Interphase Duration Research Articles

Duration of interphase and growing periods of soybean varieties depending on hydrothermal conditions and application of soil and post-emergence herbicides

Duration of interphase and growing periods of soybean varieties depending on hydrothermal conditions and application of soil and post-emergence herbicides

Economic and biological evaluation of spring rape varieties and hybrids under conditions of the Kirov region

In recent years there has been a tendency in the Russian Federation to increase the area under rapeseed, the area of which is constantly expanding. Research on economic and biological evaluation of spring rape varieties and hybrids was carried out in one of the farms of the Kirov region. Promising varieties and hybrids were studied under comparative aspect in production conditions. The seeds field germination was studied, the safety of the plants by the time of harvesting was determined. The duration of interphase and vegetation periods of the promising varieties and hybrids of spring rape was estimated, the yield of their seeds was compared. Analysis of the productivity structure elements of these varieties and hybrids is presented. In the experiment spring rape varieties Heros, Campino, Yarilo, obtained under farm conditions and having appropriate quality documents, and the first generation hybrids Joy, Jazz, Hephaestus, Joker, Jerome, Jerry were sown. When assessing the duration of the vegetation period, it was found that all the samples by biological rhythms fit into the vegetation period of the Kirov region and belong to the medium-maturing group. Field germination of the studied varieties and hybrids on average during the years of the study ranged from 48.8 to 75.8%. On average for 2 years, the highest field germination was observed in the first generation hybrids Joker and Hephaestus (75.8 and 69.1%, respectively). Preservation of plants for harvesting higher than the control (84%), on average for 2 years was observed in the varieties Campino and Yarilo. In terms of seed yield, hybrids Jerry F1 (16.7 c/ha) and Joker F1 (16.2) and the variety Yarilo (16.3 c/ha) significantly outperformed the control (15.5 c/ha). Hybrids Joy (450), Joker (482) and the variety Yarilo (459) reliably surpassed the control (358) by the number of pods on one plant on average for 2 years.

Influence of Weather Conditions on the Duration of Interphysical Periods and Yield of Durum Winter Wheat

Despite the high genetic potential of productivity of new varieties, the yield of durum winter wheat remains low. One of the reasons for this is non-compliance with the recommended cultivation technologies, which would take into account the genetic characteristics of different varieties, their adaptation to the climatic conditions of the region. Due to insufficient scientific studies of the impact of weather conditions on the productivity of durum winter wheat, taking into account the main strategy of agricultural adaptation to negative climate changes in the southern steppe of Ukraine, the research topic is relevant. The aim of the work was to determine the degree of influence of changes in weather and climatic conditions in the main interphase periods on the growth and development and yield of winter durum wheat grain, depending on the varietal composition. Field studies were conducted during 2014-2020 years in the experimental field of the MNAU training, research and practical center with four varieties of winter durum wheat. In the course of the study, generally accepted methods were used: system approach and systems analysis, monographic, analysis and synthesis, field research and statistical mathematical, etc. Its predecessor was black steam, the sowing period was October 1st. According to the results of research, it was determined that the formation of winter durum wheat grain yield was significantly influenced by the duration of interphase and vegetations and the amount of precipitation. The weather conditions of 2014, 2016 and 2019 were more favorable for the germination of winter durum wheat seeds, when the plants reached the sum of effective temperatures of 70.0-89.1 ° С, the duration of the interphase period "sowing-seedlings" was only 11-12 days. In favorable yields in 2016 and 2019 years the duration of the vegetation of plants was the longest – 296 and 288 days, respectively, with the amount of precipitation for the reporting period – 358.5-402.0 mm, and in unfavorable years in 2018 and 2020 years the vegetation was 272 and 276 days with the amount of precipitation 256.9 and 308.9 mm. The highest average yield of winter durum wheat grain by variety was formed in 2016 year as 7.24 t/ha, which was by 8.3-43.5% higher than in other years studied

Nuclear sizER in Early Development.

In this issue of Developmental Cell, Mukherjee etal. (2020) investigate control of nuclear growth by live imaging of early embryogenesis, perturbations of blastomere dimensions, and reconstitution invitro. The authors uncover new mechanisms of nuclear size scaling by the amount of inherited perinuclear ER and duration of interphase.

Haspin inhibition delays cell cycle progression through interphase in cancer cells.

Haspin (Haploid Germ Cell-Specific Nuclear Protein Kinase) is a serine/threonine kinase pertinent to normal mitosis progression and mitotic phosphorylation of histone H3 at threonine 3 in mammalian cells. Different classes of small molecule inhibitors of haspin have been developed and utilized to investigate its mitotic functions. We report herein that applying haspin inhibitor CHR-6494 or 5-ITu at the G1/S boundary could delay mitotic entry in synchronized HeLa and U2OS cells, respectively, following an extended G2 or the S phase. Moreover, late application of haspin inhibitors at S/G2 boundary is sufficient to delay mitotic onset in both cell lines, thereby, indicating a direct effect of haspin on G2/M transition. A prolonged interphase duration is also observed with knockdown of haspin expression in synchronized and asynchronous cells. These results suggest that haspin can regulate cell cycle progression at multiple stages at both interphase and mitosis.

MED28 Over-Expression Shortens the Cell Cycle and Induces Genomic Instability.

The mammalian mediator complex subunit 28 (MED28) is overexpressed in a variety of cancers and it regulates cell migration/invasion and epithelial-mesenchymal transition. However, transcription factors that increase MED28 expression have not yet been identified. In this study, we performed a luciferase reporter assay to identify and characterize the prospective transcription factors, namely E2F transcription factor 1, nuclear respiratory factor 1, E-26 transforming sequence 1, and CCAAT/enhancer-binding protein β, which increased MED28 expression. In addition, the release from the arrest at the G1−S or G2−M phase transition after cell cycle synchronization using thymidine or nocodazole, respectively, showed enhanced MED28 expression at the G1−S transition and mitosis. Furthermore, the overexpression of MED28 significantly decreased the duration of interphase and mitosis. Conversely, a knockdown of MED28 using si-RNA increased the duration of interphase and mitosis. Of note, the overexpression of MED28 significantly increased micronucleus and nuclear budding in HeLa cells. In addition, flow cytometry and fluorescence microscopy analyses showed that the overexpression of MED28 significantly increased aneuploid cells. Taken together, these results suggest that MED28 expression is increased by oncogenic transcription factors and its overexpression disturbs the cell cycle, which results in genomic instability and aneuploidy.

Rapid embryonic cell cycles defer the establishment of heterochromatin by Eggless/SetDB1 in Drosophila.

Acquisition of chromatin modifications during embryogenesis distinguishes different regions of an initially naïve genome. In many organisms, repetitive DNA is packaged into constitutive heterochromatin that is marked by di/trimethylation of histone H3K9 and the associated protein HP1a. These modifications enforce the unique epigenetic properties of heterochromatin. However, in the early Drosophila melanogaster embryo, the heterochromatin lacks these modifications, which appear only later, when rapid embryonic cell cycles slow down at the midblastula transition (MBT). Here we focus on the initial steps restoring heterochromatic modifications in the embryo. We describe the JabbaTrap, a technique for inactivating maternally provided proteins in embryos. Using the JabbaTrap, we reveal a major requirement for the methyltransferase Eggless/SetDB1 in the establishment of heterochromatin. In contrast, other methyltransferases contribute minimally. Live imaging reveals that endogenous Eggless gradually accumulates on chromatin in interphase but then dissociates in mitosis, and its accumulation must restart in the next cell cycle. Cell cycle slowing as the embryo approaches the MBT permits increasing accumulation and action of Eggless at its targets. Experimental manipulation of interphase duration shows that cell cycle speed regulates Eggless. We propose that developmental slowing of the cell cycle times embryonic heterochromatin formation.

Mitotic activity patterns and cytoskeletal changes throughout the progression of diapause developmental program in Daphnia

BackgroundDiapause is a form of dormancy that is genetically predetermined to allow animals to overcome harsh environmental conditions. It is induced by predictive environmental cues bringing cellular activity levels into a state of suspended animation. Entering diapause requires organismal, molecular and cellular adaptation to severely reduced energy flows. Cells must therefore have evolved strategies that prepare them for periods with limited metabolic resources. However, changes that occur on the (sub-)cellular level have not been thoroughly described.ResultsWe investigated mitotic activity and we monitored cytoskeletal network changes in successive stages of diapausing and non-diapausing Daphnia magna embryos using (immuno-)fluorescent labeling. We find that embryos destined to diapause show a delayed and 2.5x slower mitotic activity in comparison to continuously developing embryos. Development is halted when D. magna embryos reach ~ 3500 cells, whereupon mitotic activity is absent and cytoskeletal components are severely reduced, rendering diapause cells compact and condensed.ConclusionIn the initiation phase of diapause, the slower cell division rate points to prolonged interphase duration, preparing the cells for diapause maintenance. During diapause, cytoskeletal depletion and cellular condensation may be a means to save energy resources. Our data provide insights into the sub-cellular change of diapause in Daphnia.

Involvement of Endogenous Opioid System in Swim Stress-Induced Pain Modulation During the Interphase of the Formalin Test.

Introduction:Some evidence demonstrates endogenous inhibitory pathways of pain involved in the interphase (phase between early and later phase) of the formalin test. We previously showed that swimming stress modulates the pain-related behaviors during the interphase of the formalin test. In this study, we evaluated the role of the endogenous opioid system in modulating nociceptive responses of the formalin test.Methods:Swim stress was performed in different heights of water (5, 25, 50 cm) in a swimming tank. The mean nociceptive scores were measured during phase 1 (1–7 min), interphase (8–14 min), and phase 2 (15–90 min) of the formalin test. Opioid receptor antagonist, naloxone (3 mg/kg; IP) was injected immediately before swim stress.Results:Swim stress attenuated nociceptive behaviors in the first phase and increased the duration of interphase in the formalin test in a water-height-dependent manner, compared to the control group. Naloxone significantly increased nociceptive behaviors in the first phase, interphase, and the second phase of the formalin test, compared to the control group.Conclusion:Stress could affect the nociceptive response. Swim stress in different heights of water could have different effects on the nociception in different phases of the formalin test. In addition, the involvement of the endogenous opioid system is further demonstrated in the swim stress-induced modulation of pain behaviors in phase 1, phase 2, as well as interphase of formalin test in rats.

Phenological sequences: how early-season events define those that follow.

Plant phenology is a critical trait, as the timings of phenophases such as budburst, leafout, flowering, and fruiting, are important to plant fitness. Despite much study about when individual phenophases occur and how they may shift with climate change, little is known about how multiple phenophases relate to one another across an entire growing season. We test the extent to which early phenological stages constrain later ones, throughout a growing season, across 25 angiosperm tree species. We observed phenology (budburst, leafout, flowering, fruiting, and senescence) of 118 individual trees across 25 species, from April through December 2015. We found that early phenological events weakly constrain most later events, with the strongest constraints seen between consecutive stages. In contrast, interphase duration was a much stronger predictor of phenology, especially for reproductive events, suggesting that the development time of flowers and fruits may constrain the phenology of these events. Much of the variation in later phenological events can be explained by the timing of earlier events and by interphase durations. This highlights that a shift in one phenophase may often have cascading effects on later phases. Accurate forecasts of climate change impacts should therefore include multiple phenophases within and across years.

Chromosome\u2013nuclear envelope attachments affect interphase chromosome territories and entanglement

BackgroundIt is well recognized that the interphase chromatin of higher eukaryotes folds into non-random configurations forming territories within the nucleus. Chromosome territories have biologically significant properties, and understanding how these properties change with time during lifetime of the cell is important. Chromosome–nuclear envelope (Chr–NE) interactions play a role in epigenetic regulation of DNA replication, repair, and transcription. However, their role in maintaining chromosome territories remains unclear.ResultsWe use coarse-grained molecular dynamics simulations to study the effects of Chr–NE interactions on the dynamics of chromosomes within a model of the Drosophila melanogaster regular (non-polytene) interphase nucleus, on timescales comparable to the duration of interphase. The model simulates the dynamics of chromosomes bounded by the NE. Initially, the chromosomes in the model are prearranged in fractal-like configurations with physical parameters such as nucleus size and chromosome persistence length taken directly from experiment. Time evolution of several key observables that characterize the chromosomes is quantified during each simulation: chromosome territories, chromosome entanglement, compactness, and presence of the Rabl (polarized) chromosome arrangement. We find that Chr–NE interactions help maintain chromosome territories by slowing down and limiting, but not eliminating, chromosome entanglement on biologically relevant timescales. At the same time, Chr–NE interactions have little effect on the Rabl chromosome arrangement as well as on how chromosome compactness changes with time. These results are rationalized by simple dimensionality arguments, robust to model details. All results are robust to the simulated activity of topoisomerase, which may be present in the interphase cell nucleus.ConclusionsOur study demonstrates that Chr–NE attachments may help maintain chromosome territories, while slowing down and limiting chromosome entanglement on biologically relevant timescales. However, Chr–NE attachments have little effect on chromosome compactness or the Rabl chromosome arrangement.

A p53-dependent response limits the viability of mammalian haploid cells

The recent development of haploid cell lines has facilitated forward genetic screenings in mammalian cells. These lines include near-haploid human cell lines isolated from a patient with chronic myelogenous leukemia (KBM7 and HAP1), as well as haploid embryonic stem cells derived from several organisms. In all cases, haploidy was shown to be an unstable state, so that cultures of mammalian haploid cells rapidly become enriched in diploids. Here we show that the observed diploidization is due to a proliferative disadvantage of haploid cells compared with diploid cells. Accordingly, single-cell-sorted haploid mammalian cells maintain the haploid state for prolonged periods, owing to the absence of competing diploids. Although the duration of interphase is similar in haploid and diploid cells, haploid cells spend longer in mitosis, indicative of problems in chromosome segregation. In agreement with this, a substantial proportion of the haploids die at or shortly after the last mitosis through activation of a p53-dependent cytotoxic response. Finally, we show that p53 deletion stabilizes haploidy in human HAP1 cells and haploid mouse embryonic stem cells. We propose that, similar to aneuploidy or tetraploidy, haploidy triggers a p53-dependent response that limits the fitness of mammalian cells.

Synphenology of Herb Layer of Carpinion betuli Community in the Báb Forest

The submitted paper presents the results of a phenological research of herb layer of Carpinion betuli community which was realized on the locality of the Báb forest in 2012 and 2013. During 2012, there were 25 species recorded in an herbal layer and for a phenological research in 2013, I was able to document 24 taxa. In 2012, the highest number of present species in a phenological spectrum occurred. Especially, it was during March and October. In 2013, the highest number of species in a phenological spectrum was found on March and April and also later from September to October which is a period when forest species start to grow because of a temperature increase and it also occurred in the autumn period when a repeated growth of forest species took place. In 2012, species in generative phases occurred from 11th March until 1st September and after that, taxa in vegetative phases were found only. In 2013, because of low March temperatures, it was possible to observe generative phases only since 22nd March until the last date of a phenological observation – 11th December. A change in the onset, interphase duration and ending of the monitored phenophases between the years 2012 and 2013 was observed. Specifically, a shift in the onset of the vegetative and generative phenophases was noted. This distinction was caused by a different average week temperature measured in 2012 and 2013. In March 2013 a significant temperature decrease and even ground frost occurred.

Different cyclin types collaborate to reverse the S-phase checkpoint and permit prompt mitosis

Precise timing coordinates cell proliferation with embryonic morphogenesis. As Drosophila melanogaster embryos approach cell cycle 14 and the midblastula transition, rapid embryonic cell cycles slow because S phase lengthens, which delays mitosis via the S-phase checkpoint. We probed the contributions of each of the three mitotic cyclins to this timing of interphase duration. Each pairwise RNA interference knockdown of two cyclins lengthened interphase 13 by introducing a G2 phase of a distinct duration. In contrast, pairwise cyclin knockdowns failed to introduce a G2 in embryos that lacked an S-phase checkpoint. Thus, the single remaining cyclin is sufficient to induce early mitotic entry, but reversal of the S-phase checkpoint is compromised by pairwise cyclin knockdown. Manipulating cyclin levels revealed that the diversity of cyclin types rather than cyclin level influenced checkpoint reversal. We conclude that different cyclin types have distinct abilities to reverse the checkpoint but that they collaborate to do so rapidly.

The microtubule cytoskeleton is required for a G2 cell cycle delay in cancer cells lacking stathmin and p53

In several cancer cell lines, depleting the microtubule (MT)-destabilizing protein stathmin/oncoprotein18 leads to a G2 cell cycle delay and apoptosis. These phenotypes are observed only in synergy with low levels of p53, but the pathway(s) activated by stathmin depletion to delay the cell cycle are unknown. We found that stathmin depletion caused greater MT stability in synergy with loss of p53, measured by the levels of acetylated α-tubulin and the rate of centrosomal MT nucleation. Nocodazole or vinblastine-induced MT depolymerization abrogated the stathmin-depletion induced G2 delay, measured by the percentage of cells staining positive for several markers (TPX2, CDK1 with inhibitory phosphorylation), indicating that MTs are required to lengthen G2. Live cell imaging showed that stathmin depletion increased time in G2 without an impact on the duration of mitosis, indicating that the longer interphase duration is not simply a consequence of a previous slowed mitosis. In contrast, stabilization of MTs with paclitaxel (8 nM) slowed mitosis without lengthening the duration of interphase, demonstrating that increased MT stability alone is not sufficient to delay cells in G2.

A Time-Series Method for Automated Measurement of Changes in Mitotic and Interphase Duration from Time-Lapse Movies

BackgroundAutomated time-lapse microscopy can visualize proliferation of large numbers of individual cells, enabling accurate measurement of the frequency of cell division and the duration of interphase and mitosis. However, extraction of quantitative information by manual inspection of time-lapse movies is too time-consuming to be useful for analysis of large experiments.Methodology/Principal FindingsHere we present an automated time-series approach that can measure changes in the duration of mitosis and interphase in individual cells expressing fluorescent histone 2B. The approach requires analysis of only 2 features, nuclear area and average intensity. Compared to supervised learning approaches, this method reduces processing time and does not require generation of training data sets. We demonstrate that this method is as sensitive as manual analysis in identifying small changes in interphase or mitotic duration induced by drug or siRNA treatment.Conclusions/SignificanceThis approach should facilitate automated analysis of high-throughput time-lapse data sets to identify small molecules or gene products that influence timing of cell division.

Abstract C32: Stathmin depletion from cells lacking p53 delays mitotic entry by increasing microtubule stability during interphase

Abstract Microtubules (MTs) have been a successful target for control of cell proliferation; drugs such as vinblastine or taxol block cells in mitosis and induce apoptosis, but these drugs are indiscriminate, affecting both normal and cancerous cells. We are examining a pathway induced by depletion of the MT destabilizing protein, stathmin, that results in slowed proliferation and apoptosis only in cancer cells and thus has potential for targeted killing of cancer cells. Depletion of stathmin caused slower cell proliferation, a cell cycle delay during G2 of the cell cycle, and cell death by apoptosis only in cells lacking p53 (Carney and Cassimeris. 2010. Cancer Biology and Therapy 9: 699–709). We demonstrated this synergy in both Hela cells, where p53 could be restored by depletion of the HPV E6 protein, or in matched HCT116 colon cancer lines differing only in p53 genotype. We are working to identify the signal immediately downstream of stathmin depletion that is responsible for the G2 delay by addressing whether the cell cycle delay is signaled by increased MT stability, or by one of two other stathmin-binding proteins, STAT3 or p27Kip1. In support of increased MT stability serving as a signal relay, we find that a brief incubation in nocodazole, a MT-depolymerizing drug, is sufficient to abrogate the G2 cell cycle delay in both Hela and HCT116p53-/- cell lines. Expression of full-length stathmin or stathmin truncations, combined with depletion of endogenous stathmin, was used to further test the role of increased MT stability in causing a G2 delay. Expression of full length stathmin-GFP, or stathmin N-terminus (deleted of amino acids 101–149)-GFP was sufficient to reduce MT density and abrogate the G2 delay. In contrast, a truncation missing 20 amino acids at the N terminus (deleted of amino acids 5–25) did not depolymerize MTs and did not abrogate the G2 delay. Others previously demonstrated that STAT3 and p27Kip1 bind to stathmin's C-terminus, and this region was not necessary to abrogate the delay, making it unlikely that these proteins act downstream of stathmin depletion. Instead, our results indicate that increased MT stability, in cells lacking p53, stalls cells in G2 and delays entry into mitosis. The stathmin depletion-induced G2 delay is independent of a mitotic defect, since interphase duration, but not mitotic duration is lengthened significantly in stathmin-depleted cells. We find that interphase is approximately 5 hours longer in stathmin-depleted cells, measured either by the time between mitoses for cells growing asynchronously or by the time for cells released from an S phase block to reach mitosis. While our results point to increased MT stability as a signal delaying cell cycle progression, the nature of the signal is not yet known. Working upstream from the delay at mitotic entry, we find that stathmin depletion does not activate Chk1 and does not increase Wee1 level, making the pathways where these proteins function as unlikely contributors to delayed G2 progression. Instead, we find that Aurora A, Plk1 and Pak1 have reduced activity, as measured by reduced levels of activating phosphorylations. These data point to a model where increased MT stability blocks full activation of RhoA and its downstream targets to delay mitotic entry. Increased stable MTs may sequester components necessary for RhoA activation, or these stable MTs may be more difficult to reorganize into a mitotic spindle. Unraveling the remaining steps between stathmin depletion and cell cycle delay and/or apoptosis should identify targets for selective control of cancer cell proliferation and explain why MT stability caused by stathmin depletion and taxol addition induce delays at different cell cycle steps. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the Second AACR International Conference on Frontiers in Basic Cancer Research; 2011 Sep 14-18; San Francisco, CA. Philadelphia (PA): AACR; Cancer Res 2011;71(18 Suppl):Abstract nr C32.

Centrosome and retroviruses: The dangerous liaisons

Centrosomes are the major microtubule organizing structures in vertebrate cells. They localize in close proximity to the nucleus for the duration of interphase and play major roles in numerous cell functions. Consequently, any deficiency in centrosome function or number may lead to genetic instability. Several viruses including retroviruses such as, Foamy Virus, HIV-1, JSRV, M-PMV and HTLV-1 have been shown to hamper centrosome functions for their own profit, but the outcomes are very different. Foamy viruses, HIV-1, JSRV, M-PMV and HTLV-1 use the cellular machinery to traffic towards the centrosome during early and/or late stages of the infection. In addition HIV-1 Vpr protein alters the cell-cycle regulation by hijacking centrosome functions. Enthrallingly, HTLV-1 Tax expression also targets the functions of the centrosome, and this event is correlated with centrosome amplification, aneuploidy and transformation.

Onset of the DNA Replication Checkpoint in the Early Drosophila Embryo

The Drosophila embryo is a promising model for isolating gene products that coordinate S phase and mitosis. We have reported before that increasing maternal Cyclin B dosage to up to six copies (six cycB) increases Cdk1-Cyclin B (CycB) levels and activity in the embryo, delays nuclear migration at cycle 10, and produces abnormal nuclei at cycle 14. Here we show that the level of CycB in the embryo inversely correlates with the ability to lengthen interphase as the embryo transits from preblastoderm to blastoderm stages and defines the onset of a checkpoint that regulates mitosis when DNA replication is blocked with aphidicolin. A screen for modifiers of the six cycB phenotypes identified 10 new suppressor deficiencies. In addition, heterozygote dRPA2 (a DNA replication gene) mutants suppressed only the abnormal nuclear phenotype at cycle 14. Reduction of dRPA2 also restored interphase duration and checkpoint efficacy to control levels. We propose that lowered dRPA2 levels activate Grp/Chk1 to counteract excess Cdk1-CycB activity and restore interphase duration and the ability to block mitosis in response to aphidicolin. Our results suggest an antagonistic interaction between DNA replication checkpoint activation and Cdk1-CycB activity during the transition from preblastoderm to blastoderm cycles.

Nuclear ploidy is contingent on the microtubular cycle responsible for plant cytokinesis

Division of the plant cell relies on the preprophase band of microtubules (PPB)-phragmoplast system. Cells of onion (Allium cepa L.) root meristems were rendered binucleate by preventing the consolidation of cell plate formation in telophase with 5 mM caffeine. These binucleates developed either a single PPB around one of their two nuclei or two PPBs, one per nucleus, in the prophase of the ensuing mitosis. Prophase cells developing one single PPB were shorter in length (42.3 +/- 4.1 microm) than those developing 2 PPBs (49.8 +/- 4.1 microm), and interphase duration was inversely related to cell length. Cells whose length was less than or equal to 42 microm, i.e., which had not even reached the mean size of the small binucleates in prophase, were followed throughout mitosis. In metaphase, they always assembled two mitotic spindles (one per nucleus). However, the cells that had assembled a single PPB also developed a single phragmoplast in telophase, leading to polyploidization. As these meristematic cells were not wide enough to accommodate the midzones of both mitotic spindles in any single plane transversal to the cell elongation axis, the spindles tilted until their midzones formed a continuum where the single common phragmoplast assembled. Its position was thereby uncoupled from that of the preceding PPB. Subsequently, the chromosomes from two different half-spindles were included, by a common nuclear envelope, in a single tetraploid nucleus. Finally, the cytokinetic plate segregated the two tetraploid nuclei formed at each side of the phragmoplast into two independent sister cells.