Light and stomatal function: blue light stimulates swelling of guard cell protoplasts

Onion guard cell protoplasts swell when illuminated with blue light. The response is a 35 to 60 percent increase in volume and is dependent on potassium ion. Epidermal cell protoplasts do not swell under the same conditions. It is postulated that a membrane-bound blue photoreceptor mediates a direct response of guard cells to light.

Nuclear localization of profilin during the cell cycle in Tradescantia virginiana stamen hair cells

The localization of the actin-monomer-binding protein profilin during the cell cycle of living Tradescantia virginiana stamen hair cells has been studied by microinjection of a fluorescently labeled analog of the protein. In contrast to previously published studies performed on chemically fixed animal cells, we do not find a specific colocalization of profilin with actin filament arrays. Our results show that, besides a general cytoplasmic distribution, profilin specifically accumulates in the nucleus in interphase and prophase cells. This nuclear localization was confirmed by means of electron microscopic immunolocalization of endogenous profilin (in Gibasis scheldiana stamen hair cells). During mitosis, as the nuclear envelope and nuclear matrix break down at the onset of prometaphase, the nuclear profilin redistributes equally into the accessible volume (cytosol) of the cell. During metaphase and anaphase no specific localization of profilin can be observed associated with the mitotic apparatus. However, during telophase, as nuclear envelopes and nuclear matrices re-form and the sister chromatids start to decondense, a subset of the microinjected profilin again localizes to the nucleus. No accumulation of profilin could be observed in the phragmoplast, where a distinct array of actin filaments exists. The function of profilin in the nucleus remains unclear.

Polarized cell growth in higher plants

Pollen tubes and root hairs are highly elongated, cylindrically shaped cells whose polarized growth permits them to explore the environment for the benefit of the entire plant. Root hairs create an enormous surface area for the uptake of water and nutrients, whereas pollen tubes deliver the sperm cells to the ovule for fertilization. These cells grow exclusively at the apex and at prodigious rates (in excess of 200 nm/s for pollen tubes). Underlying this rapid growth are polarized ion gradients and fluxes, turnover of cytoskeletal elements (actin microfilaments), and exocytosis and endocytosis of membrane vesicles. Intracellular gradients of calcium and protons are spatially localized at the growing apex; inward fluxes of these ions are apically directed. These gradients and fluxes oscillate with the same frequency as the oscillations in growth rate but not with the same phase. Actin microfilaments, which together with myosin generate reverse fountain streaming, undergo rapid turnover in the apical domain, possibly being regulated by key actin-binding proteins, e.g., profilin, villin, and ADF/cofilin, in concert with the ion gradients. Exocytosis of vesicles at the apex, also dependent on the ion gradients, provides precursor material for the continuously expanding cell wall of the growing cell. Elucidation of the interactions and of the dynamics of these different components is providing unique insight into the mechanisms of polarized growth.

Inositol 1,4,5 trisphosphate is inactivated by a 5-phosphatase in stamen hair cells of Tradescantia

Inositol 1,4,5 trisphosphate [Ins(1,4,5)P3] is produced from the hydrolysis of phosphatidylinositol 4,5 bisphosphate, and as part of a second-messenger signal transduction mechanism, induces release of Ca2+ from internal stores in both plant and animal systems. It is less well established how the active Ins(1,4,5)P3 is inactivated. Studies in animal cells have demonstrated two separate metabolic pathways. Ins(1,4,5)P3 can be hydrolyzed by a 5-phosphatase or phosphorylated by a 3-kinase, resulting in the formation of Ins(1,4)P2 and Ins(1,3,4,5)P4, respectively, neither of which is able to mobilize intracellular Ca2+. Plant cell extracts have been reported to have hydrolytic and kinase activities that produce Ins(1,4)P2, and Ins(4,5)P2 and Ins(1,4,5,6)P4 from Ins(1,4,5)P3. These results offer little insight into the enzyme activities in the intact plant cell since the observed activities might be confined to intracellular compartments that have little if any impact on the signaling events within the cytosol that require Ins(1,4,5)P3. To resolve the mechanism of Ins(1,4,5)P3 inactivation, we microinjected stamen hair cells of Tradescantia virginiana L. with nonhydrolysable analogs of Ins(1,4,5)P3 that have been previously shown to cause Ca2+ release from intracellular stores. Our results indicate a sustained cytosolic [Ca2+] increase when cells were injected with the 5-phosphatase-insensitive 5-monophosphorothioate derivative of Ins(1,4,5)P3, in contrast to a brief transient when injected with the 3-kinase-insensitive 3-fluoro-3-deoxy Ins(1,4,5)P3 analog. We conclude that the 5-phosphatase pathway is the preferred pathway for Ins(1,4,5)P3 inactivation in the stamen hair cells of Tradescantia.

Actin polymerization is essential for pollen tube growth

Actin microfilaments, which are prominent in pollen tubes, have been implicated in the growth process; however, their mechanism of action is not well understood. In the present work we have used profilin and DNAse I injections, as well as latrunculin B and cytochalasin D treatments, under quantitatively controlled conditions, to perturb actin microfilament structure and assembly in an attempt to answer this question. We found that a approximately 50% increase in the total profilin pool was necessary to half-maximally inhibit pollen tube growth, whereas a approximately 100% increase was necessary for half-maximal inhibition of cytoplasmic streaming. DNAse I showed a similar inhibitory activity but with a threefold more pronounced effect on growth than streaming. Latrunculin B, at only 1--4 nM in the growth medium, has a similar proportion of inhibition of growth over streaming to that of profilin. The fact that tip growth is more sensitive than streaming to the inhibitory substances and that there is no correlation between streaming and growth rates suggests that tip growth requires actin assembly in a process independent of cytoplasmic streaming.

Cellular oscillations and the regulation of growth: the pollen tube paradigm

The occurrence of oscillatory behaviours in living cells can be viewed as a visible consequence of stable, regulatory homeostatic cycles. Therefore, they may be used as experimental windows on the underlying physiological mechanisms. Recent studies show that growing pollen tubes are an excellent biological model for these purposes. They unite experimental simplicity with clear oscillatory patterns of both structural and temporal features, most being measurable during real-time in live cells. There is evidence that these cellular oscillators involve an integrated input of plasma membrane ion fluxes, and a cytosolic choreography of protons, calcium and, most likely, potassium and chloride. In turn, these can create positive feedback regulation loops that are able to generate and self-sustain a number of spatial and temporal patterns. Other features, including cell wall assembly and rheology, turgor, and the cytoskeleton, play important roles and are targets or modulators of ion dynamics. Many of these features have similarities with other cell types, notably with apical-growing cells. Pollen tubes may thus serve as a powerful model for exploring the basis of cell growth and morphogenesis. BioEssays 23:86-94, 2001.

Cellular oscillations and the regulation of growth: the pollen tube paradigm

The occurrence of oscillatory behaviours in living cells can be viewed as a visible consequence of stable, regulatory homeostatic cycles. Therefore, they may be used as experimental windows on the underlying physiological mechanisms. Recent studies show that growing pollen tubes are an excellent biological model for these purposes. They unite experimental simplicity with clear oscillatory patterns of both structural and temporal features, most being measurable during real-time in live cells. There is evidence that these cellular oscillators involve an integrated input of plasma membrane ion fluxes, and a cytosolic choreography of protons, calcium and, most likely, potassium and chloride. In turn, these can create positive feedback regulation loops that are able to generate and self-sustain a number of spatial and temporal patterns. Other features, including cell wall assembly and rheology, turgor, and the cytoskeleton, play important roles and are targets or modulators of ion dynamics. Many of these features have similarities with other cell types, notably with apical-growing cells. Pollen tubes may thus serve as a powerful model for exploring the basis of cell growth and morphogenesis. BioEssays 23:86-94, 2001.

Actin and pollen tube growth

Actin microfilaments (MFs) are essential for the growth of the pollen tube. Although it is well known that MFs, together with myosin, deliver the vesicles required for cell elongation, it is becoming evident that the polymerization of new actin MFs, in a process that is independent of actomyosin-dependent vesicle translocation, is also necessary for cell elongation. Herein we review the recent literature that focuses on this subject, including brief discussions of the actin-binding proteins in pollen, and their possible role in regulating actin MF activity. We promote the view that polymerization of new actin MFs polarizes the cytoplasm at the apex of the tube. This process is regulated in part by the apical calcium gradient and by different actin-binding proteins. For example, profilin binds actin monomers and gives the cell control over the initiation of polymerization. A more recently discovered actin-binding protein, villin, stimulates the formation of unipolar bundles of MFs. Villin may also respond to the apical calcium gradient, fragmenting MFs, and thus locally facilitating actin remodeling. While much remains to be discovered, it is nevertheless apparent that actin MFs play a fundamental role in controlling apical cell growth in pollen tubes.

Cellular oscillations and the regulation of growth: the pollen tube paradigm

The occurrence of oscillatory behaviours in living cells can be viewed as a visible consequence of stable, regulatory homeostatic cycles. Therefore, they may be used as experimental windows on the underlying physiological mechanisms. Recent studies show that growing pollen tubes are an excellent biological model for these purposes. They unite experimental simplicity with clear oscillatory patterns of both structural and temporal features, most being measurable during real-time in live cells. There is evidence that these cellular oscillators involve an integrated input of plasma membrane ion fluxes, and a cytosolic choreography of protons, calcium and, most likely, potassium and chloride. In turn, these can create positive feedback regulation loops that are able to generate and self-sustain a number of spatial and temporal patterns. Other features, including cell wall assembly and rheology, turgor, and the cytoskeleton, play important roles and are targets or modulators of ion dynamics. Many of these features have similarities with other cell types, notably with apical-growing cells. Pollen tubes may thus serve as a powerful model for exploring the basis of cell growth and morphogenesis. BioEssays 23:86-94, 2001.

Cellular oscillations and the regulation of growth: the pollen tube paradigm

The occurrence of oscillatory behaviours in living cells can be viewed as a visible consequence of stable, regulatory homeostatic cycles. Therefore, they may be used as experimental windows on the underlying physiological mechanisms. Recent studies show that growing pollen tubes are an excellent biological model for these purposes. They unite experimental simplicity with clear oscillatory patterns of both structural and temporal features, most being measurable during real-time in live cells. There is evidence that these cellular oscillators involve an integrated input of plasma membrane ion fluxes, and a cytosolic choreography of protons, calcium and, most likely, potassium and chloride. In turn, these can create positive feedback regulation loops that are able to generate and self-sustain a number of spatial and temporal patterns. Other features, including cell wall assembly and rheology, turgor, and the cytoskeleton, play important roles and are targets or modulators of ion dynamics. Many of these features have similarities with other cell types, notably with apical-growing cells. Pollen tubes may thus serve as a powerful model for exploring the basis of cell growth and morphogenesis. BioEssays 23:86-94, 2001.

Cytoplasmic acidification with butyric acid does not alter the ionic conductivity of plasmodesmata

The effect of lowering cytoplasmic pH on the ionic conductivity of higher-plant plasmodesmata was investigated with corn (Zea mays L. cv. Black Mexican Sweet) suspension culture cells. Exposure to butyric acid decreased the cytoplasmic pH by 0.8 units. Intercellular communication was monitored by electrophysiological techniques that allowed the measurement of membrane resistances of sister cells and the electrical resistance of the plasmodesmata connecting them. The decrease in cytoplasmic pH did not affect the resistance of plasmodesmata, despite the fact that the butyric acid treatment more than doubled the concentration of cytoplasmic calcium. This is discussed in light of previous findings that increases in cytoplasmic calcium increase the electrical resistance of plasmodesmata.

Characterization and localization of profilin in pollen grains and tubes of Lilium longiflorum

Pollen tubes show a rapid and dramatically polarized growth in which the actin cytoskeleton appears to play a central role. In order to understand the regulation of actin we characterized its associated protein, profilin, in pollen tubes of Lilium longiflorum. By using purified polyclonal antibodies prepared against bean root profilin [Vidali et al., 1995: Plant Physiol. 108:115-123] we detected in pollen grains and tubes two profilin polypeptides with molecular masses of 14.4 and 13.4 KDa, and an identical isoelectric point of 5.05. Profilin comprises approximately 0.47% of the total grain protein, with actin being approximately 1.4%. We were unable to detect a statistically significant profilin increase after germination, while the actin increased approximately 68%. We also spatially localized the distribution of profilin using immunocytochemistry of fixed cells at both the light and electron microscope level, and by fluorescent analog cytochemistry on live cells. The results show that profilin is evenly distributed throughout the cytoplasm and does not specifically associate with any cellular structure.

The kinesin-like calmodulin binding protein is differentially involved in cell division

The kinesin-like calmodulin (CaM) binding protein (KCBP), a minus end-directed microtubule motor protein unique to plants, has been implicated in cell division. KCBP is negatively regulated by Ca(2)+ and CaM, and antibodies raised against the CaM binding region inhibit CaM binding to KCBP in vitro; therefore, these antibodies can be used to activate KCBP constitutively. Injection of these antibodies into Tradescantia virginiana stamen hair cells during late prophase induces breakdown of the nuclear envelope within 2 to 10 min and leads the cell into prometaphase. However, mitosis is arrested, and the cell does not progress into anaphase. Injection of antibodies later during cell division has no effect on anaphase transition but causes aberrant phragmoplast formation and delays the completion of cytokinesis by approximately 15 min. These effects are achieved without any apparent degradation of the microtubule cytoskeleton. We propose that during nuclear envelope breakdown and anaphase, activated KCBP promotes the formation of a converging bipolar spindle by sliding and bundling microtubules. During metaphase and telophase, we suggest that its activity is downregulated.

Plant GTPases: the Rhos in bloom

In animal cells and in fungi, small GTP-binding proteins of the Rho family have well-established roles in morphogenesis, cell-cycle progression, gene transcription and the generation of superoxide anions. The presence of these proteins in plant cells, however, has been established only recently, and the role of Rho GTPases in plants is now coming into view. Already, it is apparent that there are both striking similarities and fascinating differences in how Rho GTPases are regulated and used in plant versus animal and fungal cells. These new findings define certain core properties that might be common to members of this protein family in all eukaryotes.

The role of plant villin in the organization of the actin cytoskeleton, cytoplasmic streaming and the architecture of the transvacuolar strand in root hair cells of Hydrocharis

In many types of plant cell, bundles of actin filaments (AFs) are generally involved in cytoplasmic streaming and the organization of transvacuolar strands. Actin cross-linking proteins are believed to arrange AFs into the bundles. In root hair cells of Hydrocharis dubia (Blume) Baker, a 135-kDa polypeptide cross-reacted with an antiserum against a 135-kDa actin-bundling protein (135-ABP), a villin homologue, isolated from lily pollen tubes. Immunofluorescence microscopy revealed that the 135-kDa polypeptide co-localized with AF bundles in the transvacuolar strand and in the sub-cortical region of the cells. Microinjection of antiserum against 135-ABP into living root hair cells induced the disappearance of the transvacuolar strand. Concomitantly, thick AF bundles in the transvacuolar strand dispersed into thin bundles. In the root hair cells, AFs showed uniform polarity in the bundles, which is consistent with the in-vitro activity of 135-ABP. These results suggest that villin is a factor responsible for bundling AFs in root hair cells as well as in pollen tubes, and that it plays a key role in determining the direction of cytoplasmic streaming in these cells.

Physiological elevations in cytoplasmic free calcium by cold or ion injection result in transient closure of higher plant plasmodesmata

The concentration of cytoplasmic free calcium ([Ca(2+)](cyt)) required to close higher plant plasmodesmata was investigated using corn (Zea mays L. cv. Black Mexican Sweet) suspension-culture cells. Physiological elevations of [Ca(2+)](cyt) were applied by cold treatment, and ion injection was also used to increase [Ca(2+)](cyt), by diffusion (for small increases) or by iontophoresis (for larger increases). The impact of such treatments on [Ca(2+)](cyt) was measured by ratiometric ion imaging. Intercellular communication during treatments was monitored using our recently developed electrophysiological technique that allows the electrical resistance of plasmodesmata and the plasma membranes of a sister-cell pair to be measured. A 4-fold increase in the calculated resistance of single plasmodesmata was observed in response to cold treatment that caused a 2-fold increase in average [Ca(2+)](cyt) (from 107 to 210 nM). In response to iontophoresis of Ca(2+), plasmodesmata were observed to go from "open" (low resistance) to "shut" (high resistance) and then back "open" within 10 s. Our results thus indicate that higher plant plasmodesmata respond quickly to physiological changes in [Ca(2+)](cyt).

Rhizobium nod factors induce increases in intracellular free calcium and extracellular calcium influxes in bean root hairs

Application of Nod factors to growing, responsive root hairs of the bean Phaseolus vulgaris induces marked changes in both the intracellular cytosolic free calcium (Ca2+) and in the influx of extracellular [Ca2+]. The intracellular [Ca2+], which has been measured by ratiometric imaging in cells microinjected with fura-2-dextran (70 kDa), elevates within 5 min from approximately 400 nM to 1500 nM in localised zones in the root hair apex. Of particular note is the observation that the elevated regions of [Ca2+] appear to shift position during short time intervals. Increases in and fluctuations of the intracellular [Ca2+] are also observed in the perinuclear region after 10-15 min treatment with Nod factors. The extracellular Ca2+ flux, detected with the non-invasive, calcium specific vibrating electrode, is inwardly directed and also increases quickly in response to Nod factors from 13 pmol cm-2 s-1 to 28 pmol cm-2 s-1. Chitin-oligomers, which are structurally similar but biologically inactive when compared to the active Nod factors, fail to elicit changes in either intracellular or extracellular Ca2+. The similar timing and location of the intracellular elevations and the increased extracellular influx provide support for the idea that Ca2+ participates in secretion and cell wall remodelling, which occur in anticipation of root hair deformation and curling.

Uncoupling secretion and tip growth in lily pollen tubes: evidence for the role of calcium in exocytosis

Cytoplasmic calcium concentration ([Ca2+]i) and extracellular calcium (Ca2+o) influx has been studied in pollen tubes of Lilium longliflorum in which the processes of cell elongation and exocytosis have been uncoupled by use of Yariv phenylglycoside ((beta-D-Glc)3). Growing pollen tubes were pressure injected with the ratio dye fura-2 dextran and imaged after application of (beta-D-Glc)3, which binds arabinogalactan proteins (AGPs). Application of (beta-D-Glc)3 inhibited growth but not secretion. Ratiometric imaging of [Ca2+]i revealed an initial spread in the locus of the apical [Ca2+]i gradient and substantial elevations in basal [Ca2+]i followed by the establishment of new regions of elevated [Ca2+]i on the flanks of the tip region. Areas of elevated [Ca2+]i corresponded to sites of pronounced exocytosis, as evidenced by the formation of wall ingrowths adjacent to the plasma membrane. Ca2+o influx at the tip of (beta-D-Glc)3-treated pollen tubes was not significantly different to that of control tubes. Taken together these data indicate that regions of elevated [Ca2+]i, probably resulting from Ca2+o influx across the plasma membrane, stimulate exocytosis in pollen tubes independent of cell elongation.

Growing pollen tubes possess a constitutive alkaline band in the clear zone and a growth-dependent acidic tip

Using both the proton selective vibrating electrode to probe the extracellular currents and ratiometric wide-field fluorescence microscopy with the indicator 2', 7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF)-dextran to image the intracellular pH, we have examined the distribution and activity of protons (H+) associated with pollen tube growth. The intracellular images reveal that lily pollen tubes possess a constitutive alkaline band at the base of the clear zone and an acidic domain at the extreme apex. The extracellular observations, in close agreement, show a proton influx at the extreme apex of the pollen tube and an efflux in the region that corresponds to the position of the alkaline band. The ability to detect the intracellular pH gradient is strongly dependent on the concentration of exogenous buffers in the cytoplasm. Thus, even the indicator dye, if introduced at levels estimated to be of 1.0 microM or greater, will dissipate the gradient, possibly through shuttle buffering. The apical acidic domain correlates closely with the process of growth, and thus may play a direct role, possibly in facilitating vesicle movement and exocytosis. The alkaline band correlates with the position of the reverse fountain streaming at the base of the clear zone, and may participate in the regulation of actin filament formation through the modulation of pH-sensitive actin binding proteins. These studies not only demonstrate that proton gradients exist, but that they may be intimately associated with polarized pollen tube growth.

Three-dimensional organization and dynamic changes of the actin cytoskeleton in embryo sacs of Zea mays and Torenia fournieri

Actin organization was observed in m-maleimidobenzoic acid N-hydroxysuccinimide ester(MBS)-treated maize embryo sacs by confocal laser scanning microscopy. The results revealed that dynamic changes of actin occur not only in the degenerating synergid, but also in the egg during fertilization. The actin filaments distribute randomly in the chalazal part of the synergid before fertilization; they later become organized into numerous aggregates in the chalazal end after pollination. The accumulation of actin at this region is intensified after the pollen tube discharges its contents. Concurrently, actin patches have also been found in the cytoplasm of the egg cell and later they accumulate in the cortical region. To compare with MBS-treated maize embryo sacs, we have performed phalloidin microinjection to label the actin cytoskeleton in living embryo sacs of Torenia fournieri. The results have extended the previous observations on the three-dimensional organization of the actin arrays in the cells of the female germ unit and confirm the occurrence of the actin coronas in the embryo sac during fertilization. We have found that there is an actin cap occurring near the filiform apparatus after anthesis. In addition, phalloidin microinjection into the Torenia embryo sac has proved the presence of intercellular actin between the cells of the female germ unit and thus confirms the occurrence of the actin coronas in the embryo sac during fertilization. Moreover, actin dynamic changes also take place in the egg and the central cell, accomplished with the interaction between the male and female gametes. The actin filaments initially organize into a distinct actin network in the cortex of the central cell after anthesis; they become fragmented in the micropylar end of the cell after pollination. Similar to maize, actin patches have also been observed in the egg cortex after pollination. This is the first report of actin dynamics in the living embryo sac. The results suggest that the actin cytoskeleton may play an essential role in the reception of the pollen tube, migration of the male gametes, and even gametic fusion.

Effects of Yariv phenylglycoside on cell wall assembly in the lily pollen tube

Arabinogalactan-proteins (AGPs) are proteoglycans with a high level of galactose and arabinose. Their current functions in plant development remain speculative. In this study, (beta-D-glucosyl)3 Yariv phenyl-glycoside [(beta-D-Glc)3] was used to perturb AGPs at the plasmalemma-cell wall interface in order to understand their functional significance in cell wall assembly during pollen tube growth. Lily (Lilium longiflorum Thunb.) pollen tubes, in which AGPs are deposited at the tip, were used as a model. Yariv phenylglycoside destabilizes the normal intercalation of new cell wall subunits, while exocytosis of the secretory vesicles still occurs. The accumulated components at the tip are segregated between fibrillar areas of homogalacturonans and translucent domains containing callose and AGPs. We propose that the formation of AGP/(beta-D-Glc)3 complexes is responsible for the lack of proper cell wall assembly. Pectin accumulation and callose synthesis at the tip may also change the molecular architecture of the cell wall and explain the lack of proper cell wall assembly. The data confirm the importance of AGPs in pollen tube growth and emphasize their role in the deposition of cell wall subunits within the previously synthesized cell wall.

Pollen Tube Growth and the Intracellular Cytosolic Calcium Gradient Oscillate in Phase while Extracellular Calcium Influx Is Delayed

Ratio images of cytosolic Ca2+ (Ca2+i) in growing, fura-2-dextran-loaded Lilium longiflorum pollen tubes taken at 3- to 5-sec intervals showed that the tip-focused [Ca2+]i gradient oscillates with the same period as growth. Similarly, measurement of the extracellular inward current, using a noninvasive ion-selective vibrating probe, indicated that the tip-directed extracellular Ca2+ (Ca2+o) current also oscillates with the same period as growth. Cross-correlation analysis revealed that whereas the [Ca2+]i gradient oscillates in phase with growth, the influx of Ca2+o lags by ~11 sec. Ion influx thus appears to follow growth, with the effect that the rate of growth at a given point determines the magnitude of the ion influx ~11 sec later. To explain the phase delay in the extracellular inward current, there must be a storage of Ca2+ for which we consider two possibilities: either the inward current represents the refilling of intracellular stores (capacitative calcium entry), or it represents the binding of the ion within the cell wall domain.

Probing the Plant Actin Cytoskeleton during Cytokinesis and Interphase by Profilin Microinjection

We have examined the cytological effects of microinjecting recombinant birch profilin in dividing and interphase stamen hair cells of Tradescantia virginiana. Microinjection of profilin at anaphase and telophase led to a marked effect on cytokinesis; cell plate formation was often delayed, blocked, or completely inhibited. In addition, the initial appearance of the cell plate was wrinkled, thin, and sometimes fragmented. Injection of profilin at interphase caused a thinning or the collapse of cytoplasmic strands and a retardation or inhibition of cytoplasmic streaming in a dose-dependent manner. Confocal laser scanning microscopy of rhodamine-phalloidin staining in vivo revealed that high levels of microinjected profilin induced a degradation of the actin cytoskeleton in the phragmoplast, the perinuclear zone, and the cytoplasmic strands. However, some cortical actin filaments remained intact. The data demonstrate that profilin has the ability to act as a regulator of actin-dependent events and that centrally located actin filaments are more sensitive to microinjected profilin than are cortical actin filaments. These results add new evidence supporting the hypothesis that actin filaments play a crucial role in the formation of the cell plate and provide mechanical support for the cytoplasmic strands in interphase cells.

Increases in Cytosolic Ca2+ in Parsley Mesophyll Cells Correlate with Leaf Senescence

The ability to maintain the cytoplasmic Ca2+ concentration ([Ca2+]cyt) at homeostatic levels has been examined during leaf senescence in detached parsley (Petroselinum crispum) leaves. Fluorescence ratiometric imaging of mesophyll cells isolated from parsley leaves at various senescence stages and loaded with the Ca2+ indicator fura-2 has revealed a distinct elevation of [Ca2+]cyt, which was positively correlated with the progress of leaf senescence. This initial increase of [Ca2+]cyt, which was first observed in cells isolated from 3-d-senescent leaves, occurred 1 d before or in parallel with changes in two established senescence parameters, chlorophyll loss and lipid peroxidation. However, the [Ca2+]cyt elevation followed by 2 d the initial increase in the senescence-associated proteolysis. Whereas the [Ca2+]cyt of nonsenescent cells remained at the basal level, the elevated [Ca2+]cyt of the senescent cells was a long-lasting effect. Experimental retardation of senescence processes, achieved by pretreatment of detached leaves with the cytokinin benzyladenine, resulted in maintenance of homeostatic levels of [Ca2+]cyt in cells isolated from 3-d-senescent leaves. These observations demonstrate for the first time to our knowledge a correlation between elevated [Ca2+]cyt and the process of senescence in parsley leaves. Such senescence-associated elevation of [Ca2+]cyt, which presumably results from a loss of the cell's capability to extrude Ca2+, may serve as a signal inducing subsequent deteriorative processes.

The Cytosolic Ca2+ Concentration Gradient of Sinapis alba Root Hairs as Revealed by Ca2+-Selective Microelectrode Tests and Fura-Dextran Ratio Imaging

Using Ca2+-selective microelectrodes and fura 2-dextran ratio imaging, the cytosolic free [Ca2+] was measured in Sinapis alba root hair cells. Both methods yielded comparable results, i.e. values between 158 to 251 nM for the basal [Ca2+] of the cells and an elevated [Ca2+] of 446 to 707 nM in the tip region. The zone of elevated [Ca2+] reaches 40 to 60 [mu]m into the cell and is congruent with the region of inwardly directed Ca2+ net currents measured with an external Ca2+- selective vibrating electrode. The channel-blocker La3+ eliminates these currents, stops growth, and almost completely eliminates the cytosolic [Ca2+] gradient without affecting the basal level of the ion. Growth is also inhibited by pressure-injected dibromo-1,2-bis(o-aminophenoxy)ethane-N,N,N[prime],N[prime]-tetraacetic acid, which causes a decrease in the [Ca2+] in the tip in a concentration-dependent manner. Indole-3-acetic acid, used as a model stimulus, decreases cytosolic free [Ca2+] by 0.2 to 0.3 pCa units in the tip, but only by about 0.1 pCa unit in the shank. Nongrowing root hairs may or may not display a [Ca2+] gradient, but still reversibly respond to external stimuli such as La3+, Ca2+, or indole-3-acetic acid with changes in cytosolic free [Ca2+]. During short time periods, dicyclohexylcarbodiimide inhibition of the plasma membrane H+-ATPase, which stops growth, does not abolish the [Ca2+] gradient, nor does it change significantly the basal [Ca2+] level. We conclude that the cytosolic [Ca2+] gradient and an elevated [Ca2+] in the tip, as in other tip-growing cells, is essential for tip growth in root hairs; however, its presence does not indicate growth under all circumstances. We argue that with respect to Ca2+, tip growth regulation and responses to external signals may not interfere with each other. Finally, we suggest that the combination of the methods applied adds considerably to our understanding of the role of cytosolic free [Ca2+] in signal transduction and cellular growth.

Characterization and localization of profilin in pollen grains and tubes of Lilium longiflorum

Pollen tubes show a rapid and dramatically polarized growth in which the actin cytoskeleton appears to play a central role. In order to understand the regulation of actin we characterized its associated protein, profilin, in pollen tubes of Lilium longiflorum. By using purified polyclonal antibodies prepared against bean root profilin [Vidali et al., 1995: Plant Physiol. 108:115-123] we detected in pollen grains and tubes two profilin polypeptides with molecular masses of 14.4 and 13.4 KDa, and an identical isoelectric point of 5.05. Profilin comprises approximately 0.47% of the total grain protein, with actin being approximately 1.4%. We were unable to detect a statistically significant profilin increase after germination, while the actin increased approximately 68%. We also spatially localized the distribution of profilin using immunocytochemistry of fixed cells at both the light and electron microscope level, and by fluorescent analog cytochemistry on live cells. The results show that profilin is evenly distributed throughout the cytoplasm and does not specifically associate with any cellular structure.

Cryofixing single cells and multicellular specimens enhances structure and immunocytochemistry for light microscopy

Cryofixation is widely held to be superior to chemical fixation for preserving cell structure; however, the use of cryofixation has been limited chiefly to electron microscopy. To see if cryofixation would improve sample structure or antigenicity as observed through the light microscope, we cryofixed Nicotiana alata and Lilium longiflorum pollen tubes and Tradescantia virginina stamen hairs by plunge freezing. After freeze-substitution, and embedding in butylmethylmethacrylate, we found using the light microscope that the superiority of cryofixation over chemical fixation was obvious. Cryofixation, unlike chemical fixation, did not distort cell morphology and preserved microtubule and actin arrays in a form closely resembling that of living cells. Additionally, to test further the usefulness of cryofixation for light microscopy, we studied the appearance of cells and the retention of antigenicity in plunge-frozen multicellular organ. Roots of Arabidopsis thaliana were either chemically fixed or plunge frozen, and then embedded in the removable methacrylate resin used above. We found that plunge freezing preserved cell morphology far better than did chemical fixation, and likewise improved the appearance of both actin and microtubule arrays. Plunge-frozen roots also had cells with more life-like cytoplasm than those of chemically fixed roots, as assessed with toluidine-blue staining or high-resolution Nomarski optics. Damage from ice crystal formation could not be resolved through the light microscope, even in the interior of the root, 40-75 microns from the surface. We suggest that plunge freezing would enhance many investigations at the light microscope level, including those of multicellular organs, where damage from ice crystals may be less severe than artefacts from chemical fixation.

Plant mitosis promoting factor disassembles the microtubule preprophase band and accelerates prophase progression in Tradescantia

The regulation of mitosis in higher plant cells has been investigated by microinjecting protein kinase from the metaphase-arresting (met1) mutant of Chlamydomonas. Biochemical characterization of this enzyme complex confirms the presence of a p34cdc2/cyclin B-like kinase. The enzyme was injected into living stamen hair cells of Tradescantia virginiana in which microtubules (MTs) were visualized using fluorescent analogue cytochemistry and confocal laser scanning microscopy. Microinjection of this p34cdc2/cyclin B-like kinase caused rapid disassembly of the preprophase band of MTs but not of interphase-cortical, spindle or phragmoplast MTs. Effects of the enzyme on the cytomorphology of live prophase cells were also monitored using video microscopy. We found that injection of this enzyme accelerated chromatin condensation and nuclear envelope breakdown. This indicates the presence and function in plants of an enzyme that can initiate nuclear division similar to the maturation or mitosis promoting factor (MPF) of animal cells. These studies provide the first direct evidence that the mitotically-active form of plant MPF can drive disassembly of preprophase band MTs, chromosome condensation and initiation of mitosis in plant cells.

Tip-localized calcium entry fluctuates during pollen tube growth

Studies have been conducted on the dynamics of Ca2+ entry in pollen tubes using ratiometric ion imaging to measure the intracellular gradient and an ion selective vibrating electrode to detect the extracellular influx. A steep tip-focused gradient occurs in all species examined, including Lilium longiflorum, Nicotiana sylvestris, and Tradescantia virginiana. Anlaysis of Lilium pollen tubes loaded with dextran conjugated fura-2 reveals that the gradient derives from Ca2+ entry that is restricted to a small area of plasma membrane at the extreme apex of the tube dome. Since the apical membrane is continually swept to the flanks during tube elongation, either Ca2+ channels are specifically retained at the extreme apex or, as seems more likely, the Ca2+ channels which were active at the tip rapidly inactivate, as new ones are inserted during vesicle fusion. Ratiometric imaging further indicates that the high point of the gradient fluctuates in magnitude from 0.75 to above 3 microM, during measuring intervals of 60 sec, with the elevated points being correlated with an increased rate of tube growth. Independent analysis of the growth at 2- to 3-sec intervals reveals that the rates can fluctuate more than threefold; tubes longer than 700 mu m exhibit oscillations with a period of 23 sec, while tubes shorter than 700 mu m display erratic fluctuations. Inhibition of pollen tube growth caused by mild temperature shock or caffeine (1.5 to 3.0 mM) is correlated with the dissipation of the tip-focused gradient and the Ca2+ influx. Recovery from both treatments is denoted by a global swelling of the pollen tube tip, concomitant with a high transient entry of Ca2+ in the tip. The location of the highest Ca2+ domain within the tip region defines the point from which normal cylindrical elongation will proceed.

Actin Filaments in Mature Guard Cells Are Radially Distributed and Involved in Stomatal Movement

Stomatal movements, which regulate gas exchange in plants, involve pronounced changes in the shape and volume of the guard cell. To test whether the changes are regulated by actin filaments, we visualized microfilaments in mature guard cells and examined the effects of actin antagonists on stomatal movements. Immunolocalization on fixed cells and microinjection of fluorescein isothiocyanate-phalloidin into living guard cells of Commelina communis L. showed that cortical microfilaments were radially distributed, fanning out from the stomatal pore site, resembling the known pattern of microtubules. Treatment of epidermal peels with phalloidin prior to stabilizing microfilaments with m-maleimidobenzoyl N-hydroxysuccimimide caused dense packing of radial microfilaments and an accumulation of actin around many organelles. Both stomatal closing induced by abscisic acid and opening under light were inhibited. Treatment of guard cells with cytochalasin D abolished the radial pattern of microfilaments; generated sparse, poorly oriented arrays; and caused partial opening of dark-closed stomata. These results suggest that microfilaments participate in stomatal aperture regulation.

Free calcium in Micrasterias: local gradients are not detected in growing lobes

Intracellular free Ca2+ ([Ca2+]) has been measured in growing unicells of two species of the green alga, Micrasterias, which have been injected with the indicator dye fura-2-dextran. Ratiometric imaging of Micrasterias denticulata yields levels of 170 to 200 nM [Ca2+] but fails to reveal a significant [Ca2+] gradient associated with the tips of growing lobes, or in any other region of the cell. In Micrasterias muricata slight elevations from a basal value of 350 to 500 nM have been observed, but these might be due to a general inward leakage of Ca2+ at the plasma membrane which is enhanced at the narrow lobes of this cell because of their greater relative surface to volume ratio. Experimental perturbation of the intracellular [Ca2+] with injection of the ion or the addition of the non-fluorescent ionophore, Br-A23187, reveal that [Ca2+] elevations can be generated and indicate that if they naturally occurred, the image system would have detected them. Further evidence that [Ca2+] gradients are lacking derives from studies with BAPTA-type buffers. Injection of 5,5'-dibromo BAPTA and 4,4'-difluoro BAPTA, which in several other systems are the most effective at dissipating intracellular [Ca2+] gradients, have no effect on development of Micrasterias. Taken together, these studies indicate that lobe outgrowth in Micrasterias does not occur in association with marked localized [Ca2+] gradients.

Identification and localization of three classes of myosins in pollen tubes of Lilium longiflorum and Nicotiana alata

The presence and localization of actin and myosin have been examined in pollen tubes of Lilium longiflorum and Nicotiana alata. Immunoblot analysis of pollen tube extracts with antibodies to actin, myosins IA and IB, myosin II, and myosin V reveals the presence of these contractile proteins. Immunofluorescence microscopy using various methods to preserve the pollen tubes; chemical fixation, rapid freeze fixation and freeze substitution (RF-FS) followed by rehydration or by embeddment in a methacrylate mixture, was performed to optimize preservation. Immunocytochemistry reaffirmed that actin is localized longitudinally in the active streaming lanes and near the cortical surface of the pollen tube. Myosin I was localized to the plasma membrane, larger organelles, the surface of the generative cell and the vegetative nucleus, whereas, myosin V was found in the vegetative cytoplasm in a punctate fashion representing smaller organelles. Myosin II subfragment 1 and light meromyosin were localized in a punctate fashion on the larger organelles throughout the vegetative cytoplasm. In addition, isolated generative cells and vegetative nuclei labeled only with the myosin I antibody. Competition studies indicated the specificity of the heterologous antibodies utilized in this study suggesting the presence of three classes of myosins in pollen. These results lead to the following hypothesis: Myosin I may move the generative cell and vegetative nucleus unidirectionally through the pollen tube to the tip, while myosin V moves the smaller organelles and myosins I and II move the larger organelles (bidirectionally) that are involved in growth.

Pollen tube growth is coupled to the extracellular calcium ion flux and the intracellular calcium gradient: effect of BAPTA-type buffers and hypertonic media

Lily pollen tubes possess a steep, tip-focused intracellular Ca2+ gradient and a tip-directed extracellular Ca2+ influx. Ratiometric ion imaging revealed that the gradient extends from above 3.0 microM at the apex to approximately 0.2 microM within 20 microns from the tip, while application of the Ca(2+)-specific vibrating electrode indicated that the extracellular influx measured between 1.4 and 14 pmol cm-2 sec-1. We examined the relationship between these phenomena and their role in tube growth by using different 1,2-bis(o-aminophenoxy)ethane N,N,N',N'-tetraacetic acid (BAPTA)-type buffers and hypertonic media. Injection of active BAPTA-type buffers or application of elevated levels of sucrose reversibly inhibited growth, destroyed tip zonation of organelles, and modified normal patterns of cytoplasmic streaming. Simultaneously, these treatments dissipated both the intracellular tip-focused gradient and the extracellular Ca2+ flux. Of the BAPTA-type buffers, 5,5'-dibromo-BAPTA (dissociation constant [Kd] is 1.5 microM) and 4,4'-difluoro-BAPTA (Kd of 1.7 microM) exhibited greater activity than those buffers with either a higher affinity (5,5'-dimethyl-BAPTA, Kd of 0.15 microM; BAPTA, Kd of 0.21 microM; 5,5'-difluoro-BAPTA, Kd of 0.25 microM) or lower affinity (5-methyl, 5'-nitro-BAPTA, Kd of 22 microM) for Ca2+. Our findings provide evidence that growing pollen tubes have open Ca2+ channels in their tip and that these channels become inactivated in nongrowing tubes. The studies with elevated sucrose support the view that stretching of the apical plasma membrane contributes to the maintenance of the Ca2+ signal.

Pollen tube growth is coupled to the extracellular calcium ion flux and the intracellular calcium gradient: effect of BAPTA-type buffers and hypertonic media

Lily pollen tubes possess a steep, tip-focused intracellular Ca2+ gradient and a tip-directed extracellular Ca2+ influx. Ratiometric ion imaging revealed that the gradient extends from above 3.0 microM at the apex to approximately 0.2 microM within 20 microns from the tip, while application of the Ca(2+)-specific vibrating electrode indicated that the extracellular influx measured between 1.4 and 14 pmol cm-2 sec-1. We examined the relationship between these phenomena and their role in tube growth by using different 1,2-bis(o-aminophenoxy)ethane N,N,N',N'-tetraacetic acid (BAPTA)-type buffers and hypertonic media. Injection of active BAPTA-type buffers or application of elevated levels of sucrose reversibly inhibited growth, destroyed tip zonation of organelles, and modified normal patterns of cytoplasmic streaming. Simultaneously, these treatments dissipated both the intracellular tip-focused gradient and the extracellular Ca2+ flux. Of the BAPTA-type buffers, 5,5'-dibromo-BAPTA (dissociation constant [Kd] is 1.5 microM) and 4,4'-difluoro-BAPTA (Kd of 1.7 microM) exhibited greater activity than those buffers with either a higher affinity (5,5'-dimethyl-BAPTA, Kd of 0.15 microM; BAPTA, Kd of 0.21 microM; 5,5'-difluoro-BAPTA, Kd of 0.25 microM) or lower affinity (5-methyl, 5'-nitro-BAPTA, Kd of 22 microM) for Ca2+. Our findings provide evidence that growing pollen tubes have open Ca2+ channels in their tip and that these channels become inactivated in nongrowing tubes. The studies with elevated sucrose support the view that stretching of the apical plasma membrane contributes to the maintenance of the Ca2+ signal.

The role of calcium in cell division

Calcium ions (Ca2+) appear to participate in the regulation of several aspects of cell division. Evidence is accumulating that transients or local gradients in the [Ca2+] contribute to different events including nuclear envelope breakdown and reformation, cleavage furrow formation and growth, and cell plate formation. At present there is little direct evidence that Ca2+ transients trigger the onset of anaphase. However, studies with exogenously applied Ca2+ indicate that spindle fibers and the movement of chromosomes at anaphase are exquisitely sensitive to the ion at physiological levels. Although Ca2+ is involved with many processes there are many gaps in our understanding, particularly pertaining to exactly when and where the ion concentration changes are expressed, which events and macromolecules are targeted, and what the processes are that control Ca2+.

Actin microfilaments are associated with the migrating nucleus and the cell cortex in the green alga Micrasterias. Studies on living cells

Rhodamine-phalloidin or FITC-phalloidin has been injected in small amounts into living, developing cells of Micrasterias denticulata and the stained microfilaments visualized by confocal laser scanning microscopy. The results reveal that two different actin filament systems are present in a growing cell: a cortical actin network that covers the inner surface of the cell and is extended far into the tips of the lobes in both the growing and the nongrowing semicell; it is also associated with the surface of the chloroplast. The second actin system ensheathes the nucleus at the isthmus-facing side during nuclear migration. Its arrangement corresponds to that of the microtubule system that has been described in earlier electron microscopic investigations. The spatial correspondence between the distribution of actin filaments and microtubules suggests a cooperation between both cytoskeleton elements in generating the motive force for nuclear migration. The function of the cortical actin network is not yet clear. It may be involved in processes like transport and fusion of secretory vesicles and may also function in shaping and anchoring the chloroplast.

Quantification of microtubule dynamics in living plant cells using fluorescence redistribution after photobleaching

Microtubule (MT) turnover within the four principal MT arrays, the cortical array, the preprophase band, the mitotic spindle and the phragmoplast, has been measured in living stamen hair cells of Tradescantia that have been injected with fluorescent neurotubulin. Using the combined techniques of confocal laser scanning microscopy and fluorescence redistribution after photobleaching (FRAP), we report that the half-time of turnover in spindle MTs is t 1/2 = 31 +/- 6 seconds, which is in excellent agreement with previous measurements of turnover in animal cell spindles. Tradescantia interphase MTs, however, exhibit turnover rates (t 1/2 = 67 +/- seconds) that are some 3.4-fold faster than those measured in interphase mammalian cells, and thus are revealed as being highly dynamic. Preprophase band and phragmoplast MTs have turnover rates similar to those of interphase MTs in Tradescantia. The spatial and temporal aspects of the fluorescence redistribution after photobleaching in all four MT arrays are more consistent with subunit exchange by the mechanism of dynamic instability than treadmilling. This is the first quantification of MT dynamics in plant cells.

Nuclear concentration and mitotic dispersion of the essential cell cycle protein, p13suc1, examined in living cells

Stamen hair cells of Tradescantia virginiana have been microinjected with p13suc1 labeled with carboxyfluorescein (CF) and studied throughout the division cycle in living cells by using the confocal laser scanning microscope. The protein, p13suc1, is essential for the rapid inactivation of the key mitotic catalyst, p34cdc2 kinase, at anaphase and for completion of nuclear division. During interphase or prophase, CF-p13suc1 concentrates quickly (< 2 min) in nuclei, reaching levels that are approximately 2-fold greater than those in the cytoplasm. At nuclear envelope breakdown, CF-p13suc1 permeates throughout the entire spindle and nonspindle cytoplasm. The protein is excluded from the tightly condensed chromosomes but otherwise no regions accumulate or exclude the protein. It remains evenly distributed throughout metaphase, anaphase, and well into cytokinesis; however, during telophase CF-p13suc1 reconcentrates in the daughter nuclei.

Independent modes of propagation of calcium waves in smooth muscle cells

The purinergic agonist adenosine triphosphate (ATP) stimulates an initial transient followed by subsequent oscillations in cytosolic calcium ion concentration ([Ca2+]i) in individual porcine aortic smooth muscle cells. Using microinjection of fura-2 covalently coupled to dextran, we have analyzed in detail the spatial and temporal features of the oscillations. We have observed both cytoplasmic calcium waves and gradients within single cells. Single cells can contain multiple loci of initiation of oscillations. Independent oscillations in a single cell can have independent frequencies and these oscillations can propagate without interference across the same region of the cell, suggesting that they arise either from separately regulated stores of Ca2+ or a single Ca2+ store operated by two separate release mechanisms. The shape of the wave front and the manner of the waye's decay can vary from one oscillation to the next. Ca2+ signaling in individual arterial smooth muscle cells thus displays complex spatial and temporal organization.

Inhibitors of cell division and protoplasmic streaming fail to cause a detectable effect on intracellular calcium levels in stamen-hair cells of Tradescantia virginiana L

The herbicides amiprophos-methyl (APM) and oryzalin disrupt mitosis and cytokinesis in plant cells by causing the depolymerization of microtubules. These drugs have also been shown to affect calcium sequestration by mitochondria. Controversy thus exists as to whether microtubule depolymerization occurs as a result of direct interaction between the drug and tubulin, or because of elevated intracellular calcium levels resulting from drug interference with calcium regulation. In order to clarify this issue we have directly measured the effect of these herbicides and other cell-motility-altering drugs on intracellular calcium levels in stamen-hair cells of Tradescantia. The results indicate that low levels (1-3 μM) of APM and oryzalin can act within 3-7 min causing disorganization of mitosis. Studies using the calcium indicator indo-1 injected into stamen-hair cells to monitor internal levels of calcium, show that at drug concentrations where inhibitory effects on mitosis and-or cytokinesis are clearly seen, APM, oryzalin, isopropyl-N-phenyl carbamate, caffeine and cytochalasin D produce no change in intracellular calcium levels. Furthermore, except for cytochalasin D, these drugs do not inhibit cytoplasmic streaming, a calcium-sensitive process. We conclude that the mode of action of these drugs on the cytoskeleton is independent of an effect on intracellular calcium.

Freeze substitution reveals a new model for sporangial cleavage in Phytophthora, a result with implications for cytokinesis in other eukaryotes

Rapid freezing and freeze substitution (RF-FS) have been used to re-examine the process by which the multinucleate sporangium of the Oomycetes, Phytophthora cinnamomi and P. palmivora, is subdivided into uninucleate zoospores. The results indicate a new model for sporangial cleavage in Phytophthora and suggest that the currently accepted model is based on interpretation of artefacts caused by chemical fixation. The previous model describes cleavage as a two-stage process in which specialized cleavage vesicles first become positioned at the boundaries of each future subdivision and later fuse to compartmentalize the sporangium. RF-FS, however, indicates that cleavage results from the progressive extension of paired sheets of membrane along the future subdivision boundaries. These sheets finally interconnect and subdivide the sporangium. Cleavage vesicles are only evident in preliminary stages of this process and are never aligned along the future boundaries, contrary to the observations of studies based on chemical fixation. Chemical fixation apparently causes the membranous sheets to vesiculate, even at relatively advanced stages of cleavage, thus giving the misleading impression that the resulting network of lined-up vesicles is an intermediate stage in the cleavage process. This finding has wide-ranging implications for the understanding of eukaryotic cytokinesis, because all previous studies that describe vesicle alignment and fusion have relied upon chemical fixation. Other novel features revealed by RF-FS include an extensive extracellular matrix within the sporangium that could be involved in zoospore release, and a trans-Golgi network.

Microtubule dynamics in living dividing plant cells: confocal imaging of microinjected fluorescent brain tubulin

Carboxyfluorescein-labeled brain tubulin has been microinjected into stamen hair cells of Tradescantia, and its distribution during mitosis and cytokinesis was examined using confocal laser scanning fluorescence microscopy. The results show that brain tubulin incorporates into plant microtubules and is utilized throughout mitosis and cytokinesis. Microtubule structures that incorporate brain tubulin include the preprophase band, the perinuclear sheath at late prophase, the kinetochore fibers during prometaphase, metaphase, and anaphase, the interzone spindle during anaphase, and finally the phragmoplast during late anaphase and telophase. All of these microtubule-containing structures and, notably, their transitions from one to another have been observed in single live cells progressing through mitosis and cytokinesis.

Regulation of anaphase chromosome motion in Tradescantia stamen hair cells by calcium and related signaling agents

Several lines of evidence support the idea that increases in the intracellular free calcium concentration [( Ca2+]i) regulate chromosome motion. To directly test this we have iontophoretically injected Ca2+ or related signaling agents into Tradescantia stamen hair cells during anaphase and measured their effect on chromosome motion and on the Ca2+ levels. Ca2+ at (+)1 nA for 10 s (approximately 1 microM) causes a transient (20 s) twofold increase in the rate of chromosome motion, while at higher levels it slows or completely stops motion. Ca2+ buffers, EGTA, and 5,5'-dibromo-1,2- bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid, which transiently suppress the ion level, also momentarily stop motion. Injection of K+, Cl-, or Mg2+, as controls, have no effect on motion. The injection of GTP gamma S, and to a lesser extent GTP, enhances motion similarly to a low level of Ca2+. However, inositol 1,4,5-trisphosphate, ATP gamma S, ATP, and GDP beta S have no effect. Measurement of the [Ca2+]i with indo-1 reveals that the direct injections of Ca2+ produce the expected increases. GTP gamma S, on the other hand, causes only a small [Ca2+]i rise, which by itself is insufficient to increase the rate of chromosome motion. Further studies reveal that any negative ion injection, presumably through hyperpolarization of the membrane potential, generates a similar small pulse of Ca2+, yet these agents have no effect on motion. Two major conclusions from these studies are as follows. (a) Increased [Ca2+]i can enhance the rate of motion, if administered in a narrow physiological window around 1 microM; concentrations above 1 microM or below the physiological resting level will slow or stop chromosomes. (b) GTP gamma S enhances motion by a mechanism that does not cause a sustained uniform rise of [Ca2+]i in the spindle; this effect may be mediated through very localized [Ca2+]i changes or Ca2(+)-independent effectors.