Some retrospectives on early studies of plant microtubules

We pay tribute to the seminal paper 'A microtubule in plant cell fine structure' by Myron C. Ledbetter and Keith R. Porter (1963) by summarizing the very limited knowledge of plant cell ultrastructure that we had prior to that publication, and, by way of our three retrospective accounts, show how this paper stimulated and influenced subsequent research on plant microtubules. Micrographs of historical interest are presented that are either previously unpublished or from primary publications.

What generates flux of tubulin in kinetochore microtubules?

We discuss models for production of tubulin flux in kinetochore microtubules. Current models concentrate solely on microtubules and their associated motors and enzymes. For example, in some models the driving force for flux is enzymes at the poles and the kinetochores; in others the driving force is motor molecules that are associated with a stationary spindle matrix. We present a different viewpoint, that microtubules are propelled poleward by forces arising from the spindle matrix, that the forces on the microtubules "activate" polymerising and depolymerising enzymes at kinetochores and poles, that matrix forces utilise actin, myosin, and microtubule motors, and that the matrix itself may not necessarily be static.

Actin and myosin inhibitors block elongation of kinetochore fibre stubs in metaphase crane-fly spermatocytes

We used an ultraviolet microbeam to cut individual kinetochore spindle fibres in metaphase crane-fly spermatocytes. We then followed the growth of the "kinetochore stubs", the remnants of kinetochore fibres that remain attached to kinetochores. Kinetochore stubs elongate with constant velocity by adding tubulin subunits at the kinetochore, and thus elongation is related to tubulin flux in the kinetochore microtubules. Stub elongation was blocked by cytochalasin D and latrunculin A, actin inhibitors, and by butanedione monoxime, a myosin inhibitor. We conclude that actin and myosin are involved in generating elongation and thus in producing tubulin flux in kinetochore microtubules. We suggest that actin and myosin act in concert with a spindle matrix to propel kinetochore fibres poleward, thereby causing stub elongation and generating anaphase chromosome movement in nonirradiated cells.

Spatial determinants in morphogenesis: recovery from plasmolysis in the diatom Ditylum

Ditylum cells are enclosed in a rigid wall consisting of two "valves" (end walls) connected by "girdle bands." A hollow spine, the Labiate Process (LP), extends from each valve and a stable cytoplasmic strand connects its base with the nucleus. We investigated whether cells might possess "spatial determinants" for controlling their internal organization and wall morphogenesis. Upon plasmolysis, cells contracted into a spherical protoplast detached from the wall. Recovery was initiated by growing filopodia that "searched" the inside of the wall. Some attached to the inside corners, generating tension that could temporarily displace the protoplast. Others consolidated into the strand connecting nucleus with the LP. The protoplasts soon expanded and cells recovered: some divided immediately, the rest within 24 h. When recently divided cells were plasmolysed, their nascent valves were exocytosed. These were ignored by the filopodia during recovery. Later, protoplasts secreted a new valve, while the nascent valves were discarded. The interphase microtubule (MT) cytoskeleton radiates from a central Microtubule Center. A thicker bundle connects the nucleus to each LP. Plasmolysis destroyed the MT cytoskeleton; its re-establishment matched growth of the filopodia. The anti-MT drug oryzalin prevented filopodial extension while existing filopodia retracted, except those stabilized by attachment to the corners of the cell and the LP. Several anti-actin agents had relatively little effect. However, one, mycalolide B, caused the nucleus to be extruded from the protoplast by a bundle of MTs. We conclude that the geometry of the wall could provide spatial information to which the MT-cytoskeleton/filopodia respond.

Structure of kinetochore fibres in crane-fly spermatocytes after irradiation with an ultraviolet microbeam: Neither microtubules nor actin filaments remain in the irradiated region

We studied chromosome movement after kinetochore microtubules were severed. Severing a kinetochore fibre in living crane-fly spermatocytes with an ultraviolet microbeam creates a kinetochore stub, a birefringent remnant of the spindle fibre connected to the kinetochore and extending only to the edge of the irradiated region. After the irradiation, anaphase chromosomes either move poleward led by their stubs or temporarily stop moving. We examined actin and/or microtubules in irradiated cells by means of confocal fluorescence microscopy or serial-section reconstructions from electron microscopy. For each cell thus examined, chromosome movement had been recorded continuously until the moment of fixation. Kinetochore microtubules were completely severed by the ultraviolet microbeam in cells in which chromosomes continued to move poleward after the irradiation: none were seen in the irradiated regions. Similarly, actin filaments normally present in kinetochore fibres were severed by the ultraviolet microbeam irradiations: the irradiated regions contained no actin filaments and only local spots of non-filamentous actin. There was no difference in irradiated regions when the associated chromosomes continued to move versus when they stopped moving. Thus, one cannot explain motion with severed kinetochore microtubules in terms of either microtubules or actin-filaments bridging the irradiated region. The data seem to negate current models for anaphase chromosome movement and support a model in which poleward chromosome movement results from forces generated within the spindle matrix that propel kinetochore fibres or kinetochore stubs poleward.

Phallacidin stains the kinetochore region in the mitotic spindle of the green algae Oedogonium spp

We found previously that in living cells of Oedogonium cardiacum and O. donnellii, mitosis is blocked by the drug cytochalasin D (CD). We now report on the staining observed in these spindles with fluorescently actin-labeling reagents, particularly Bodipy FL phallacidin. Normal mitotic cells exhibited spots of staining associated with chromosomes; frequently the spots appeared in pairs during prometaphase-metaphase. During later anaphase and telophase, the staining was confined to the region between chromosomes and poles. The texture of the staining appeared to be somewhat dispersed by CD treatment but it was still present, particularly after shorter (< 2 h) exposure. Electron microscopy of CD-treated cells revealed numerous spindle microtubules (MTs); many kinetochores had MTs associated with them, often laterally and some even terminating in the kinetochore as normal, but the usual bundle of kinetochore MTs was never present. As treatment with CD became prolonged, the kinetochores became shrunken and sunk into the chromosomes. These results support the possibility that actin is present in the kinetochore of Oedogonium spp. The previous observations on living cells suggest that it is a functional component of the kinetochore-MT complex involved in the correct attachment of chromosomes to the spindle.

Pac-Man does not resolve the enduring problem of anaphase chromosome movement

The Pac-Man hypothesis suggests that poleward movement of chromosomes during anaphase A is brought about by: disassembly of kinetochore microtubules (MTs) at the kinetochore; generation of the poleward force exclusively at or very close to the kinetochore; and the required energy coming from coupled disassembly of these MTs. This model has become widely accepted and cited as the sole or major mechanism of anaphase A. Rarely acknowledged are several significant phenomena that refute some or all of these postulates. We summarise these anomalies as follows: poleward movement of chromosomes occurring without insertion of any MTs at the kinetochore; "anaphase" shortening of kinetochore fibres in spindles entirely devoid of chromosomes and, presumably, kinetochores; continued movement of chromosomes while their severed kinetochore stub elongated poleward after treatment with UV microbeams; and fluxing of tubulin subunits through kinetochore MTs during anaphase A, indicating that during anaphase, kinetochore MTs disassemble partly or solely at the poles.

Traction fibre: toward a "tensegral" model of the spindle

Most current hypotheses of mitotic mechanisms are based on the "PAC-MAN" paradigm in which chromosome movement is generated and powered by disassembly of kinetochore microtubules (k-MTs) by the kinetochore. Recent experiments demonstrate that this model cannot explain force generation for anaphase chromosome movement [Pickett-Heaps et al., 1996: Protoplasma 192:1-10]. Another such experiment is described here: a UV-microbeam cut several kinetochore fibres (k-fibres) in newt epithelial cells at metaphase and the half-spindle immediately shortened: in several cells, the remaining intact spindle fibres bowed outwards as they came under increased compression. Thus, severing of k-MTs can lead to increased tension between chromosomes and poles. This observation cannot be explained by models in which force is produced by motor molecules at the kinetochore actively disassembling k-MTs. Rather, we argue that tensile forces act along the whole k-fibre, which, therefore, can be considered as a classic "traction fibre." We suggest that anaphase polewards force is generated by MTs interacting with the spindle matrix and when k-MTs are severed, polewards force continues to act on the remaining kMT-stub; spindle MTs act as rigid struts concurrently resisting and being controlled by these forces. We suggest that the principles of "cellular tensegrity" [Ingber, 1993: J. Cell Sci. 104:613-627] derived from the behaviour and organization of the interphase cell apply to the spindle. In an evolutionary context, this argument further suggests that the spindle might originally have evolved as the mechanism by which a single tensegral unit (cytoplast) is divided into two cytoplasts; use of the spindle for segregating chromosomes might represent a secondary, more recent development of this primary function. If valid, this concept has implications for the way the spindle functions and for the spindle's relationship to cytokinesis.

The cytoplast concept in dividing plant cells: cytoplasmic domains and the evolution of spatially organized cell

The unique cytokinetic apparatus of higher plant cells comprises two cytoskeletal systems: a predictive preprophase band of microtubules (MTs), which defines the future division site, and the phragmoplast, which mediates crosswall formation after mitosis. We review features of plant cell division in an evolutionary context and from the viewpoint that the cell is a domain of cytoplasm (cytoplast) organized around the nucleus by a cytoskeleton consisting of a single "tensegral" unit. The term "tensegrity" is a contraction of "tensional integrity" and the concept proposes that the whole cell is organized by an integrated cytoskeleton of tension elements (e.g., actin fibers) extended over compression-resistant elements (e.g., MTs).During cell division, a primary role of the spindle is seen as generating two cytoplasts from one with separation of chromosomes a later, derived function. The telophase spindle separates the newly forming cytoplasts and the overlap between half spindles (the shared edge of two new domains) dictates the position at which cytokinesis occurs. Wall MTs of higher plant cells, like the MT cytoskeleton in animal and protistan cells, spatially define the interphase cytoplast. Redeployment of actin and MTs into the preprophase band (PPB) is the overt signal that the boundary between two nascent cytoplasts has been delineated. The "actin-depleted zone" that marks the site of the PPB throughout mitosis may be a more persistent manifestation of this delineation of two domains of cortical actin. The growth of the phragmoplast is controlled by these domains, not just by the spindle. These domains play a major role in controlling the path of phragmoplast expansion. Primitive land plants show different morphological changes that reveal that the plane of division, with or without the PPB, has been determined well in advance of mitosis.The green alga Spirogyra suggests how the phragmoplast system might have evolved: cytokinesis starts with cleavage and then actin-related determinants stimulate and positionally control cell-plate formation in a phragmoplast arising from interzonal MTs from the spindle. Actin in the PPB of higher plants may be assembling into a potential furrow, imprinting a cleavage site whose persistent determinants (perhaps actin) align the outgrowing edge of the phragmoplast, as in Spirogyra. Cytochalasin spatially disrupts polarized mitosis and positioning of the phragmoplast. Thus, the tensegral interaction of actin with MTs (at the spindle pole and in the phragmoplast) is critical to morphogenesis, just as they seem to be during division of animal cells. In advanced green plants, intercalary expansion driven by turgor is controlled by MTs, which in conjunction with actin, may act as stress detectors, thereby affecting the plane of division (a response clearly evident after wounding of tissue). The PPB might be one manifestation of this strain detection apparatus.

Cytochalasin D and latrunculin affect chromosome behaviour during meiosis in crane-fly spermatocytes

Living crane-fly spermatocytes were treated with 10-20 microg/ml cytochalasin D (CD) or 0.3 microg/ml latrunculin (LAT) at various stages of meiosis I. The drugs had the same effects on chromosome behaviour, but CD effects were reversible and LAT effects generally were not. When applied in mid-prometaphase to metaphase, both drugs altered subsequent anaphase poleward movements: half-bivalents either moved more slowly than normal, or moved more slowly after a brief period of movement at normal rate or stalled for 10 min or more immediately after disjunction. CD effects were reversible: within 1 min after washing out the CD, stopped chromosomes started moving and slowed chromosomes sped up. When applied in anaphase, both drugs stopped or slowed poleward chromosome movements, usually reversibly. When applied near the end of prophase, both drugs often prevented one or more bivalents in the cell from attaching to the spindle. Attached bivalents behaved as in cells treated with drugs at later stages, as described above. Unattached bivalents in the same cells moved to poles or cytoplasm in early prometaphase, where they remained motionless; at anaphase they sometimes did not disjoin, but when they did disjoin the half-bivalents did not move, either in the continued presence of the drug or when CD was washed out, confirming that they were not atttached. When CD or LAT prevented all bivalents in the cell from attaching, spindles kept in the drug were invaded by granules at about the time of normal anaphase. Conversely, when CD was washed out during late prometaphase, chromosomes often attached to spindle fibres and later entered anaphase. As CD and LAT are different antiactin drugs, but have the same effect on chromosome behaviour, the results implicate actin in early interactions of chromosomes with spindle fibres and in anaphase chromosome movements.

The effects of diazepam on mitosis and the microtubule cytoskeleton. I. Observations on the diatoms Hantzschia amphioxys and Surirella robusta

The effects of diazepam (DZP) on mitosis and the microtubule (MT) cytoskeleton in the live diatoms Hantzschia amphioxys and Surirella robusta were followed using time-lapse video microscopy. Similarly treated cells were fixed and later examined for immunoflouresence staining of MTs or for transmission electron microscopy. DZP treatment (250 microM) had no effect on interphase cells but affected mitosis, resulting in the majority of prometaphase and metaphase chromosomes releasing from one or both spindle poles and collecting irregularly along the central spindle. Chromosomes remaining attached to one pole continued to display slight prometaphase oscillations; however, this activity was never observed in metaphase spindles. Following removal of DZP, some chromosomes still bipolarly attached, immediately released elastically from one pole. Within the first 2 minutes of recovery, all chromosomes recommenced spindle attachment, exhibiting normal prometaphase oscillations and proceeded through mitosis. DZP treatment during anaphase had no detectable effect on chromosome motion or cell cleavage. These results suggest that DZP acts as an anti-MT agent, selectively affecting polar MTs at prophase, prometaphase and metaphase, and thereby weakening kinetochore connection to the poles. From these and other results (unpublished), its mode of action is different to that of most anti-MT agents.

An extended corona attached to metaphase kinetochores of the green alga Oedogonium

Mitotic cells of the green alga Oedogonium were treated with the anti-microtubule agent oryzalin (1.0-0.1 microM) for 5 to 10 min. Within 5 min treatment of living cells, metaphase spindles became spherical with disorganized chromosomes, and anaphase spindles collapsed. At lower concentrations, the effects were slower, and partial recovery was observed about 10 to 20 min after the drug was washed out. Following breakdown of the spindle, considerable disorganized activity detected by time-lapse continued within the nucleus, isolated from the cytoplasm by its intact nuclear membrane. Under the electron microscope, spindle microtubules (MTs) were absent in oryzalin-treated cells. Paired metaphase kinetochores displayed an array of fine filamentous material extended, usually straight, about 3 microns into the nucleoplasm. In cells recovering from oryzalin treatment, MTs became associated with kinetochores in the usual manner. However, this filamentous array, the "extended corona" (EC), was almost undetectable, even when the MTs were short and poorly organized. The EC is appreciably larger by metaphase than the corona of prophase chromosomes and so it may assemble during early mitosis. Fine filaments interspersed with kinetochore MTs have been described in carefully fixed cells of this alga (M.J. Schibler, J.D. Pickett-Heaps, Eur. J. Cell Biol. 22, 687-698 (1980)). The EC apparently represents a less organized form of this material remaining after its scaffold of MTs has been removed. These fibers appear involved in MT capture upon spindle recovery from anti-MT drugs. They could function during prometaphase and even anaphase movement along spindle MTs.

UV-microbeam irradiations of the mitotic spindle: spindle forces and structural analysis of lesions

Mitotic PtK1 spindles were UV irradiated (285 nm) during metaphase and anaphase between the chromosomes and the pole. The irradiation, a rectangle measuring 1.4 x 5 microns parallel to the metaphase plate, severed between 90 and 100% of spindle microtubules (MTs) in the irradiated region. Changes in organization of MTs in the irradiated region were analyzed by EM serial section analysis coupled with 3-D computer reconstruction. Metaphase cells irradiated 2 to 4 microns below the spindle pole (imaged by polarization optics) lost birefringence in the irradiated region. Peripheral spindle fibers, previously curved to focus on the pole, immediately splayed outwards when severed. We demonstrate via serial section analysis that following irradiation the lesion was devoid of MTs. Within 30 s to 1 min, recovery in live cells commenced as the severed spindle pole moved toward the metaphase plate closing the lesion. This movement was concomitant with the recovery of spindle birefringence and some of the severed fibers becoming refocused at the pole. Ultrastructurally we confirmed that this movement coincided with bridging of the lesion by MTs presumably growing from the pole. The non-irradiated half spindle also lost some birefringence and shortened until it resembled the recovered half spindle. Anaphase cells similarly irradiated did not show recovery of birefringence, and the pole remained disconnected from the remaining mitotic apparatus. Reconstructions of spindle structure confirmed that there were no MTs in the lesion which bridged the severed spindle pole with the remaining mitotic apparatus. These results suggest the existence of chromosome-to-pole spindle forces are dependent upon the existence of a MT continuum, and to a lesser extent to the loss of MT initiation capacity of the centrosome at the metaphase/anaphase transition.

UV microbeam irradiations of the mitotic spindle. II. Spindle fiber dynamics and force production

Metaphase and anaphase spindles in cultured newt and PtK1 cells were irradiated with a UV microbeam (285 nM), creating areas of reduced birefringence (ARBs) in 3 s that selectively either severed a few fibers or cut across the half spindle. In either case, the birefringence at the polewards edge of the ARB rapidly faded polewards, while it remained fairly constant at the other, kinetochore edge. Shorter astral fibers, however, remained present in the enlarged ARB; presumably these had not been cut by the irradiation. After this enlargement of the ARB, metaphase spindles recovered rapidly as the detached pole moved back towards the chromosomes, reestablishing spindle fibers as the ARB closed; this happened when the ARB cut a few fibers or across the entire half spindle. We never detected elongation of the cut kinetochore fibers. Rather, astral fibers growing from the pole appeared to bridge and then close the ARB, just before the movement of the pole toward the chromosomes. When a second irradiation was directed into the closing ARB, the polewards movement again stopped before it restarted. In all metaphase cells, once the pole had reestablished connection with the chromosomes, the unirradiated half spindle then also shortened to create a smaller symmetrical spindle capable of normal anaphase later. Anaphase cells did not recover this way; the severed pole remained detached but the chromosomes continued a modified form of movement, clumping into a telophase-like group. The results are discussed in terms of controls operating on spindle microtubule stability and mechanisms of mitotic force generation.

The effects of colchicine and dinitrophenol on the in vivo rates of anaphase A and B in the diatom Surirella

The rates of chromosome-to-pole movement (anaphase A) and pole-pole separation (anaphase B) in vivo were measured in the pennate diatom Surirella, using differential interference contrast (DIC) light microscopy. In control cells, the rate of anaphase A is 1.6 +/- 0.6 micron/min, the rate of anaphase B is 2.3 +/- 0.3 micron/min, and the extent of anaphase B is 26.7 +/- 9.7% of metaphase spindle length. Colchicine was added to metaphase cells in order to inhibit any further addition of microtubule (MT) subunits onto the spindle. Colchicine, which does not break down the well-ordered Surirella central spindle, caused no significant change in the rate of anaphase A (1.3 +/- 0.3 micron/min) while it significantly decreased both the rate of anaphase B (1.2 +/- 0.4 micron/min) and the extent of anaphase B (14.8 +/- 8.3% of metaphase spindle length). Surirella cells were also treated with the metabolic inhibitor 2-4-dinitrophenol (DNP) in order to test the effects of energy depletion on anaphase. When DNP was added early in anaphase A, prior to the completion of sister chromosome separation, anaphase A was inhibited. When DNP was added after initiation of sister chromosome separation, anaphase A continued to completion, although at a lower rate than control cells (0.5 +/- 0.2 micron/min). Anaphase B was completely inhibited by DNP, but upon recovery from DNP resumed at a normal rate (2.2 +/- 0.5 micron/min) and progressed to a slightly larger than normal extent (44.0 +/- 13.0% of metaphase length).(ABSTRACT TRUNCATED AT 250 WORDS)

On the mechanism of anaphase A: evidence that ATP is needed for microtubule disassembly and not generation of polewards force

As anaphase began, mitotic PtK1 and newt lung epithelial cells were permeabilized with digitonin in permeabilization medium (PM). Permeabilization stopped cytoplasmic activity, chromosome movement, and cytokinesis within about 3 min, presumably due to the loss of endogenous ATP. ATP, GTP, or ATP-gamma-S added in the PM 4-7 min later restarted anaphase A while kinetochore fibers shortened. AMPPNP could not restart anaphase A; ATP was ineffective if the spindle was stabilized in PM + DMSO. Cells permeabilized in PM + taxol varied in their response to ATP depending on the stage of anaphase reached: one mid-anaphase cell showed initial movement of chromosomes back to the metaphase plate upon permeabilization but later, anaphase A resumed when ATP was added. Anaphase A was also reactivated by cold PM (approximately 16 degrees C) or PM containing calcium (1-10 mM). Staining of fixed cells with antitubulin showed that microtubules (MTs) were relatively stable after permeabilization and MT assembly was usually promoted in asters. Astral and kinetochore MTs were sensitive to MT disassembly conditions, and shortening of kinetochore MTs always accompanied reactivation of anaphase A. Interphase and interzonal spindle MTs were relatively stable to cold and calcium until extraction of cells was promoted by longer periods in the PM, or by higher concentrations of detergent. Since we cannot envisage how both cold treatment or relatively high calcium levels can reactivate spindle motility in quiescent, permeabilized, and presumably energy-depleted cells, we conclude that anaphase A is powered by energy stored in the spindle. The nucleotide triphosphates effective in reactivating anaphase A could be necessary for the kinetochore MT disassembly without which anaphase movement cannot proceed.

Microtubule dynamics in the spindle. Theoretical aspects of assembly/disassembly reactions in vivo

The mitotic spindle contains several classes of microtubules (MTs) whose lengths change independently during mitosis. Precise control over MT polymerization and depolymerization during spindle formation, anaphase chromosome movements, and spindle breakdown is necessary for successful cell division. This model proposes the site of addition and removal of MT subunits in each of four classes of spindle MTs at different stages of mitosis, and suggests how this addition and removal is controlled. We propose that spindle poles and kinetochores significantly alter the assembly-disassembly kinetics of associated MT ends. Control of MT length is further modulated by localized forces affecting assembly and disassembly kinetics of individual sets of MTs.

The organization of microtubules during anaphase and telophase spindle elongation in the rust fungus Puccinia

The entire framework of microtubules (MTs) in the meiotic spindle of the rust fungus Puccinia has been reconstructed during the later stages of meiosis I, by tracking MTs through transverse serial sections. This spindle is of special interest because it elongates considerably during anaphase spindle elongation, from 5 microns at metaphase to 15 microns at telophase. The spindle is composed mainly of MTs from opposite poles which interdigitate or overlap in the middle of the spindle. In the overlap region, MTs from one pole seek out as near neighbors, MTs from the opposite pole at a preferred spacing of 43 to 55 nm. During anaphase elongation three changes in spindle structure occur: 1) the region of overlap decreases, but this reduction in overlap cannot account for all the increase in spindle length; 2) interdigitated MTs (MTs from one pole that are within 80 nm of a MT from the opposite pole) dramatically increase in length by MT polymerization and; 3) kinetochore MTs, free MTs (those unattached to the poles) and non-interdigitated polar MTs shorten and disappear. The mechanism of anaphase elongation and the control over MT polymerization and depolymerization during anaphase are discussed.

Spindle microtubule dynamics following ultraviolet-microbeam irradiations of mitotic diatoms

Lesions ("ARBs") generated in metaphase and anaphase central spindles of Hantzschia by an ultraviolet microbeam are devoid of microtubules previously present. In vivo, the poleward transverse edge of the lesion invariably loses birefringence poleward, until this segment has vanished; the loss is slow during metaphase and faster at anaphase. The other transverse edge, proximal to the overlap, remains stable until disassembly of the whole spindle. We conclude that the central spindle microtubules are not in flux during metaphase to telophase, and that depolymerization of these microtubules takes place only from the end distal to the pole, as during normal spindle disassembly. Microtubule polarity and the creation of free ends may determine which microtubules are disassembled during later mitosis and how disassembly proceeds.

A routine flat embedding method for electron microscopy of microorganisms allowing selection and precisely orientated sectioning of single cells by light microscopy

A simple method is described to embed material in resin, in the form of microscope slides, to observe it with high resolution light microscopy, to select, orient and section it for TEM. This method can be applied to many kinds of material but is particularly useful for the study of rare or tiny plant or animal microorganisms from field or culture. A diamond scriber, translucent hydrosoluble resin release agent, translucent and smooth resin stubs and a longitudinally perforated block-holder for ultramicrotome are the specific tools of this method.

Near-neighbor analysis of spindle microtubules in the alga Ochromonas

The near-neighbor spacing of microtubules (MTs) in the spindle of the alga Ochromonas is analyzed. The technique of near-neighbor analysis of MTs (as developed by McDonald et al. [9]) in the mid-region of the Ochromonas spindle (overlap) shows that MTs from one pole preferentially associate with MTs from the opposite pole at a center-to-center distance of 35 to 43 nm. However, in the half spindle between the chromosomes and the poles, kinetochore MTs (kMTs) do not preferentially associate with other MTs in the half spindle but instead are arranged essentially at random. Individual polar MTs (MTs attached to one pole), kMTs and free MTs (MTs unattached to the poles) were selected for near-neighbor analysis over their entire lengths. The spacing of MTs in the overlap is compatible with those models for mitosis which propose that separation of the poles is accomplished by sliding between closely spaced MTs of opposite polarity. In contrast to the overlap, the arrangement of MTs in the half spindle is not compatible with MT2MT sliding theories that propose that chromosome movement is accomplished by sliding between kMTs and polar MTs.

Ultraviolet microbeam irradiations of mitotic diatoms: investigation of spindle elongation

Our simple instrumentation for generating a UV-microbeam is described UV microbeam irradiations of the central spindle in the pennate diatom Hantzschia amphioxys have been examined through correlated birefringence light microscopy and TEM. A precise correlation between the region of reduced birefringence and the UV-induced lesion in the microtubules (MTs) of the central spindle is demonstrated. The UV beam appears to dissociate MTs, as MT fragments were rarely encountered. The forces associated with metaphase and anaphase spindles have been studied via localized UV-microbeam irradiation of the central spindle. These spindles were found to be subjected to compressional forces, presumably exerted by stretched or contracting chromosomes. Comparisons are made with the results of other writers. These compressional forces caused the poles of a severed anaphase spindle to move toward each other and the center of the cell. As these poles moved centrally, the larger of the two postirradiational central spindle remnants elongated with a concomitant decrease in the length of the overlap. Metaphase spindles, in contrast, did not elongate nor lose their overlap region. Our interpretation is that the force for anaphase spindle elongation in Hantzschia is generated between half-spindles in the region of MT overlap.

Studies on kinetochore function in mitosis. I. The effects of colchicine and cytochalasin on mitosis in the diatom Hantzschia amphioxys

Cytochalasin does not affect mitosis (including half spindle separation and disassembly) while cleavage is partially or totally inhibited. While colchicine stops central spindle growth, it resists breakdown even after prolonged exposure. Prometaphase chromosome movement soon ceases, and some attached chromosomes slowly detach; these phenomena are correlated with a loss of the numerous microtubules (MTs) that emanate from the poles, with which chromosomes interact. "C-anaphase", often seen, is marked in vivo by spindle elongation and unequal polar distribution of those chromosomes still attached to the central spindle; this stage is characterized ultrastructurally by the accumulation of dense matrix material, probably the "collar" previously described, at the poles. Kinetochores often remain tightly associated with this matrix. We believe this result is significant, since it clearly demonstrates that the kinetochores are attached to a spindle component other than microtubules. We suspect that this matrix is contractile and part of the mitotic machinery for moving chromosomes. These colchicine effects are not reversible.

Mitosis in Oedogonium: spindle microfilaments and the origin of the kinetochore fiber

New ultrastructural observations of mitosis in the closed spindle of Oedogonium cardiacum have been made using cells fixed with glutaraldehyde and tannic acid. Fine filaments 5 to 8 nm in diameter are attached to kinetochores from prophase through anaphase. Some are free in the early division nucleus while others emanate from forming kinetochores at prophase when few if any microtubules (MTs) are inside the nucleus. During prometaphase, MTs invade the nucleus from the poles and appear to interact with the microfilaments. Early in prometaphase, numerous MTs are laterally associated with kinetochores, and the kinetochore fiber is often formed first at one kinetochore of a pair. During metaphase and anaphase, the microfilaments are interspersed among the MTs of these kinetochore fibers. There also is an ill-defined matrix concentrated in the kinetochore fiber, and MTs are often coated irregularly with osmiophilic material. Live mitotic cells of Oedogonium were studied using time lapse cinematography, and we correlate these observations with the above results. We conclude that these microfilaments may constitute one structural component of the traction apparatus that moves chromosomes during metakinesis and anaphase, and that at least some (and possibly many) of the MTs of the kinetochore fiber are derived from those entering the nucleus at prometaphase.

Cell division in two large pennate diatoms Hantzschia and Nitzschia III. A new proposal for kinetochore function during prometaphase

Prometaphase in two large species of diatoms is examined, using the following techniques: (a) time-lapse cinematography of chromosome movements in vivo; (b) electron microscopy of corresponding stages: (c) reconstruction of the microtubules (MTs) in the kinetochore fiber of chromosomes attached to the spindle. In vivo, the chromosomes independently commence oscillations back and forth to one pole. The kinetochore is usually at the leading edge of such chromosome movements; a variable time later both kinetochores undergo such oscillations but toward opposite poles and soon stretch poleward to establish stable bipolar attachment. Electron microscopy of early prometaphase shows that the kinetochores usually laterally associate with MTs that have one end attached to the spindle pole. At late prometaphase, most chromosomes are fully attached to the spindle, but the kinetochores on unattached chromosomes are bare of MTs. Reconstruction of the kinetochore fiber demonstrates that most of its MTs (96%) extend past the kinetochore and are thus apparently not nucleated there. At least one MT terminates at each kinetochore analyzed. Our interpretation is that the conventional view of kinetochore function cannot apply to diatoms. The kinetochore fiber in diatoms appears to be primarily composed of MTs from the poles, in contrast to the conventional view that many MTs of the kinetochore fiber are nucleated by the kinetochore. Similarly, chromosomes appear to initially orient their kinetochores to opposite poles by moving along MTs attached to the poles, instead of orientation effected by kinetochore MTs laterally associating with other MTs in the spindle. The function of the kinetochore in diatoms and other cell types is discussed.

Light and electron microscopic observations on cell division in two large pennate diatoms, Hantzschia and Nitzschia. I. Mitosis in vivo

Mitosis and cytokinesis have been followed in live cells using Nomarski and birefringence optics. Prophase is protracted. The small square or rectangular spindle is brillantly birefringent and situated close to one side of the cell. It grows very slowly until suddenly it begins to elongate rapidly, doubling or trebling its length in a few minutes. This prometaphase stage is immediately accompanied by very active, oscillatory movements of the previously quiescent chromosomes, along invisible tracks directed at either pole. Independently, each pair of chromatids soon attaches to the other pole as well; immediately, its oscillations cease, and it becomes stretched across the central spindle. Some chromosomes attach almost as soon as the spindle enters the nucleus, others much later. The overlap in the central spindle becomes discernable during mid prometaphase; it stays roughly the same length while the total length of the spindle increases to a temporarily stable maximum at metaphase which is quiescent except for late chromosome attachments and which lasts around 10 mins. Then suddenly and synchronously, the chromatids split and immediately move polewards as if tension has been released in the. About a minute later, the spindle recommences elongation, but now the overlap diminishes in step with elongation. At this stage, Nitzschia and Hantzschia differ markedly in behavior. In Hantzschia, like other diatoms, the half spindles become coarsely striated near the poles, and the elongated central spindle stays intact after reaching its maximum length, until broken by the cleavage furrow, whereupon the broken halves slowly disassemble. In contrast, the half spindles in Nitzschia never display such striations, and after maximum elongation, the central spindle rapidly breaks down entirely, before cleavage is complete. The cleavage furrow grows inward very slowly during metaphase. Its ingrowth is stimulated during late anaphase, and it moves inwards at about 20 micrometer/min. Most of the cleavage is accomplished in about 4 mins. The chloroplasts are pulled inwards and finally pinched in two by the furrow. These events are discussed with emphasis on the dynamics and mechanics of spindle assembly, elongation and disassembly.

Light and electron microscopic observations on cell division in two large pennate diatoms. Hantzschia and Nitzschia. II. Ultrastructure

Cells, preselected to cover all stages of mitosis, were sectioned accurately for investigating changes in spindle structure that accompany mitosis. During spindle formation, the interphase Microtubule Center (MC) breaks down. Numerous tiny foci, each apparently nucleating one microtubule (MT) and derived from the MC, line up along the two polar plates; lateral interaction between these two sets of (oppositely polarized--?) MTs is presumed to generate the MT packing arrangement characteristic of the diatom spindle's overlap. Later, when the elongating central spindle enters the nucleus at prometaphase, the MTs from each polar plate have either interacted thus to generate the central spindle proper, or else they radiate into the nucleus. This latter population of MTs interacts with the kinetochores and most become thereby organized into kinetochore fibres. The zone of overlap quickly develops ragged edges, suggesting that it is labile (i.e., by irregular sliding and/or growth of MTs) even at early prometaphase. Metaphase spindle structure is as expected from light microscopy. The collar material is difficult to discern, but it apparently permeates the kinetochore fibres. During anaphase, the overlap diminishes and disappears as the spindle elongates. The chromosomes always move past the ends of the spindle, a movement accomplished without any apparent involvement of MTs. In N. sigmoidea, the spindle invariably breaks down upon completion of elongation, and the scattered remnants of its MTs soon disappear. In contrast, the central spindle of H. amphioxys persists until it is broken by the cleavage furrow; the MTs in the half spindle away from the overlap always exhibit pronounced clumping. These observations are integrated with extensive observations on mitosis in vivo, with a view to understanding the mechanisms of spindle formation, function and disassembly.

Analysis of the distribution of spindle microtubules in the diatom Fragilaria

The spindle of the colonial diatom Fragilaria contains two distinct sets of spindle microtubules (MTs): (a) MTs comprising the central spindle, which is composed of two half-spindles interdigitated to form a region of "overlap"; (b) MTs which radiate laterally from the poles. The central spindles from 28 cells are reconstructed by tracking each MT of the central spindle through consecutive serial sections. Because the colonies of Fragilaria are flat ribbons of contiguous cells (clones), it is possible, by using single ribbons of cells, to compare reconstructed spindles at different mitotic stages with minimal intercellular variability. From these reconstructions we have determined: (a) the changes in distribution of MTs along the spindle during mitosis; (b) the change in the total number of MTs during mitosis; (c) the length of each MT (measured by the number of sections each traverses) at different mitotic stages; (d) the frequency of different classes of MTs (i.e., free, continuous, etc.); (e) the spatial arrangement of MTs from opposite poles in the overlap; (f) the approximate number of MTs, separate from the central spindle, which radiate from each spindle pole. From longitudinal sections of the central spindle, the lengths of the whole spindle, half-spindle, and overlap were measured from 80 cells at different mitotic stages. Numerous sources of error may create inaccuracies in these measurements; these problems are discussed. The central spindle at prophase consists predominantly of continuous MTs (pole to pole). Between late prophase and prometaphase, spindle length increases, and the spindle is transformed into two half-spindles (mainly polar MTs) interdigitated to form the overlap. At late anaphase-telophase, the overlap decreases concurrent with spindle elongation. Our interpretation is that the MTs of the central spindle slide past one another at both late prophase and late anaphase. These changes in MT distribution have the effect of elongating the spindle and are not involved in the poleward movement of the chromosomes. Some aspects of tracking spindle MTs, the interaction of MTs in the overlap, formation of the prophase spindle, and our interpretation of rearrangements of MTs, are discussed.

Electron microscope study of vegetative cell division in two species of Marchanda

Cell division in Marehantia polymorpha and M. berteroana was examined with the electron microscope. Distinct preprophase bands of microtubules, typical of higher plants, were not observed. Most of the spindle microtubules in early prophase appeared to insert into polar MTOC's. The behaviour of the nuclear envelope, nucleolus, and chromosomes was typical of higher plant divisions. Cytokinesis was accomplished by centrifugal cell plate growth in a phragmoplast. Numerous coated vesicles were associated with the developing cell plate.

On the mechanism of anaphase spindle elongation in Diatoma vulgare

Central spindles from five dividing cells (one metaphase, three anaphase, and one telophase) of Diatoma vulgare were reconstructed from serial sections. Each spindle is made up of two half-spindles that are composed almost entirely of polar microtubules. A small percentage of continuous microtubules and free microtubules were present in every stage except telophase. The half-spindles interdigitate at the midregion of the central spindle, forming a zone of overlap where the microtubules from one pole intermingle with those of the other. At metaphase the overlap zone is fairly extensive, but as elongation proceeds, the spindle poles move apart and the length of the overlap decreases because fewer microtubules are sufficiently long to reach from the pole to the zone of interdigitation. At telophase, only a few tubules are long enough to overlap at the midregion. Concurrent with the decrease in the length of the overlap zone is an increase in the staining density of the intermicrotubule matrix at the same region. These changes in morphology can most easily be explained by assuming zone mechanochemical interaction between microtubules in the overlap zone which results in a sliding apart of the two half-spindles.

Mitosis in the pennate diatom Surirella ovalis

Mitosis in Surirella is described; this organism displays a number of unusual features including an unorthodox method of chromosome attachment to the spindle, and the differentiation of an extranuclear central spindle from a large spherical organelle named the microtubule center (MC). The MC, present during interphase, breaks down at late prophase as the central spindle is formed. Later, the spindle enters the nucleus; the chromatin, in association with microtubules (MTs) from the poles, increasingly aggregates around the middle "overlap" region of the central spindle, and by metaphase completely encircles it. Throughout, MTs usually associate laterally with the chromatin. We were not able to identify kinetochore MTs with confidence at either metaphase or anaphase. Instead, at anaphase the leading point of the chromosomes is embedded in a ring of electron-dense material, named the "collar," which encircles each half spindle and extends from the chromatin to the pole. Anaphase separation of the chromosomes is achieved by at least three separate mechanisms: (a) between metaphase and late anaphase the central spindle increases in length by the addition of MT subunits; (b) at late anaphase the central spindle elongates concurrent with a reduction in the overlap; this apparently results from an MT/MT sliding mechanism; (c) each set of chromosomes moves to the poles by a thus far unknown mechanism; however, we anticipate some interaction of the collar and central spindle. At telophase, the polar complexes, (i.e., structures at the spindle pole) separate from the spindle, and later a new MC is formed near each polar complex, after which the polar complexes break down. Aspects of the complex differentiation of the MC, spindle formation, and some unusual characteristics of the diatom spindle as they relate to anaphase motion and spindle function are discussed.

Apparent amitosis in the binucleate dinoflagellate Peridinium balticum

Mitosis and cytokinesis in the free-living binucleate dinoflagellate Peridinium balticum are described, P. balticum contains 2 nuclei; one is a typical dinoflagellate nucleus and the other resembles the interphase nuclei of some eucaryotic cells and is here named the supernumerary nucleus (formerly called the eucaryotic nucleus). The dinoflagellate nucleus divides in the characteristic manner already described for certain other dinoflagellates. The supernumerary nucleus does not undergo normal mitosis; its chromatin does not condense, a spindle is not differentiated for its division, nor are any microtubules present inside the nucleus during any stage of its division. Instead the supernumerary nucleus divides by simple cleavage, which is concurrent with cytoplasmic cleavage. The nucleus cleaves first on its side facing the wall, but later it cleaves circumferentially as the cytoplasmic cleavage furrow draws closer. Invariably at late cytokinesis, a portion of the dividing nucleus passes through the only remaining uncleaved area of the cell. The final separation of the supernumerary nucleus is probably accomplished by the ingrowing furrow pinching the nucleus in two. There is no apparent precise segregation of genetic material during division, nor are there any structural changes inside the dividing nucleus which distinguish it from the interphase nucleus. Certain aspects of amitosis, and previously postulated theories concerning the endosymbiont origin of the second nucleus, are discussed.

The effect of colchicine on colony formation in the algae Hydrodictyon, Pediastrum and Sorastrum

Uninucleate, biflagellate zoospores of Hydrodictyon, Pediastrum and Sorastrum, derived from multinucleate parental cells, aggregate and adhere to form distinctively patterned colonies; earlier work has shown that microtubules underlie the plasmalemma of these zoospores and are also conspicuous in the developing horns of aggregating cells of Pediastrum and Sorastrum. Colchicine applied to parental cells inhibited cytoplasmic cleavage and production of uninucleate zoospores. When zoospores were treated with colchicine, their peripheral microtubules disappeared; the spores failed to aggregate in ordered arrays and did not develop horns. The microtubules therefore appear to play an important role in determining the arrangement of cells in developing colonies by affecting the shape of the cells at the time of their aggregation.

The effects of isopropyl N-phenyl carbamate on the green alga Oedogonium cardiacum. I. Cell division

Cell division in vegetative filaments of the green alga Oedogonium cardiacum is presented as an experimental system. We report on how we have used this system to study the effects of isopropyl N-phenylcarbamate (IPC) on the mitotic apparatus and on the phycoplast, a planar array of cytokinetic microtubules. Polymerization of microtubules was prevented when filaments, synchronized by a light/dark regime and chilled (2 degrees C) while in metaphase or just before phycoplast formation, were exposed to 5.5 x 10(-4) M IPC and then returned to room temperature. Spindles reformed or phycoplasts formed when these filaments were transferred to growth medium free of IPC. However, the orientation of both microtubular systems was disturbed: the mitotic apparatus often contained three poles, frequently forming three daughter nuclei upon karyokinesis; the phycoplast was often stellate rather than planar, and it sometimes was displaced to the side of both daughter nuclei, resulting in a binucleate and an anucleate cell upon cytokinesis. Our results suggest that IPC (a) prevents the assembly of microtubules, (b) increases the number of functional polar bodies, and (c) affects the orientation of microtubules in O. cardiacum. High voltage (1,000 kV) electron microscopy of 0.5-microm thick sections allowed us to visualize the polar structures, which were not discernible in thin sections.

Ultrastructure and Differentiation of Hydrodictyon Reticulatum IV. Conjugation of Gametes and the Development of Zygospores and Azygospores

In H. reticulatum, gametes differed from other zooids principally in that some of them bore an electron�dense apical cap between their flagella. Conjugation did not take place until the walls of the coenobia, in which the gametes developed, ruptured; and often did not occur even among the liberated gametes. Only in zooids collected from cultures in which conjugation was evident were these apical caps extended as fertilization tubules. Fertilization took place by the fusion of the tip of this tubule on one gamete with the membrane between the flagella of another which apparently lacked a fertilization tubule. Subsequent lateral fusion of the united zooids produced quadriflagellate zygotes which were active for only a short time before flagellar retrac� tion and cell wall deposition. Karyogamy usually preceded wall secretion. Gametes failing to conjugate often laid down a wall to form azygotes.

Ultrastructure and Differentiation of Hlydrodictyon Reticulatum VI. Formation of the Germ Net

Uninucleate, biflagellate, net-forming zoo ids arise by cleavage of the multi-nucleate cytoplasm of polyhedra. These zoo ids appeared to be indistinguishable from net-forming zooids produced by cylindrical coenocytes. Whereas zoo ids derived from cylindrical cells aggregated within their parental cell wall to form cylindrical nets, zooids produced by polyhedra swarmed within a spheroidal vesicle, probably derived from the inner layer of polyhedral wall, and aggregated usually as a flat net, similar to nets of other species of Hydrodictyon and vegetative colonies of Pediastrum. Bands of peripheral microtubules underlaid the initial sites of contact of aggregating zooids; the role of these microtubules, which were generally oriented in the plane of the developing net, and other aspects of patterned cellular aggregation are discussed.

Ultrastructure and Differentiation of Hydrodictyon Reticulatum III. Formation of the Vegetative Daughter Net

Vegetative zooids of H. reticulatum, produoed by cleavage of parental ooenobial oytoplasm, linked together within their parental oell walls to form oylindrioal nets oharaoteristio of this alga. A oonspiouous feature of net-forming zooids were bands of miorotubules underlying the plasmalemma. An active role is proposed for these miorotubules in the ordered linking of the zooids. Amorphous material, presumably adhesive, was seen only in interoellular spaces between aggregating zooids. Following adhesion of the zooids, eaoh one usually linking with four others, their flagella were retraoted and both flagellar miorotubules and basal bodies disintegrated. Centrioles arose de novo on the nuolear envelope of eaoh cell at the time of deposition of a bilayered wall.

"Bristly" cristae in algal mitochondria

In forming zoospores of Oedogonium, mitochondria were found to contain numerous, evenly-spaced bristle-like structures projecting from the surface of cristae.

Ultrastructure and differentiation of Hydrodictyon reticulatum. II. Formation of zooids within the coenobium

A summary of the life cycle of H. reticulatum is given here in the second of a series of papers on an ultrastructural study of the development and differentiation of the various stages in the life cycle. The formation of zooids by the coenobia is then discussed in detail. After the fragmentation of the chloroplast and disintegra. tion of the pyrenoids the cytoplasm cleaves: firstly, to form the vacuolar envelope, a thin cytoplasmic layer that separates the vacuole from the rest of the cytoplasm; secondly, to form uninucleate fragments of the cytoplasm each of which later develops a pair of flagella. Observations on the cytoplasmic cleavage and the role of microtubules in the cleavage are related to similar events in other algae. The function of the vacuolar envelope and the golgi apparatus, and the disintegration of the pyrenoids are also discussed.