B. Galatis

Microtubules and their organizing centres in differentiating guard cells ofAdiantum capillus veneris

SummaryThe cortical cytoplasm of the young guard cells ofAdiantum capillus veneris is locally differentiated. At an early post-telophase stage, numerous microtubules diverge from the cytoplasm occupying the junctions of the midregion of the ventral wall with the periclinal ones, towards the periclinal and ventral wall faces as well as towards the inner cytoplasm. Microtubule-vesicle complexes (MVCs) are detected in these regions. Their appearance is accompanied by the initiation of local wall thickenings in the same areas.Afterwards, more distinct MVCs anchored to the plasmalemma were seen in the cortical cytoplasm of the periclinal walls, close to the growing thickenings, usually at a distance up to 3μm from them. Sometimes, they seemed to contain an electron dense substance in which the microtubules were embedded. Cortical microtubules converging from more than one direction terminate at the MVCs. Besides, the microtubule population lining the periclinal walls radiate from the regions where the above cytoplasmic formations are localized. The overlying cellulose microfibrils exhibit the same orientation. The vesicles localized at the MVCs appear to be of dictyosomal origin, very electron dense and react positively to periodic acid-thiocarbohydrazide-silver proteinate (PA-TCH-SP) test. Another population of microtubules fan out from the MVCs, entering deeper into the cytoplasm. They become associated with the nucleus and mitochondria, and traverse the peridictyosomal cytoplasm. In some instances the nucleus formed a protrusion towards an MVC and appeared associated with it via microtubules which radiate from the MVC and flank the nuclear envelope.The observations favour the hypothesis that prominent microtubule organizing centres (MTOCs) function in the cortical cytoplasm of the midregion of the periclinal walls surrounding the ventral one for a relatively long time. The MVCs and/or their adjacent plasmalemma sites may represent MTOCs or at least they specify the cortical cytoplasmic sites where microtubules are nucleated.

Experimental studies on the function of the cortical cytoplasmic zone of the preprophase microtubule band

SummaryCentrifugation of young seedlings ofTriticum durum andTriticum aestivum for 8–10 hours at 1,500–2,000 x g causes a serious disorder of the spatial organelle relationships in the interphase as well as the preprophase and mitotic subsidiary cell mother cells (SMCs). The nucleus, most organelles and cytoplasm are displaced to the centrifugal end of the cell, while the vacuoles lie at the other end. However, after centrifugation, the preprophase microtubule bands (PMBs) are nucleated and remain at the expected position close to the guard cell mother cells (GMCs). In some elongated SMCs the PMBs become completely separated from the nucleus. The mitotic spindle exhibits variable orientation and is usually formed at some distance from the PMB cortical zone.Cytokinesis in SMCs is spatially highly disturbed and the cell plate shows a variety of unpredictable dispositions, which seem to be determined by: 1. the position of the preprophase-prophase nucleus and the orientation of the mitotic spindle as well as their spatial relationships to the PMB cortical zone, and 2. the space available for cell plate growth. Many of the daughter cells exhibit a highly variable shape and size in different planes. Usually one edge of the cell plate partly or totally joins the anticlinal parent wall adjacent to the PMB cortical zone.In some SMCs ofZea mays andTriticum aestivum, the junction regions of the periclinal walls with the anticlinal ones, lined by the PMB cortical zone in normal SMCs, are detectably thickened after the arrest of mitosis and the prevention of interphase microtubule formation by a prolonged colchicine treatment. In a small number of protodermal cells of the same plants, participating in the development of stomatal complexes, irregular wall bodies or incomplete wall sheets were formed at wall regions lined by the PMB cortical zone.The presented observations are in line with the following hypotheses: 1. the PMB cortical zone interacts with the growing edges of the cell plate “attracting” it to fuse with the underlying parent wall when the latter approaches the former at a critical distance, and 2. in SMCs particular regions of the PMB cortical zone and/or the adjacent plasmalemma promote the local wall deposition in the absence of microtubules.

FINE STRUCTURAL STUDIES ON THE INTERPHASE AND DIVIDING APICAL CELLS OF SPHACELARIA TRIBULOIDES (PHAEOPHYTA)1

The apical cells of Sphacelaria tribuloides Menegh. are larger than other thallus cells, contain more organelles and appear polarized. Their tip portion, where they grow, contains a well developed Golgi apparatus, abundant endoplasmic reticulum (ER) membranes, mitochondria, chloroplasts and a large number of small vacuoles. It seems likely that a continuous flow of membranous material from the ER membranes to the dictyosomes and from the latter to the plasmalemma of the extending tip portion takes place. In contrast, the basal pole possesses fewer organelles and is occupied mainly by large‐sized, sometimes central vacuoles. The apical cells undergo two distinct types of highly asymmetrical differential divisions giving rise to cells of the thallus and hair initials. During the early stages of mitosis the nuclear envelope remains intact, except for fenestrated poles. Microtubules pass through the fenestrae into the nucleoplasm. During meta‐phase, a typical chromosome plate is organized. The sites of attachment of spindle microtubules to the chromosomes are structurally different from the rest of the chromosomes. At late anaphase, the nuclear envelope breaks down completely. During telophase, a new membrane encloses the chromosomes which are decondensed and the nucleoli are reorganized. Cytokinesis proceeds long after mitosis at a stage in which the nuclei have increased in size and have moved farther apart. A membranous furrow develops centripetally, without the participation of microtubules. However, microtubules traverse the thin cytoplasmic strands which, in both interphase and cytokinetic cells, meander among the vacuoles of the basal pole of the cell and the internuclear space. Dictyosomes appear to be involved in the subsequent wall deposition.

Disturbance of reactive oxygen species homeostasis induces atypical tubulin polymer formation and affects mitosis in root-tip cells of Triticum turgidum and Arabidopsis thaliana.

In this study, the effects of disturbance of the reactive oxygen species (ROS) homeostasis on the organization of tubulin cytoskeleton in interphase and mitotic root‐tip cells of Triticum turgidum and Arabidopsis thaliana were investigated. Reduced ROS levels were obtained by treatment with diphenylene iodonium (DPI) and N‐acetyl‐cysteine, whereas menadione was applied to achieve ROS overproduction. Both increased and low ROS levels induced: (a) Macrotubule formation in cells with low ROS levels and tubulin paracrystals under oxidative stress. The protein MAP65‐1 was detected in treated cells, exhibiting a conformation comparable to that of the atypical tubulin polymers. (b) Disappearance of microtubules (MTs). (c) Inhibition of preprophase band formation. (d) Delay of the nuclear envelope breakdown at prometaphase. (e) Prevention of perinuclear tubulin polymer assembly in prophase cells. (f) Loss of bipolarity of prophase, metaphase and anaphase spindles. Interestingly, examination of the A. thaliana rhd2/At respiratory burst oxidase homolog C (rbohc) NADPH oxidase mutant, lacking RHD2/AtRBOHC, gave comparable results. Similarly to DPI, the decreased ROS levels in rhd2 root‐tip cells, interfered with MT organization and induced macrotubule assembly. These data indicate, for first time in plants, that ROS are definitely implicated in: (a) mechanisms controlling the assembly/disassembly of interphase, preprophase and mitotic MT systems and (b) mitotic spindle function. The probable mechanisms, by which ROS affect these processes, are discussed.

Microtubules and morphogenesis in ordinary epidermal cells ofVigna sinensis leaves

SummaryUndifferentiated ordinary epidermal cells (ECs) ofVigna sinensis leaves possess straight anticlinal walls and cortical microtubules (Mts) scattered along them. At an early stage of EC differentiation cortical Mts adjacent to the above walls form bundles normal to the leaf plane, loosely interconnected through the cortical cytoplasm of the internal periclinal wall. At the upper ends of the Mt bundles, Mts fan out towards the external periclinal wall and form radial arrays. Mt bundles and radial arrays exhibit strict alternate disposition between neighbouring ECs. An identical reticulum of cellulose microfibril (CM) bundles is deposited outside the Mt bundles. Local wall pads rise at the junctions of anticlinal walls with the external periclinal one, where the CM bundles terminate. They display radial CMs fanning towards the external periclinal wall. The CM bundles and radial CM systems prevent local cell bulging, but allow it in the intervening wall areas. In particular, the radial CM systems dictate the pattern of EC waviness by favouring local tangential expansion of external periclinal wall. As a result, ECs obtain an undulate appearance. “Constrictions” in one EC correspond with protrusions of adjacent ECs. ECs affected by colchicine entirely lose their Mts and do not develop wavy walls, an observation substantiating the role of cortical Mts in EC morphogenesis.

Synchronous organization of two preprophase microtubule bands and final cell plate arrangement in subsidiary cell mother cells of someTriticum species

SummaryIn the primary leaves of threeTriticum species examined, two successive guard cell mother cells (GMCs) are often laterally flanked by one epidermal cell which is induced twice by them and forms two subsidiary cells (SCs). In the case of simultaneous induction of the common subsidiary cell mother cell (SMC) by the GMCs, its nucleus does not migrate towards either of the GMCs, but occupies a position between them. Unexpectedly, in a number of the above “double-polarized” SMCs, two preprophase microtubule bands (PMBs) are organized at the same time, apposed on the GMCs at the expected positions. In some of those cells the daughter wall exhibits aberrant dispositions and either a small lens-shaped cell adjacent to the intervening cell between the GMCs or a large SC alongside both the GMCs and the intervening cell, or an SC flanking one GMC and a part of the intervening cell between the GMCs are separated. Obviously, the sites of fusion of the cell plate with the parent walls do not coincide completely with those of either of the PMB cortical zones. These cell plates appear to intersect those parental walls which are common with the intervening cells at PMB cortical sites belonging to two PMBs. Besides, the one end of the cell plate may pass from the cortical zone of the one PMB to another of the other PMB.The SC nucleus retains the telophase size and chromatin condensation for a longer time period than the other nucleus. This nuclear lag-phase may persist up to the completion of the GMC division, when all the cells of the stomatal complex undergo a coordinated growth and differentiation. The telophase SC nucleus frequently interacts with the phragmoplast microtubules attached on the nuclear envelope. They appear to be pulling the nucleus which forms acute local extensions towards the terminal anticlinal regions of the cell plate. Despite the above-mentioned nuclear behaviour, it does not seem likely that the curved growth of the cell plate is controlled by the SC telophase nucleus. The PMB cortical zone seems to affect the direction of growth of the expanding cell plate, thus controlling its final orientation. In few SMCs in which the prophase nucleus was localized at some distance from the GMC, it formed an acute angular extension towards it. This phenomenon probably indicates the stabilization mechanism of the one pole of the mitotic spindle close to the GMC and implies that the nucleus interacts with the polarized cortical cytoplasm adjacent to the inducing GMC.

Immunofluorescence and electron microscopic studies of microtubule organization during the cell cycle ofDictyota dichotoma (Phaeophyta, Dictyotales)

SummaryInterphase cells ofDictyota dichotoma (Hudson) Lamour. lack cortical microtubules (Mts) but display an impressive network of cytoplasmic microtubules (c-Mts). These are focussed on two opposed perinuclear centriolar sites where centrin or a centrin-homologue is localized. Some of the Mts surround the nucleus, but the majority traverse the cytoplasm as bundles variously directed towards the plasmalemma. In apical cells, and to a lesser extent in the square or slightly elongated meristematic cells, Mts are more or less evenly arranged. In elongated cells they form thick bundles longitudinally traversing the cytoplasm; a pattern maintained in differentiated cells. In early prophase the non-perinuclear Mts disappear but by late prophase a bi-astral arrangement of short Mts is observed. They enter polar nuclear depressions and attach to differentiated regions of the nuclear envelope where polar gaps open. By metaphase the spindle Mts converge on the centrioles at the polar gaps. At anaphase, interzonal Mts are evident and the asters start to reassemble. After telophase disruption of the interzonal Mts, the daughter nuclei approach each other, but move apart again before cytokinesis. The latter movement keeps pace with the development of two interdigitating Mt systems, ensheathing both daughter nuclei. The partition membrane “bisects” this Mt “cage”. Between telophase and cytokinesis the centrosomes separate, finally occupying opposed perinuclear sites. New Mts arise at the new centrosomes, some terminating on the consolidating partition membrane. Our data show thatD. dichotoma vegetative cells display a prominent cytoplasmic Mt cytoskeleton, which undergoes continual, but definite, change in organization during the cell cycle.

Patterns of cortical and perinuclear microtubule organization in meristematic root cells ofAdiantum capillus veneris

SummaryThe interphase meristematic root cells ofAdiantum capillus venerispossess a well developed cytoskeleton of cortical microtubules (Mts), which disappear at prophase. The preprophase-prophase cells display a well organized preprophase microtubule band (PMB) and a perinuclear Mt system. The observations favour the suggestion that the cell edges included in the PMB cortical zone possess a Mt organizing capacity and thus play an important role in PMB formation. The perinuclear Mts are probably organized on the nuclear surface. The preprophase-prophase nuclei often form protrusions towards the PMB cortical zone and the spindle poles, assuming a conical or rhomboid shape. Mts may be involved in this nuclear shaping.Reinstallation of cortical Mts in dividing cells begins about the middle of cytokinesis with the reappearance of short Mts on the cell surface. When cytokinesis terminates, numerous Mts line the postcytokinetic daughter wall. Many of them converge or form clusters in the cytoplasm occupying the junctions of the new and the old walls. In the examined fern, the cortical Mt arrays seem to be initiated in the cortex of post-cytokinetic root cells. A transitory radial perinuclear Mt array, comparable to that found in post-telophase root cells of flowering plants, was not observed inA. capillus veneris.

Aluminium Effects on Microtubule Organization in Dividing Root-Tip Cells of Triticum turgidum. II. Cytokinetic Cells

Triticum turgidum were examined, using tubulin immunolabeling and electron microscopy. In cells, which at the beginning of the treatment were at a transitional stage between anaphase and telophase, the transformation of the interzonal microtubule (Mt) system into a phagmoplast was delayed. In cells treated at a telophase/ cytokinetic stage, the lateral phragmoplast expansion towards the cell periphery was delayed or inhibited. Besides, in cells entering telophase through an abnormal mitosis, Al inhibited phragmoplast formation and induced the organization of atypical tubulin bundles. The latter formed a network around the reassembling polyploid nucleus. The Al-effects resulted in the disturbance of cytokinesis and the formation of binuclear or polyploid cells, which lacked typical Mts. Instead of them, the post-telophase cells displayed atypical tubulin aggregations. In addition, Al affects cell plate development. Dividing cells, encompassing early interphase daughter nuclei, contained incomplete, atypical cell plates. The latter were quite thick, wavy and perforated, showing large “islands”, which contained electron transparent material. In some cells, the atypical cell plates gave rise to incomplete daughter walls, but in some others they were dismantled. The aberrant cell plates as well as the young daughter cell walls fluoresced intensely after aniline blue staining, an observation suggesting that they contain significant quantities of callose. The above findings combined with those derived from the study of the Al-effects on the mitotic spindle show that Mt cytoskeleton is a target site of Al toxicity in dividing cells.

Studies on the development of the air pores and air chambers ofMarchantia paleacea

SummaryThe preprophase-prophase initial aperture (IA) cells ofMarchantia paleacea undergo a particular sequence of protoplasmic changes, which reflects the establishment of an unusual premitotic polarization. The marking feature of preprophase-prophase thallus cells is the shape of the nucleus which becomes spindle-shaped. This phenomenon accompanies the organization of an extranuclear microtubule (MT) sheath, nucleated and/or organized by distinct polar MT organizing centres (MTOCs).The interphase MTs disappear after activation of polar MTOCs. In preprophase IA cells incomplete preprophase MT bands (PMBs) are organized. They consist of PMB portions which traverse only small portions of the cell cortex at the level of the future cytokinesis and do not form a complete ring. In the same cells other MT bundles, independent of the incomplete PMBs terminate in the cortical cytoplasm abutting on the lower part of the intercellular spaces (ISs) or the surface cavities (SCs). Almost complete or complete PMBs are organized in IA cells in which the plane of PMB formation coincides with that passing through ISs of the same growth.The observations suggest that in preprophase-prophase IA cells ofMarchantia paleacea cortical MTOCs function in regions distant from each other: One region is the PMB cortical cytoplasm, probably that covering the wall edges, and the other is the one adjacent to the lower part of the wall facing the IS(s) or that underlying the SCs. The competition between the cortical MTOCs as well as between them and the polar ones may be responsible for the organization of incomplete PMBs.