Microtubule organization in the apical cell of Sphacelaria (Phaeophyceae) and its related protoplast

The growth of the filamentous brown alga Sphacelaria depends on a large, strongly polarized, apical cell. The protoplast derived from this cell can be distinguished in a heterogeneous suspension by cytological markers, so it is possible to study development of the cytoskeleton during protoplast isolation and the first steps of regeneration. In the initial cell, microtubules show an asymmetric distribution along the axis; they are mainly located at the distal part around the physodes. After protoplast isolation, this polarity initially seems to be maintained; subsequently, the microtubules radiate from the two centrioles and spread out to the plasmalemma. This experimental model is suitable for investigating the development of the polarity of the initial cell, and the sequence of the first morphogenetic events leading to protoplast regeneration.     

Cytoskeleton and morphogenesis in brown algae

BACKGROUND: Morphogenesis on a cellular level includes processes in which cytoskeleton and cell wall expansion are strongly involved. In brown algal zygotes, microtubules (MTs) and actin filaments (AFs) participate in polarity axis fixation, cell division and tip growth. Brown algal vegetative cells lack a cortical MT cytoskeleton, and are characterized by centriole-bearing centrosomes, which function as microtubule organizing centres. SCOPE: Extensive electron microscope and immunofluorescence studies of MT organization in different types of brown algal cells have shown that MTs constitute a major cytoskeletal component, indispensable for cell morphogenesis. Apart from participating in mitosis and cytokinesis, they are also involved in the expression and maintenance of polarity of particular cell types. Disruption of MTs after Nocodazole treatment inhibits cell growth, causing bulging and/or bending of apical cells, thickening of the tip cell wall, and affecting the nuclear positioning. Staining of F-actin using Rhodamine-Phalloidin, revealed a rich network consisting of perinuclear, endoplasmic and cortical AFs. AFs participate in mitosis by the organization of an F-actin spindle and in cytokinesis by an F-actin disc. They are also involved in the maintenance of polarity of apical cells, as well as in lateral branch initiation. The cortical system of AFs was found related to the orientation of cellulose microfibrils (MFs), and therefore to cell wall morphogenesis. This is expressed by the coincidence in the orientation between cortical AFs and the depositing MFs. Treatment with cytochalasin B inhibits mitosis and cytokinesis, as well as tip growth of apical cells, and causes abnormal deposition of MFs. CONCLUSIONS: Both the cytoskeletal elements studied so far, i.e. MTs and AFs are implicated in brown algal cell morphogenesis, expressed in their relationship with cell wall morphogenesis, polarization, spindle organization and cytokinetic mechanism. The novelty is the role of AFs and their possible co-operation with MTs.     

Microtubular organization and its involvement in the biogenetic pathways of plasma membrane proteins in Caco-2 intestinal epithelial cells

We characterized the three-dimensional organization of microtubules in the human intestinal epithelial cell line Caco-2 by laser scanning confocal microscopy. Microtubules formed a dense network approximately 4-microns thick parallel to the cell surface in the apical pole and a loose network 1-micron thick in the basal pole. Between the apical and the basal bundles, microtubules run parallel to the major cell axis, concentrated in the vicinity of the lateral membrane. Colchicine treatment for 4 h depolymerized 99.4% of microtubular tubulin. Metabolic pulse chase, in combination with domain-selective biotinylation, immune and streptavidin precipitation was used to study the role of microtubules in the sorting and targeting of four apical and one basolateral markers. Apical proteins have been recently shown to use both direct and transcytotic (via the basolateral membrane) routes to the apical surface of Caco-2 cells. Colchicine treatment slowed down the transport to the cell surface of apical and basolateral proteins, but the effect on the apical proteins was much more drastic and affected both direct and indirect pathways. The final effect of microtubular disruption on the distribution of apical proteins depended on the degree of steady-state polarization of the individual markers in control cells. Aminopeptidase N (APN) and sucrase-isomaltase (SI), which normally reach a highly polarized distribution (110 and 75 times higher on the apical than on the basolateral side) were still relatively polarized (9 times) after colchicine treatment. The decrease in the polarity of APN and SI was mostly due to an increase in the residual basolateral expression (10% of control total surface expression) since 80% of the newly synthesized APN was still transported, although at a slower rate, to the apical surface in the absence of microtubules. Alkaline phosphatase and dipeptidylpeptidase IV, which normally reach only low levels of apical polarity (four times and six times after 20 h chase, nine times and eight times at steady state) did not polarize at all in the presence of colchicine due to slower delivery to the apical surface and increased residence time in the basolateral surface. Colchicine-treated cells displayed an ectopic localization of microvilli or other apical markers in the basolateral surface and large intracellular vacuoles. Polarized secretion into apical and basolateral media was also affected by microtubular disruption. Thus, an intact microtubular network facilitates apical protein transport to the cell surface of Caco-2 cells via direct and indirect routes; this role appears to be crucial for the final polarity of some apical plasma membrane proteins but only an enhancement factor for others.     

Ontogenesis in the Fucophyceae: case studies and comparison of fucoid zygotes and Sphacelaria apical cells

In multicellular eukaryotes, the zygote, a single cell, gives rise to the different cell types of the organism. The study of the mechanisms involved is a key point of developmental biology. Generally, the first stages are characterized by an orderly sequence of asymmetrical divisions resulting from an initial developmental polarity. The establishment of this initial polarity has been the subject of numerous studies in animals, but not in higher plants since the zygote is encased in several layers of tissues that prevent experimental approaches. Moreover, plant development is characterized by two successive ontogenetic steps: the construction of the embryonic apico-basal axis and the establishment of meristems in charge of organogenesis. Members of the Fucophyceae provide good models for the investigation of these processes. Any inferred homology of mechanisms must take into account the polyphyletic nature of the algae. This paper is a tentative review of two case studies: fucoid zygotes and Sphacelaria apical cells, and deals respectively with the two successive ontogenetic steps characteristic of higher plant development. The first part concerns development of the fucoid zygotes. Fucoid zygotes, including those of different species, are considered as model systems in plants for studying the establishment of the polarity axis because, at the moment of fertilization, they do not have any morphological or biochemical polarity. This report concerns progress in the identification of some cellular or molecular mechanisms involved in the settlement and/or stabilization of the polarity axis, and the consequence of this polar organisation for the control of asymmetrical divisions and the building of a functional embryo. The second part concerns the apical cell of Sphacelaria as a model for establishing and maintaining a meristematic cell. The apical cell exhibits a permanent polarized organisation throughout repetitive asymmetric divisions and can be comparatively analysed in situ and isolated as a protoplast. This allowed us to investigate the evolution of the cytoplasmic cytoskeleton, centrosomes and the mitotic apparatus during the cell cycle in relation to the cell polarity; particularly the interactions between the cytoskeleton and cell wall. For the two models, the results are compared with mechanisms involved in the development of other multicellular organisms, and their value in gaining an insight into higher plant ontogenesis is assessed.     

ORIENTATION OF THE PLANE OF CELL DIVISION IN FERN GAMETOPHYTES: THE ROLES OF CELL SHAPE AND STRESS

Apical cells of Onoclea sensibilis L. protonemata were measured to determine areas of new walls which were formed during both transverse and longitudinal cell division. Actual wall areas were compared with calculated areas of hypothetical walls oriented in the opposite sense (i.e., an actual transverse wall compared with a hypothetical longitudinal wall, and the reverse). Among 87 out of 90 cells which were analyzed the actual walls had the least area. Thus, the minimal area hypothesis of cell partitioning accurately predicts wall orientation in this instance, although it appears, on other grounds, that the hypothesis does not furnish a plausible mechanism for wall orientation. The application of Lintilhac's concept of the orientation of cell walls in response to anisotropic stresses in the cell was explored. Photographs of apical cells during deplasmolysis indicated that unequal stresses might be generated in apical cells as a result of the osmotic distension of the elastic protoplast. It is concluded that the primary factor which determines the plane of cell division in the apical cell, and the transition from one- to two-dimensional growth, is the local pattern of stress which exists at the position of the nucleus at the time of onset of cell division and wall formation. Calculations of some geometrical properties of idealized model cells are interpreted to mean that the accuracy of the minimal area hypothesis results from a coincidence of its predictions with predictions of Lintilhac's hypothesis, and no causal significance is attributed to wall areas.     

The density of apical cells of dark-grown protonemata of the mossCeratodon purpureus

Summary Determinations of plant or algal cell density (cell mass divided by volume) have rarely accounted for the extracellular matrix or shrinkage during isolation. Three techniques were used to indirectly estimate the density of intact apical cells from protonemata of the mossCeratodon purpureus. First, the volume fraction of each cell component was determined by stereology, and published values for component density were used to extrapolate to the entire cell. Second, protonemal tips were immersed in bovine serum albumin solutions of different densities, and then the equilibrium density was corrected for the mass of the cell wall. Third, apical cell protoplasts were centrifuged in low-osmolarity gradients, and values were corrected for shrinkage during protoplast isolation. Values from centrifugation (1.004 to 1.015 g/cm³) were considerably lower than from other methods (1.046 to 1.085 g/cm³). This work appears to provide the first corrected estimates of the density of any plant cell. It also documents a method for the isolation of protoplasts specifically from apical cells of protonemal filaments.Abbreviations BSA bovine serum albumin - ER endoplasmic reticulum - V_v volume fraction     

Uniform apicobasal polarity of microtubules and apical location of gamma-tubulin in polarized intestinal epithelium in situ

Polarized differentiation of the intestinal epithelium has been previously shown to depend on an intact microtubular system that is essential for vectorial delivery of apical membrane proteins to the apical cell surfaces. Uniform alignment and polarization of microtubules have been suggested to provide the ultrastructural basis for vectorial transport between the Golgi apparatus and the apical cell surface. In the present study we applied the hook decoration technique to analyse the polarity of microtubules in the rat jejunal epithelium. By immunocytochemistry we studied the subcellular location of gamma-tubulin, an essential component of microtubule-organizing centers. Microtubules were found to be mainly aligned parallel to the apicobasal axis of the cells and to extend from the subterminal space underneath the apical terminal web down to the cellular basis. We found that 98% out of 1122 decorated microtubules displayed uniform apicobasal polarity with the growing ends (plus ends) pointing basally and the non-growing ends (minus ends) pointing towards the cellular apex. No differences were observed with respect to microtubular polarity between the apical, perinuclear and infranuclear cellular portions. Immunostaining specific for gamma-tubulin was restricted to the apical subterminal space underneath the rootlets of microvilli. These findings indicate that the apical subterminal space of enterocytes serves as the predominant if not exclusive microtubule-organizing compartment from which uniformly polarized microtubules grow out with their plus ends towards the cellular basis.     

Tissue degradation and enzymatic activity observed during protoplast isolation in two ornamental <Emphasis Type="Italic">Grevillea</Emphasis> species

Summary Degradative changes in tissue during protoplast isolation were a contributing factor to low protoplast yields in the saltsensitive Grevillea arenaria (R. Brown) and the salt-tolerant Grevillea ilicifolia (R. Brown). Protein and malondialdehyde content decreased significantly during the protoplast isolation procedure. Acid and neutral proteases were identified, and high acid protease activities were correlated to low protoplast yields. Acid phosphatase, catalase, polyphenol oxidase and lipoxygenase activities increased in both Grevillea species with cell wall digestion. High activities of catalase and low levels of polyphenol oxidase were correlated with high protoplast yields. Levels of acid phosphatase and lipoxygenase were not good indicators of final protoplast yields. The addition of the anti-oxidant, reduced glutathione, and the acid protease inhibitor, pepstatin A, significantly increased protoplast yields. Strategies were identified to minimize deleterious degradative effects during the isolation of protoplasts, including strict pH control, testing a number of cell wall digestion enzymes, and the addition of anti-oxidative metabolites and protease inhibitors.     

Protoplast fusion in the yeast, Schwanniomyces alluvius

Summary This first application of the technique of protoplast fusion to Schwanniomyces suggests that it is possible to overcome the genetic isolation of this genus imposed by its inability to undergo conventional intraspecific mating. The stability, increased ploidy, and cell volumes of such fusion hybrids over the parental strains indicate the possibility of construction of polyploid strains suitable for use in industry.Nuclear fusion (karyogamy) appears to occur in intraspecific hybrids as evidenced by isolation of recombinants after mitotic segregation of parental auxotrophic genetic markers.Intergeneric hybrids formed from Schw. alluvius and Saccharomyces spp. were unstable and spontaneously segregated into original auxotrophic parent cultures. Genetic diversity between these genera may be too great to allow stable co-existance of the two genomes within a single nucleus. Nuclear fusion in such cases could not be confirmed.     

Dynamic Actin Controls Polarity Induction de novo in Protoplasts

Cell polarity and axes are central for plant morphogenesis. To study how polarity and axes are induced de novo, we investigated protoplasts of tobacco Nicotiana tabacum cv. BY-2 expressing fluorescently-tagged cytoskeletal markers. We standardized the system to such a degree that we were able to generate quantitative data on the temporal patterns of regeneration stages. The synthesis of a new cell wall marks the transition to the first stage of regeneration, and proceeds after a long preparatory phase within a few minutes. During this preparatory phase, the nucleus migrates actively, and cytoplasmic strands remodel vigorously. We probed this system for the effect of anti-cytoskeletal compounds, inducible bundling of actin, RGD-peptides, and temperature. Suppression of actin dynamics at an early stage leads to aberrant tripolar cells, whereas suppression of microtubule dynamics produces aberrant sausage-like cells with asymmetric cell walls. We integrated these data into a model, where the microtubular cytoskeleton conveys positional information between the nucleus and the membrane controlling the release or activation of components required for cell wall synthesis. Cell wall formation is followed by the induction of a new cell pole requiring dynamic actin filaments, and the new cell axis is manifested as elongation growth perpendicular to the orientation of the aligned cortical microtubules.     

Structural and ultrastructural analysis of Solanum lycopersicoides protoplasts during diploid plant regeneration

Light, fluorescence and electron microscopy were used to analyse the structural properties of protoplasts obtained from established suspension culture of Solanum lycopersicoides Dun, composed of meristematic cell aggregates. Four types of protoplasts were distinguished immediately after isolation: (1) mononuclear; (2) polynuclear, (3) anuclear and (4) homogeneous protoplasts. Only mononuclear protoplasts were capable of complete cell wall regeneration and mitotic division. Other types of protoplasts were eliminated during culture. Three phases were distinguished in the developing protoplast culture: (1) the elimination phase during which protoplasts damaged during isolation underwent complete degradation; (2) a phase of intense division during which both mitotic cell division and amitotic nuclear division took place; and (3) a stabilization phase leading to the formation of suspension culture. The cell suspension culture obtained from protoplasts was capable of regenerating diploid plants.     

Apical F‐actin‐regulated exocytic targeting of NtPPME1 is essential for construction and rigidity of the pollen tube cell wall

In tip‐confined growing pollen tubes, delivery of newly synthesized cell wall materials to the rapidly expanding apical surface requires spatial organization and temporal regulation of the apical F‐actin filament and exocytosis. In this study, we demonstrate that apical F‐actin is essential for the rigidity and construction of the pollen tube cell wall by regulating exocytosis of Nicotiana tabacum pectin methylesterase (NtPPME1). Wortmannin disrupts the spatial organization of apical F‐actin in the pollen tube tip and inhibits polar targeting of NtPPME1, which subsequently alters the rigidity and pectic composition of the pollen tube cell wall, finally causing growth arrest of the pollen tube. In addition to mechanistically linking cell wall construction and apical F‐actin, wortmannin can be used as a useful tool for studying endomembrane trafficking and cytoskeletal organization in pollen tubes.     

Cytological Events during Zygote Formation of the Fern Ceratopteris thalictroides

The cytological events, including nuclear fusion, digestion of male organelles and rebuilding of the plasmalemma and cell wall, during zygote formation of the fern Ceratopteris thalictroides (L.) Brongn. are described based on the observations of transmission electron microscopy. When the spermatozoid enters the egg and contacts the cytoplasm, the male chromatin relaxes continually. The microtubular ribbon (MTr) is separated from the male nucleus and then an envelope reappears around the male nucleus. During nuclear fusion, the egg nucleus becomes highly irregular and extends some nuclear protrusions. It is proposed that the protrusions fuse with the male nucleus actively. After nuclear fusion the irregular zygotic nucleus contracts gradually. It becomes spherical before the zygote divides. The male chromatin is identifiable as fibrous structure in the zygotic nucleus in the beginning, but it gradually becomes diffused completely. The male organelles, including the MTr, multilayered structure, flagella and the male mitochondria are finally digested in the zygotic cytoplasm. Finally a new plasmalemma and cell wall are formed outside the protoplast. The organelles in the zygote are rearranged, which produces a horizontal polarity zygote. The zygote divides with an oblique-vertical cell plate facing the apical notch of the gametophyte.     

Studies of cotyledon protoplast cultures from Brassica napus,B. campestris and B. oleracea. I: Cell wall regeneration and cell division

Protoplasts isolated from cotyledons of a number of cultivars of Brassica napus, B. campestris and B. oleracea were cultured in different media to study the characteristics of cell wall regeneration and cell division at early stages of culture. Time course analysis using Calcolfluor White staining indicated that cell wall regeneration began in some protoplasts 2–4 h following isolation in all cultivars. 30–70% of cultured cotyledon protoplasts exhibited cell wall regeneration at 24 h and about 60–90% at 72 h after the initiation of culture. Results also indicated that a low percentage (0.4–5.4%) of cultured cotyledon protoplasts entered their first cell division one day after initial culture in all twelve cultivars. The percentage of dividing cells increased linearly up to 40% from 1 to 7 day, indicating that cotyledon protoplasts of Brassica had a high capacity for cell division. Factors that influence the level of cell wall regeneration and cell division during cotyledon protoplast culture have been investigated in this study. Cotyledons from seedlings germinated in a dark/dim light regime provided a satisfactory tissue source for protoplast isolation and culture for all Brassica cultivars used. The percentages of protoplasts exhibiting cell wall regeneration and division were significantly influenced by cultivar and species examined, with protoplasts from all five cultivars of B. campestris showing much lower rates of cell wall regeneration than those of B. napus and B. oleracea over 24–120 h, and with the levels of cell division in B. napus cultivars being much higher than those in B. campestris and B. oleracea over 1–9 days. The capacity of cell wall regeneration and cell division in cotyledon protoplast culture of the Brassica species appears under strong genetic control. Cell wall regeneration in protoplast culture was not affected by the culture medium used. In contrast, the composition of the culture medium played an important role in determining the level of cell division, and the interaction between medium type and cultivars was very significant.Abbreviations BA benzylaminopurine - CPW Composition of Protoplast Washing-solution - CW Calcolfluor White - EDTA ethylenediamine-tetraacetic acid - KT Kinetin - Md MS modified Murashige and Skoog medium - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA -naphthaleneacetic acid - IAA indole-3-acetic acid - PAR photosynthetically active radiation - SDS sodium dodecyl sulfate     

Seaweed protoplasts: status,biotechnological perspectives and needs

Protoplasts are living plant cells without cell walls which offer a unique uniform single cell system that facilitates several aspects of modern biotechnology, including genetic transformation and metabolic engineering. Extraction of cell wall lytic enzymes from different phycophages and microbial sources has greatly improved protoplast isolation and their yield from a number of anatomically more complex species of brown and red seaweeds which earlier remained recalcitrant. Recently, recombinant cell wall lytic enzymes were also produced and evaluated with native ones for their potential abilities in producing viable protoplasts from Laminaria. Reliable procedures are now available to isolate and culture protoplasts from diverse groups of seaweeds. To date, there are 89 species belonging to 36 genera of green, red and brown seaweeds from which successful protoplast isolation and regeneration has been reported. Of the total species studied for protoplasts, most belonged to Rhodophyta with 41 species (13 genera) followed by Chlorophyta and Phaeophyta with 24 species each belonging to 5 and 18 genera, respectively. Regeneration of protoplast-to-plant system is available for a large number of species, with extensive literature relating to their culture methods and morphogenesis. In the context of plant genetic manipulation, somatic hybridization by protoplast fusion has been accomplished in a number of economically important species with various levels of success. Protoplasts have also been used for studying foreign gene expression in Porphyra and Ulva. Isolated protoplasts are also exploited in numerous miscellaneous studies involving membrane function, cell structure, bio-chemical synthesis of cell walls etc. This article briefly reviews the status of various developments in seaweed protoplasts research and their potentials in genetic improvement of seaweeds, along with needs that must to be fulfilled for effective realization of the objectives envisaged for protoplast research.     

Two phases of chromatin decondensation during dedifferentiation of plant cells: distinction between competence for cell fate switch and a commitment for S phase

Cellular dedifferentiation is the major process underlying totipotency, regeneration, and formation of new stem cell lineages in multicellular organisms. In animals it is often associated with carcinogenesis. Here, we used tobacco protoplasts (plant cells devoid of cell wall) to study changes in chromatin structure in the course of dedifferentiation of mesophyll cells. Using flow cytometry and micrococcal nuclease analyses, we identified two phases of chromatin decondensation prior to entry of cells into S phase. The first phase takes place in the course of protoplast isolation, following treatment with cell wall degrading enzymes, whereas the second occurs only after protoplasts are induced with phytohormones to re-enter the cell cycle. In the absence of hormonal application, protoplasts undergo cycles of chromatin condensation/decondensation and die. The ubiquitin proteolytic system was found indispensable for protoplast progression into S phase, being required for the second but not the first phase of chromatin decondensation. The emerging model suggests that cellular dedifferentiation proceeds by two functionally distinct phases of chromatin decondensation: the first is a transitory phase that confers competence for cell fate switch, which is followed, under appropriate conditions, by a second proteasome-dependent phase representing a commitment for the mitotic cycle. These findings might have implications for a wide range of dedifferentiation-driven cellular processes in higher eukaryotes.     

Central Roles of Small GTPases in the Development of Cell Polarity in Yeast and Beyond

Summary: The establishment of cell polarity is critical for the development of many organisms and for the function of many cell types. A large number of studies of diverse organisms from yeast to humans indicate that the conserved, small-molecular-weight GTPases function as key signaling proteins involved in cell polarization. The budding yeast Saccharomyces cerevisiae is a particularly attractive model because it displays pronounced cell polarity in response to intracellular and extracellular cues. Cells of S. cerevisiae undergo polarized growth during various phases of their life cycle, such as during vegetative growth, mating between haploid cells of opposite mating types, and filamentous growth upon deprivation of nutrition such as nitrogen. Substantial progress has been made in deciphering the molecular basis of cell polarity in budding yeast. In particular, it becomes increasingly clear how small GTPases regulate polarized cytoskeletal organization, cell wall assembly, and exocytosis at the molecular level and how these GTPases are regulated. In this review, we discuss the key signaling pathways that regulate cell polarization during the mitotic cell cycle and during mating.     

Par1b Induces Asymmetric Inheritance of Plasma Membrane Domains via LGN-Dependent Mitotic Spindle Orientation in Proliferating Hepatocytes

The development and maintenance of polarized epithelial tissue requires a tightly controlled orientation of mitotic cell division relative to the apical polarity axis. Hepatocytes display a unique polarized architecture. We demonstrate that mitotic hepatocytes asymmetrically segregate their apical plasma membrane domain to the nascent daughter cells. The non-polarized nascent daughter cell can form a de novo apical domain with its new neighbor. This asymmetric segregation of apical domains is facilitated by a geometrically distinct “apicolateral” subdomain of the lateral surface present in hepatocytes. The polarity protein partitioning-defective 1/microtubule-affinity regulating kinase 2 (Par1b/MARK2) translates this positional landmark to cortical polarity by promoting the apicolateral accumulation of Leu-Gly-Asn repeat-enriched protein (LGN) and the capture of nuclear mitotic apparatus protein (NuMA)–positive astral microtubules to orientate the mitotic spindle. Proliferating hepatocytes thus display an asymmetric inheritance of their apical domains via a mechanism that involves Par1b and LGN, which we postulate serves the unique tissue architecture of the developing liver parenchyma.     

Cytocortical organization during natural and prolonged mitosis of mouse 8-cell blastomeres

Late 8-cell blastomeres were harvested within the first 45 min after entering mitosis. Some mitotic cells were analysed within the ensuing 2 h for the organization of their surface in relation to their progress through mitosis. Whereas in most late interphase cells microvilli were restricted to a discrete polar region, in mitotic cells at all stages from early metaphase to immediately postcytokinesis microvilli were found to be present over more of the cell surface. Other mitotic cells were placed in nocodazole to arrest them in M-phase for up to 10 h. They were found to show an even more extensive distribution of microvilli over the whole surface, the longer periods of incubation yielding more extended coverage such that many cells no longer appeared to have any residual surface polarity. Removal from nocodazole at all time points from 1 to 10 h resulted in most cells completing mitosis to yield pairs of cells which, in most cases, resembled pairs derived from nonarrested blastomeres and in which a defined polar area of microvilli was restored. However, the percentage of differentiative divisions decreased after 6 h arrest. If, instead of removing cells from nocodazole, they were placed in both nocodazole and cytochalasin D (CCD) for periods of up to 3 h, most microvilli retracted to reveal a tight polar zone of CCD-resistant microvilli. This result suggests that a heterogeneity of cytocortical organization may still exist within the arrested mitotic cell. We propose a model to explain the origin of this heterogeneity of organization and its relationship to the generation of cell diversity.     

Central roles of small GTPases in the development of cell polarity in yeast and beyond.

Summary: The establishment of cell polarity is critical for the development of many organisms and for the function of many cell types. A large number of studies of diverse organisms from yeast to humans indicate that the conserved, small-molecular-weight GTPases function as key signaling proteins involved in cell polarization. The budding yeast Saccharomyces cerevisiae is a particularly attractive model because it displays pronounced cell polarity in response to intracellular and extracellular cues. Cells of S. cerevisiae undergo polarized growth during various phases of their life cycle, such as during vegetative growth, mating between haploid cells of opposite mating types, and filamentous growth upon deprivation of nutrition such as nitrogen. Substantial progress has been made in deciphering the molecular basis of cell polarity in budding yeast. In particular, it becomes increasingly clear how small GTPases regulate polarized cytoskeletal organization, cell wall assembly, and exocytosis at the molecular level and how these GTPases are regulated. In this review, we discuss the key signaling pathways that regulate cell polarization during the mitotic cell cycle and during mating.