MICROTUBULE ARMS AND CYTOPLASMIC STREAMING AND MICROTUBULE BENDING AND STRETCHING OF INTERTUBULE LINKS IN THE FEEDING TENTACLE OF THE SUCTORIAN CILIATE TOKOPHRYA

Microtubules attached to the pellicle at the tips of tentacles pivot through about 140° on these attachments, splay apart, and bend along their longitudinal axes when feeding occurs. The tubules could be bending in response to pellicular contractions; active bending, sliding, or contraction of the tubules may not be involved. Intertubule links apparently prevent tubules from splaying apart at certain levels. These links are probably under tension during feeding. They stretch; they sometimes become half as thick and eight times as long as they are before feeding. Often, tubules joined together by these links also change in shape; they become slightly flattened and elliptical in cross section. Cytoplasm from the ciliate Tetrahymena is drawn down a feeding tentacle inside an invagination of the Tokophrya cell membrane from the tentacle tip. The positions of arm-bearing microtubules around such invaginations indicate that arms are involved in moving invaginations along. The edges of the perforated Tetrahymena cell membrane are "sealed" to the cell membrane of Tokophrya around each feeding tentacle tip.     

Ultrastructural studies of the commensal suctorian,Choanophrya infundibulifera hartog

Summary The feeding tentacles of Choanophrya contain a central canal lined by microtubules. Only one tentacle develops during metamorphosis of the embryo into the adult, but others develop at intervals throughout adult life. Each tentacle forms adjacent to a solitary, subcortical kinetosome which lies parallel to the body surface, lacks accessory elements and never develops a cilium. Small condensations of electron-dense material and short bundles of microtubules form adjacent to the cartwheel region of the kinetosome. Initially these bundles are orientated randomly but later they become radially arranged and curved into prolamellae around a disc-shaped condensation centre, to form a paddlewheel-like tentacle primordium 0.8–1.1 m in diameter. The condensation centre consists of alternating concentric electron-dense and electron-transparent zones, and lies with its axis perpendicular to both the kinetosome and the cortex. The microtubules in each prolamella increase in number and pairs of short tip microtubules develop between adjacent prolamellae. Subsequently the developing lamellae become enclosed by a cylinder of ring microtubules. Once all the microtubule components of the tentacle primordium are established it increases in length by addition of material to the basal ends of the microtubules to form a short microtubule canal. As the canal elongates the epiplasm above it disappears and the pellicle membranes become uplifted around the protruding tentacle. An epiplasmic collar differentiates around the growing tentacle whilst spheroid vesicles and solenocysts begin to accumulate in the surrounding cytoplasm.This investigation was supported by the J.S. Dunkerley Fellowship in Protozoology, awarded by the University of Manchester.     

Ultrastructural studies of the commensal suctorian,Choanophyra infundibulifera hartog

Summary Tentacle structure, movement and feeding of the commensal suctorian Choanophrya infundibulifera have been examined by light, scanning and transmission electron microscopy. The tentacles possess a flattened tip and rounded shaft externally, with a neck and root region internally. There is a microtubule canal consisting of 150 ring microtubules within which are 20–35 curved lamellae each containing about 20 microtubules. Novel structural features include pairs of short oblique arranged microtubules at the tip, and a collar of epiplasm in the neck region. No haptocysts are found in Choanophrya but the tentacle cytoplasm contains two types of inclusions named solenocysts and spherical vesicles. These features are discussed in relation to the processes of tentacle movement and feeding. The rapid longitudinal movements of the tentacles are described and compared to those of other suctorians and possible mechanisms are suggested. Ingestion in Choanophrya is described and several theories involving tentacle microtubules in the feeding process are examined.This investigation was supported by the J.S. Dunkerley Fellowship in Protozoology, awarded by the University of Manchester.     

The fine structure and function of the tentacle in Tokophrya infusionum

The feeding apparatus of Suctoria consists of long, thin, stiff tubes called tentacles. When a swimming prey attaches to the tip of the tentacle a number of events follow in rapid succession. The tentacle broadens, a stream of tiny granules starts to move upward at its periphery to the tip, the prey becomes immobilized and shortly thereafter the cytoplasm of the still living prey begins to flow through the center of the tentacle to the body of the predator. An electron microscope study of the tentacle in Tokophrya infusionum, a protozoan of the subclass Suctoria, has disclosed a number of structural details which help to clarify some of the mechanisms involved in this unusual way of feeding. Each tentacle is composed of two concentric tubes. The lumen of the inner tube is surrounded by 49 tubular fibrils most probably of contractile nature. In the inner tube the cytoplasm of the prey is present during feeding, and in the outer tube are small dense bodies. It was found that the dense bodies originate in the cytoplasm of Tokophrya. They have an elongate, missile-like appearance, pointed at one end, rounded at the other, and are composed of several distinct segments. At the tip of the tentacle they penetrate the plasma membrane, with their pointed ends sticking out. It is assumed that the missile-like bodies play a major role in the feeding process. Their composite structure suggests that they might contain a number of enzymes which most probably are responsible for the various events preceding the actual food intake.     

Comparative ultrastructure of catch tentacles and feeding tentacles in the sea anemone Haliplanella

TEM observations of catch tentacles revealed that the tentacle tip epidermis is filled with two size classes of mature holotrich nematocysts and a gland cell filled with electron-dense vesicles. Vesicle production is restricted to upper-middle and tentacle tip regions, whereas holotrich development occurs in the lower-middle and tentacle base regions. Thus, catch tentacles have a maturity gradient along their length, with mature tissues concentrated at the tentacle tip. Occasional feeding tentacle cnidae (microbasic p-mastigophores and basitrichs) and mucus gland cells occur in proximal portions of catch tentacles, but are phagocytized by amoeboid granulocytes and transported to the gastrodermis for further degradation. No feeding tentacle cnidae or mucus cells occur distally in catch tentacles. Unlike catch tentacles, feeding tentacles are homogeneous in structure along their length with enidocytes containing mature spirocysts, microbasic p-mastigophore or basitrich nematocysts distributed along the epithelial surface. Cnidoblasts are recessed beneath cnidocytes, occurring along the nerve plexus. Mucus gland cells and gland cells filled with electron-dense vesicles are present in feeding tentacles, distributed at the epithelial surface. Granular phagocytes are rare in the feeding tentacle tip, but common in the tentacle base.     

Calmodulin Localization and its Effects on Endocytic and Phagocytic Membrane Trafficking in Paramecium multimicronucleatum

ABSTRACT. In ciliates, calmodulin (CaM), as in other cells, has multiple functions, such as activation of regulatory enzymes and modulating calcium‐dependent cellular processes. By immunogold localization, CaM is concentrated at multiple sites in Paramecium. It is seen scattered over the cytosol, but bound to its matrix, and is concentrated at the pores of the contractile vacuole complexes and with at least three microtubular arrays. It was localized peripheral to the nine‐doublet microtubules of the ciliary axonemes. The most striking localization was on the akinetic side only of the cytopharyngeal microtubular ribbons opposite the side where the discoidal vesicles, acidosomes and the 100‐nm carrier vesicles bind and move. CaM was also present at the periphery of the postoral microtubular bundles along which the early vacuole moves and was associated with the cytoproct microtubules that guide the spent digestive vacuoles to the cytoproct. It was not found on the membranes of, or in the interior of nuclei, mitochondria, phagosomes, and trichocysts, and was only sparsely scattered over the cytosolic sides of discoidal vesicles, acidosomes, lysosomes, and digestive vacuoles. Together the associations with specific microtubular arrays and the effects of trifluoperazine and calmidazolium indicate that CaM is involved (i) in vesicle transport to the cytopharynx area for vacuole formation and subsequent vacuole acidification, (ii) in early vacuole transport along the postoral fiber, and (iii) in transporting the spent vacuole to the cytoproct. Higher CaM concentrations subjacent to the cell's pellicle and close to the decorated tubules of the contractile vacuole complex may support a role for CaM in ion traffic.     

Disruption of cellulose synthesis by isoxaben causes tip swelling and disorganizes cortical microtubules in elongating conifer pollen tubes

Summary.  In elongating pollen tubes of the conifer Picea abies (Norway spruce), microtubules form a radial array beneath the plasma membrane only at the elongating tip and an array parallel with elongation throughout the tube. Tips specifically swell following microtubule disruption. Here we test whether these radial microtubules coordinate cell wall deposition and maintain tip integrity as tubes elongate. Control pollen tubes contain cellulose throughout the walls, including the tip. Pollen tubes grown in the presence of isoxaben, which disrupts cellulose synthesis, are significantly shorter with a decrease in cellulose throughout the walls. Isoxaben also significantly increases the frequency of tip swelling, with no effect on tube width outside of the swollen tip. The decrease in cellulose is more pronounced in pollen tubes with swollen tips. The effects of isoxaben are reversible. Following isoxaben treatment, the radial array of microtubules persists beneath the plasma membrane of nonswollen tips, while this array is specifically disrupted in swollen tips. Microtubules instead form a random network throughout the tip. Growth in these pollen tubes is turgor driven, but the morphological changes due to isoxaben are not just the result of weakened cell walls since pollen tubes grown in hypoosmotic media are not significantly shorter but do have swollen tips and tubes are wider along their entire length. We conclude that the radial microtubules in the tip do maintain tip integrity and that the specific inhibition of cellulose microfibril deposition leads to the disorganization of these microtubules. This supports the emerging model that there is bidirectional communication across the plasma membrane between cortical microtubules and cellulose microfibrils. Received January 15, 2002; accepted August 3, 2002; published online March 11, 2003     

The Fine Structure of the Cinctum of Ellobiophrya conviva (Ciliophora: Peritricha)

Ellobiophrya conviva clasps tentacles of the bryozoan Bugula neritina with a ring-like structure formed from aboral extensions of its body that taper into two slender arms. The tips of the arms overlap and join to form a unique organelle, the bouton. Each arm contains a massive myoneme that splays out at the bouton. The bouton consists of the cupped tips of the arms and a cavity, which is filled with dense homogeneous material. Long digitations containing longitudinal microtubules at their periphery project from the inner surface of the tip of each arm into the cavity. Deep folds of pellicle with pores opening into their depths line the wall of the cavity. Conventional kinetosomes are not visible in the bouton, but circular or elliptical arrays of microtubules are found at the bases of digitations. The nonfunctional scopula of the adult is in a depression enclosed by pellicular folds. The bouton is distant from the scopula, but its fine structure somewhat resembles it, supporting Chatton and Lwoff's hypothesis that the cinctal arms carry parts of the scopula at their tips. The fine structure of the cinctum supports their suggestion that the cinctal arms are homologous to the spasmonemes of vorticellid peritrichs.     

The fine structure of the cinctum of Ellobiophrya conviva (Ciliophora: Peritricha).

Ellobiophrya conviva clasps tentacles of the bryozoan Bugula neritina with a ring-like structure formed from aboral extensions of its body that taper into two slender arms. The tips of the arms overlap and join to form a unique organelle, the bouton. Each arm contains a massive myoneme that splays out at the bouton. The bouton consists of the cupped tips of the arms and a cavity, which is filled with dense homogeneous material. Long digitations containing longitudinal microtubules at their periphery project from the inner surface of the tip of each arm into the cavity. Deep folds of pellicle with pores opening into their depths line the wall of the cavity. Conventional kinetosomes are not visible in the bouton, but circular or elliptical arrays of microtubules are found at the bases of digitations. The nonfunctional scopula of the adult is in a depression enclosed by pellicular folds. The bouton is distant from the scopula, but its fine structure somewhat resembles it, supporting Chatton and Lwoff's hypothesis that the cinctal arms carry parts of the scopula at their tips. The fine structure of the cinctum supports their suggestion that the cinctal arms are homologous to the spasmonemes of vorticellid peritrichs.     

Microtubules and microfilaments coordinate to direct a fountain streaming pattern in elongating conifer pollen tube tips

This study investigates how microtubules and microfilaments control organelle motility within the tips of conifer pollen tubes. Organelles in the 30-m-long clear zone at the tip of Picea abies (L.) Karst. (Pinaceae) pollen tubes move in a fountain pattern. Within the center of the tube, organelles move into the tip along clearly defined paths, move randomly at the apex, and then move away from the tip beneath the plasma membrane. This pattern coincides with microtubule and microfilament organization and is the opposite of the reverse fountain seen in angiosperm pollen tubes. Application of latrunculin B, which disrupts microfilaments, completely stops growth and reduces organelle motility to Brownian motion. The clear zone at the tip remains intact but fills with thin tubules of endoplasmic reticulum. Applications of amiprophosmethyl, propyzamide or oryzalin, which all disrupt microtubules, stop growth, alter organelle motility within the tip, and alter the organization of actin microfilaments. Amiprophosmethyl inhibits organelle streaming and collapses the clear zone of vesicles at the extreme tip together with the disruption of microfilaments leading into the tip, leaving the plasma membrane intact. Propyzamide and oryzalin cause the accumulation of membrane tubules or vacuoles in the tip that reverse direction and stream in a reverse fountain. The microtubule disruption caused by propyzamide and oryzalin also reorganizes microfilaments from a fibrillar network into pronounced bundles in the tip cytoplasm. We conclude that microtubules control the positioning of organelles into and within the tip and influence the direction of streaming by mediating microfilament organization.Electronic Supplementary Material Supplementary material is available in the online version of this article at Abbreviations APM Amiprophosmethyl - FITC Fluorescein isothiocyanate - LATB Latrunculin B     

The role of the motile tubular vacuole system in mycorrhizal fungi

Mycorrhizal fungi, to be effective for the plant, must be able to transfer mineral nutrient elements from sites of uptake at hyphal tips across various distances to the exchange region in the mycorrhiza. Vacuoles are likely to be important in this transport, since they contain elements of nutritional significance in abundance. In tip cells of hyphae of most fungi –- known to include three ectomycorrhizal basidiomycetes, an ericoid mycobiont, and two arbuscular mycorrhizal fungi –- the vacuoles form a motile tubular reticulum. The vacuoles are most active in hyphal tips, but non-motile vacuoles at a distance from the tip can be induced to become motile by environmental changes. Neither the tubular vacuolar reticulum nor its contents are properly preserved by conventional fixation and embedding. Vacuolar tubules are readily shown in vivo with fluorescent tracers, throughout the extramatrical mycelium and in outer hyphae of the sheath in eucalypt mycorrhizas synthesised with Pisolithus sp., but they have proved harder to label in field-collected ectomycorrhizas and ericoid mycorrhizas. Freeze-substitution does preserve the structure of vacuoles and vacuolar tubules, and careful anhydrous techniques allow them to be microanalysed, indicating high content of K and P in vacuoles of hyphal tips, and also in sheath and Hartig net of ectomycorrhizas. Vacuoles contain polyphosphate in diffuse, non-granular form. Polyphosphate is present right up to the tip region of hyphae as well as in sheath and Hartig net: thus important mineral nutrient elements are present at both ends of the long hyphal transport pathway. Exactly what happens in between, however, remains to be elucidated.     

The ultrastructure of zoospores ofAphanomyces euteiches and of their encystment and subsequent germination

Summary The ultrastructure ofAphanomyces euteiches during the periods of zoospore motility, encystment, and germination has been studied. The motile spore has two heterokont flagella inserted laterally into the groove of the zoospore body where each is attached to a kinetosome. The kinetosomes and flagella are anchored into the zoospore body by rootlets comprised of two rows of microtubules with up to 12 microtubules in the outer row and are attached by fine threads to a striate fiber bundle. Secondary microtubules are attached at right angles at regular intervals along the rootlets. An unidentified body, 1.25m in diameter, containing helical fibers 16 nm in diameter is present in each zoospore. This body is situated near the two kinetosomes on the side of the pyriform nucleus opposite the contractile vacuole. The Golgi complex is between the nucleus and the contractile vacuole. The latter is surrounded by a 0.5–1.0m wide zone of Golgi proliferated vesicles. Ribosomes are generally absent from this region. Endoplasmic reticulum containing tubules within the expanded cisternae are also present. Vesicles with striated electron opaque inclusions and vesicles containing a granular cortex and center that developed in previous stages of zoosporogenesis were also present. During encystment of the zoospore the latter vesicles disappear. The two flagella are shed at this time leaving a membrane-bounded granular knob protruding from each of the kinetosome terminal plates. The contractile vacuole becomes disorganized and the zoospore assumes a spherical shape. Cyst wall deposition begins immediately and is completed in 30 minutes. The spore begins to germinate 1 hour following initiation of encystment with the appearance of a bulge in the cyst wall which elongates into a germ tube. Mitotic nuclear division follows.Research supported by the College of Agricultural and Life Sciences Station Project No. 1281.Research assistant and Professor. The advice and assistance of G. A. deZoeten, G. R.Gaard, and S.Vicen are most gratefully acknowledged.     

Functional design of tentacles in squid: linking sarcomere ultrastructure to gross morphological dynamics

This paper offers a quantitative analysis of tentacle extension in squid that integrates several levels of structural organization. The muscular stalks of the two tentacles of squid are rapidly elongated by 70 per cent of resting length during prey capture. A typical duration of the extension is 30 ms in Loligo pealei (with a contracted tentacle length of 93 mm and a strike distance of about 37 mm). In a successful strike, the terminal clubs hit the prey and attach to it via arrays of suckers.A forward dynamics model is proposed for the extension of the tentacular stalk and the forward motion of the terminal club. The stalk is modelled as a longitudinal array of thin muscular discs with extensor muscle fibres oriented parallel to the disc planes. As a disc contracts radially, it lengthens because its volume is constant. The equations of motion for the linked system of discs were formulated and solved numerically. The inputs of the model are the dimensions of the tentacle, passive and active muscle properties such as Hill''s force–velocity relationship, myofilament lengths and activation of the muscle fibres. The model predicts the changing geometry of the tentacle, the pressure and stress distribution inside the tentacle and the velocity and kinetic energy distribution of the stalk and club. These predictions are in agreement with kinematic observations from high-speed films of prey capture. The model demonstrates also that the unusually short myosin filaments (reported range 0.5–0.9 micrometre) that characterize the extensor muscles are necessary for the observed extension performance. Myosin filament lengths typical for vertebrate sarcomeres (1.58 micrometre) would lead to a significant reduction in performance. In addition, the model predicts that, to maximize peak velocity of the terminal club, the myosin filaments should be longer at the base and shorter at the tip of the stalk (0.97 micrometre at the base and 0.50 micrometre at the tip for the tentacle size above). This results from differences in dynamic loading along the stalk. Finally, the model allows exploration of the effects of changes in the dimensions and mass of the tentacle and intrinsic speed of the myofilaments on the optimum myosin filament lengths.     

CYTOPLASMIC MICROTUBULE AND WALL MICROFIBRIL ORIENTATION IN ROOT HAIRS OF RADISH

The fine structure of young root hairs of radish was studied, with special attention to cytoplasm-wall relationships. Hairs up to 130 µ in length were examined after fixation of root tips in glutaraldehyde followed by osmium tetroxide. Microtubules occur axially aligned in the cytoplasm just beneath the plasmalemma, and extend from the base of the hair to within 2 to 3 µ of the tip. Poststaining with uranyl acetate and lead citrate clearly reveals in thin sections the presence of the two layers of cellulose microfibrils known from studies on shadowed wall preparations: an outer layer of randomly arranged microfibrils arising at the tip, and a layer of axially oriented microfibrils deposited on the inside of this layer along the sides. The youngest microfibrils of the inner, oriented layer first appear at a distance of about 25 µ from the tip. Although the microfibrils of the inner layer and the adjacent microtubules are similarly oriented, the oriented microtubules also extend through the 20- to 25-µ zone near the tip where the wall structure consists of random microfibrils. This suggests that the role of microtubules in wall deposition or orientation may be indirect.     

Metamorphosis in Tokophrya infusionum; an Electron-Microscope Study

SYNOPSIS. In Tokophrya infusionum metamorphosis from a ciliated swimming embryo to a sessile organism with a stalk, disc, and tentacles lasts only 3 minutes. The remarkable speed of meta-morphosis was clarified by an electron-microscope study of embryos before and during metamorphosis. Ultrathin sections have revealed that the embryo has at the anterior end of the body a number of specialized structures, such as dense bodies containing the precursor material for the disc and stalk, and microtubules which align the dense bodies into rows leading to pit-kite invaginations of the pellicle at the tip of the anterior end. At meta-morphosis the embryo settles down on this end and the precursor material is released thru the pits to the outside. At the same time the body of the embryo invaginates at this end, forming a cavity which becomes deeper and narrower until it acquires the shape of a channel. The 1st drops released from the dense bodies spread out on the substrate, forming the disc. The rest of the material, secreted into the channel, solidifies there to form the stalk. It seems obvious that the channel serves as a mold for the stalk, since after completion of the stalk the channel disappears. The stalk is structureless with no limiting membrane; it is outside the boundaries of the cell. Both the stalk and disc are extra-cellular organelles.
Of the new organelles appearing at metamorphosis, only the stalk and disc are formed de novo. The electron-microscope study disclosed that the embryo has internal parts of tentacles composed of a tube formed of microtubules. At the distal end of the microtubules is a ring of dense material. During metamorphosis the microtubules, together with the dense ring, grow out of the body, and along with them the pellicle and plasma membrane to form the external part of the tentacle.     

Organization of cytoskeleton during the tentacle contraction and cytostome movement in the dinoflagellate Noctiluca scintillans McCartney

Summary Electron microscopy of Noctiluca scintillans reveals that the cytoskeleton of the tentacle involved in the motor action of the prey capture consists of three characteristic elements: a deformable peripheral fibrillo-granular ectosarc, abundant underlying microtubules organized in several rows on the convex side, and helicoid filaments about 8 nm in diameter organized into striated myonemes. Microtubules of the external row are crossed-linked with each other by fibrous elements 5 nm in diameter and 10–15 nm long, their links with the second row result in a Y-shaped binding. Bonds of the other rows are linked to each other irregularly between those of the same row. Striated myonemes are regularly inserted between the rows of microtubules on the ectosarc and between its pleats, joining together in a knot of disarrayed filaments with multidirectional orientation in the central axis of the tentacle. Striation of myonemes is based on an alternation of thick striae (TS) 40 nm wide with a periodicity of about 200 nm, and of some intermediary fine striae (FS) 10 nm wide. The events during tentacle contraction are: (1) Rotation of the tentacle, bringing the convex side to the inner side of it. Here, large numbers of microtubules have been visualized by optical immunocytochemistry after labelling with Paramecium antitubulin antiserum. (2) Increase of pleat amplitude (200–300 nm to 600 nm) in concomitance with a decrease of its period (500–700 nm to 250 nm). (3) Apparent modification of the microtubule orientation. (4) Transformation of some TS in several FS without modification of the striation periodicity.Near the cytostome, the cytoskeleton consists of a number quantity of microtubules underlying a non-pleated ectosarc and long tracts of contractile myonemes formed by 6-nm helicoid filaments linking the internal side of the cytostome of the supporting rod. Semirelaxed myonemes show an alternation of fine striae (FS) 35 nm wide between two clear areas (CA) with a periodicity of about 300 nm, plus an incipient dark area (DA) lying between them; together they are transformed into a thick stria (TS) during maximal contraction; the striation periodicity thus decreases by one half. These two systems are compared with one another and with other motile systems.     

Observations on tubules derived from the endoplasmic reticulum in leaf glands ofPhaseolus vulgaris

Summary Tubular systems present in bean leaf glands have been studied electron microscopically. Ordered arrays of small tubules (290 Å in diameter) arise from the endoplasmic reticulum in early stages of gland development and remain connected to it. Subsequently larger tubules (560–660 Å in diameter) appear among the smaller tubules and gradually replace many of them. The large tubules are not connected to the endoplasmic reticulum. They contain an electron dense material and their walls exhibit a patterned substructure. In older gland cells the bundles of large tubules run randomly through the cytoplasm. The relationship of the two types of gland tubules to conventional microtubules has been examined morphologically and experimentally. The small tubules have larger diameters and thicker walls than microtubules. Neither type of gland tubule is affected by low temperature or colchicine, or, in thin sections, by pepsin digestion. This suggests that these tubules are not closely related chemically to either cytoplasmic or ciliary microtubules. The two systems of tubules are closely associated with prominent protein vacuoles in the gland cells, but are not directly connected to them.This work was supported in part by grant no. GB-6161 from the National Science Foundation.     

Membrane/microtubule tip attachment complexes (TACs) allow the assembly dynamics of plus ends to push and pull membranes into tubulovesicular networks in interphase Xenopus egg extracts

We discovered by using high resolution video microscopy, that membranes become attached selectively to the growing plus ends of microtubules by membrane/microtubule tip attachment complexes (TACs) in interphase- arrested, undiluted, Xenopus egg extracts. Persistent plus end growth of stationary microtubules pushed the membranes into thin tubules and dragged them through the cytoplasm at the approximately 20 microns/min velocity typical of free plus ends. Membrane tubules also remained attached to plus ends when they switched to the shortening phase of dynamic instability at velocities typical of free ends, 50-60 microns/min. Over time, the membrane tubules contacted and fused with one another along their lengths, forming a polygonal network much like the distribution of ER in cells. Several components of the membrane networks formed by TACs were identified as ER by immunofluorescent staining using antibodies to ER-resident proteins. TAC motility was not inhibited by known inhibitors of microtubule motor activity, including 5 mM AMP-PNP, 250 microM orthovanadate, and ATP depletion. These results show that membrane/microtubule TACs enable polymerizing ends to push and depolymerizing ends to pull membranes into thin tubular extensions and networks at fast velocities.     

Tea2p kinesin is involved in spatial microtubule organization by transporting tip1p on microtubules

The positioning of growth sites in fission yeast cells is mediated by spatially controlled microtubule dynamics brought about by tip1p, a CLIP-170-like protein, which is localized at the microtubule tips and guides them to the cell ends. The kinesin tea2p is also located at microtubule tips and affects microtubule dynamics. Here we show that tea2p interacts with tip1p and that the two proteins move with high velocity along the microtubules toward their growing tips. There, tea2p and tip1p accumulate in larger particles. Particle formation requires the EB1 homolog, mal3p. Our results suggest a model in which kinesins regulate microtubule growth by transporting regulatory factors such as tip1p to the growing microtubule tips.     

Reconciling the bizarre inheritance of microtubules in complex (euglenid) microeukaryotes

We introduce a hypothetical model that explains how surface microtubules in euglenids are generated, integrated and inherited with the flagellar apparatus from generation to generation. The Euglenida is a very diverse group of single-celled eukaryotes unified by a complex cell surface called the "pellicle", consisting of proteinaceous strips that run along the longitudinal axis of the cell and articulate with one another along their lateral margins. The strips are positioned beneath the plasma membrane and are reinforced with subtending microtubules. Euglenids reproduce asexually, and the two daughter cells inherit pellicle strips and associate microtubules from the parent cell in a semi-conservative pattern. In preparation for cell division, nascent pellicle strips develop from the anterior end of the cell and elongate toward the posterior end between two parent (mature) strips, so that the total number of pellicle strips and underlying microtubules is doubled in the predivisional cell. Each daughter cell inherits an alternating pattern of strips consisting of half of the nascent strips and half of the parent (mature) strips. This observation combined with the fact that the microtubules underlying the strips are linked to the flagellar apparatus created a cytoskeletal riddle: how do microtubules associated with an alternating pattern of nascent strips and mature strips maintain their physical relationship to the flagellar apparatus when the parent cell divides? The model of microtubular inheritance articulated here incorporates known patterns of cytoskeletal semi-conservatism and two new inferences: (1) a multigenerational "pellicle microtubule organizing center" (pMTOC) extends from the dorsal root of the flagellar apparatus, encircles the flagellar pocket, and underpins the microtubules of the pellicle; and (2) prior to cytokinesis, nascent pellicle microtubules fall within one of two "left/right" constellations that are linked to one of the two new dorsal basal bodies.