regulatory processes that control the functional status of genome domains with variable sizes, notably by dynamically influencing the subnuclear partitioning of generich and repeat-rich domains within euchromatic and heterochromatic regions, respectively (reviewed in refs. 1-3). These chromatin-based processes impact plasticity in the regulation of nuclear programs during both vegetative and reproductive phases of the plant life cycle (recently reviewed in refs. 4-8). In many cases, such events combine local chromatin variations with prominent changes in nuclear architecture and higher-order chromatin organization.Spatial chromatin organization is well exemplified by the extreme cases of transcriptionally silent chromocenters that contain the majority of ribosomal DNA repeats, such as the (peri)centromeric domains of mice and several plant species that include transposable elements (TE) and non-TE repeated sequences (9,
Rotavirus nonstructural protein NSP3 interacts specifically with the 3 end of viral mRNAs, with the eukaryotic translation initiation factor eIF4G, and with RoXaN, a cellular protein of yet-unknown function. By evicting cytoplasmic poly(A) binding protein (PABP-C1) from translation initiation complexes, NSP3 shuts off the translation of cellular polyadenylated mRNAs. We show here that PABP-C1 evicted from eIF4G by NSP3 accumulates in the nucleus of rotavirus-infected cells. Through modeling of the NSP3-RoXaN complex, we have identified mutations in NSP3 predicted to interrupt its interaction with RoXaN without disturbing the NSP3 interaction with eIF4G. Using these NSP3 mutants and a deletion mutant unable to associate with eIF4G, we show that the nuclear localization of PABP-C1 not only is dependent on the capacity of NSP3 to interact with eIF4G but also requires the interaction of NSP3 with a specific region in RoXaN, the leucine-and aspartic acid-rich (LD) domain. Furthermore, we show that the RoXaN LD domain functions as a nuclear export signal and that RoXaN tethers PABP-C1 with RNA. This work identifies RoXaN as a cellular partner of NSP3 involved in the nucleocytoplasmic localization of PABP-C1.The cytoplasmic poly(A)-binding protein (PABP-C1) is considered a bona fide translation initiation factor which enhances translation by binding the 3Ј poly(A) tail of the cellular mRNAs and simultaneously interacting with eukaryotic translation initiation factor 4G (eIF4G) (27,29). eIF4G is a scaffold protein that allows mRNA circularization by providing sites of interaction for PABP-C1 and eIF4E, the protein that binds the 5Ј end of capped mRNAs. eIF4G then coordinates the assembly of several other translation initiation factors, such as eIF4A, eIF3, and the small ribosomal subunit (37). In synergy with the cap structure present at the 5Ј end of most mRNAs, PABP-C1 stimulates the translation of cellular polyadenylated mRNAs by enhancing 40S ribosome subunit recruitment and 60S subunit joining (20). Furthermore, PABP-C1 binding to eIF4G increases the affinity of eIF4E for the cap structure (6, 28) by lowering its dissociation rate. Thus, PABP-C1 enhances translation by promoting the binding of mRNA to eIF4G and by lowering dissociation of the 5Ј cap structure from the eIF4G/eIF4E complex. Normally evenly dispersed throughout the cytoplasm, PABP-C1 is redistributed into stress granules (SGs) under conditions of stress, such as oxidative stress or heat shock (22). SGs are cytoplasmic foci formed by the condensation of mRNAs stalled during translation and bound by the related RNA-binding proteins TIA-1 and TIA-R. SGs are not translationally competent, but rather serve as local storage and protection compartments for mRNAs under translational arrest during cellular stress. Although it is primarily cytoplasmic, PABP-C1 has been detected nevertheless in the nucleus of several mammalian cells (1, 17, 50, 51) associated with nuclear pre-mRNP (17). PABP-C1 is thus regarded as a shuttling protein that participates in mRNA ma...
We report on the sub-cellular localisation and function of m-Rabmc, a N-myristoylated plant-specific Rab-GTPase previously characterised at the molecular level and also by structural analysis in Mesembryanthemum crystallinum. By confocal laser scanning microscopy, we identified m-Rabmc predominantly on the prevacuolar compartment of the lytic vacuole but also on the Golgi apparatus in various plant cell types. Two complementary approaches were used immunocytochemistry and cyan fluorescent protein (CFP)/yellow fluorescent protein (YFP)-fusion proteins. Co-localisation studies of m-Rabmc with a salinity stress modulated integral calcium-ATPase suggest involvement of m-Rabmc in a plant-specific transport pathway to the prevacuolar compartment of the lytic vacuole. This hypothesis was strengthened by the inhibition of the transport of aleurain fused to green fluorescent protein (GFP), a marker of the lytic vacuole, in the presence of the dominant negative mutant m-Rabmc(N147I) in Arabidopsis thaliana protoplasts. The inhibitory effect of m-Rabmc(N147I) was specific for the transport pathway to the lytic vacuole, since the transport of chitinase-YFP, a marker for the neutral vacuole, was not hindered by the mutant.
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