E. V. Deineko

New insights into cytomixis: specific cellular features and prevalence in higher plants

The phenomenon of intercellular migration of nuclei in plant tissues (cytomixis) was discovered over a century ago, which has been followed by numerous attempts to clarify the essence of this process as well as to determine its causes and consequences. Most attention of researchers has been paid to cytomixis in microsporogenesis, since the transfer of part of genetic material between microsporocytes may influence the ploidy level of the produced pollen and, presumably, have an evolutionary significance. This review compiles the data on cytological pattern of cytomixis and proposes a scheme as to how cytomictic channels are formed and function in angiosperms. The prevalence of cytomixis in different plant taxa is analyzed using the published data. The causes, mechanisms, and consequences of the nuclear migration between cells in plant tissues are discussed.

Characteristics of the cytomictic channel formation in Nicotiana tabacum L. pollen mother cells

Electron-microscopic analysis of cytomictic channels formation in the pollen mother cells in tobacco at the stage of meiosis prophase I of anthers has been conducted. The cytomictic channels in the pollen mother cells in tobacco have been established to be formed under the basis of both single plasmodesmata and de novo with the involvement of specific electron-dense bodies. The role of cytomictic channels in microsporogenesis regulation is discussed.

An ultrastructural study of cytomixis in tobacco pollen mother cells

Intercellular chromatin migration (cytomixis) in the pollen mother cells of two tobacco (Nicotiana tabacum L.) lines was analyzed by electron microscopy during the first meiotic prophase. The maximal manifestation of cytomixis was observed in the pachytene. As a rule, several cells connected with one another by cytomictic channels wherein the nuclei migrated were observable at this stage. In the majority of cases, nuclei passed from cell to cell concurrently through several closely located cytomictic channels. Chromatin migrated between cells within the nuclear envelope, and its disintegration was unobservable. The nucleus, after passing through cytomictic channels into another cell, can be divided into individual micronuclei or, in the case of a direct contact with another nucleus, can form a nuclear bridge. It has been demonstrated that the chromatin structure after intracellular migration visually matches the chromatin structure before it passed through the cytomictic channel. No signs of pyknosis were observable in the chromatin of the micronuclei formed after cytomixis, and the synaptonemal complex was distinctly seen. The dynamics of changes in the nucleoli during cytomixis was for the first time monitored on an ultrastructural level. Possible mechanisms determining cytomixis are discussed and the significance of this process in plant development is considered.

Peculiarities of cytomixis in pollen mother cells of transgenic tobacco plants (Nicotiana tabacum L.) with mutant phenotype

The frequency characteristics and cytological picture of cytomixis in the course of male meiosis are described in transgenic tobacco plants (Nicotiana tabacum L.) with altered flower morphology and male sterility. Effects of cytomixis on qualitative composition of meiotic products are studied (formation of cytoplasts and polyads). Doubling of the chromosome number was established to increase frequency of cytomixis in the studied plants.

How cytomixis can form unreduced gametes in tobacco

Cytomixis is migration of the nuclei between cells, widespread in various higher plant species. Most frequently, cytomixis takes place in microsporogenesis and is assumed to be a possible cause of unreduced gamete generation. In the present work the cytological mechanisms leading to a change in the cell chromosome number via cytomixis in tobacco microsporocytes are described. The amount of chromatin migrating between cells in cytomixis may be different, varying from a single bivalent to the whole nucleus. It is shown that a whole nucleus when migrating from one cell to another displays no signs of injury or degradation and the formed binucleated microsporocyte continues its meiotic division. If individual nuclear fragments rather than the whole nucleus migrate between cells, one or several micronuclei are formed in the recipient cell, which may contact the recipient cell nucleus. The most probable consequence of these events in tobacco microsporogenesis is the unreduced pollen formation.

An ultrastructural study of microsporogenesis in tobacco line SR1

This article provides an ultrastructural atlas of microsporogenesis in the tobacco model line SR1. The stages of cell-wall remodeling and reorganization of the intercellular channels, accompanying this process, are reported for the microspore mother cells. The meiotic changes in the cell nucleus and cytoplasm are traced. The appearance of single-, double-, or multi-membrane nuclear vacuoles in microspore mother cells and their further elimination from the nucleus are for the first time described for the genus Nicotiana as well as deviations from a normal course for this process. Intercellular chromatin migration (cytomixis) was observed in the microsporogenesis of the line SR1 and behavior of the nuclear vacuoles within the cytomictic nucleus was described for the first time. The enzymatic activity of spherosome-like vesicles in the tobacco microsporogenesis is discussed. The features of microsporogenesis in the tobacco line SR1 are compared with those of other plant species and its association with the transition from a diploid to a haploid phase of the life cycle is discussed.

Cytomixis doesn’t induce obvious changes in chromatin modifications and programmed cell death in tobacco male meiocytes

Cytomixis is a poorly studied process of nuclear migration between plant cells. It is so far unknown what drives cytomixis and what is the functional state of the chromatin migrating between cells. Using immunostaining, we have analyzed the distribution of posttranslational histone modifications (methylation, acetylation, and phosphorylation) that reflect the functional state of chromatin in the tobacco microsporocytes involved in cytomixis. We demonstrate that the chromatin in the cytomictic cells does not differ from the chromatin in intact microsporocytes according to all 14 analyzed histone modification types. We have also for the first time demonstrated that the migrating chromatin contains normal structures of the synaptonemal complex (SC) and lacks any signs of apoptosis. As has been shown, the chromatin migrating between cells in cytomixis is neither selectively heterochromatized nor degraded both before its migration to another cell and after it enters a recipient cell as micronuclei. We also showed that cytomictic chromatin contains marks typical for transcriptionally active chromatin as well as heterochromatin. Moreover, marks typical for chromosome condensation, SC formation and key proteins required for the formation of bivalents were also detected at migrated chromatin.

Transcriptional gene silencing in plants

The review presents current data on molecular genetic mechanisms of suppression of the gene (transgene) expression in plants at the transcriptional level. The stages of RNA-directed DNA methylation are discussed in detail. Mutations affecting transcriptional gene inactivation without altering nucleotide sequence methylation are described.

Cytomixis in the cereal (Gramineae) microsporogenesis

The specific features in behavior of the nuclei and chromatin migrating through cytomictic channels as well as in formation of micronuclei in the cereal microsporogenesis have been studied. Immunofluorescence microscopy has allowed for demonstration that the tubulin cytoskeleton does not play a significant role in the intercellular migration of nuclei. Potential involvement of the actin cytoskeleton and SUN–KASH linker complexes in cytomixis is discussed. Comparative analysis of the published and own data suggests that the cytological patterns of cytomixis in monocots and dicots are conserved. As has been shown, each higher ploidy level in the polyploid series of the family Gramineae is accompanied by an increase in the rate of cytomixis independently of individual species. The results confirm the assumption on a correlation between the rate of cytomixis, ploidy level, and genome balance.

Role of Microtubular Cytoskeleton and Callose Walls in the Manifestation of Cytomixis in Pollen Mother Cells of Tobacco Nicotiana tabacum L.

The structure and dynamics of microtubular cytoskeleton and of callose walls in normal pollen mother cells (PMC) of tobacco N. tabacum L. and in cells with intercellular translocation of nuclear material (cytomictic) was studied in the course of the cell cycle. The microtubular cytoskeleton was established as playing no obvious role in the process of cytomixis. The elevated level of cytomictic seems to be due to disturbances of synthesis of callose walls as a result of their attenuation and perforation. Possible causes of cytomictic in tobacco PMC at the cellular level are discussed.