Analysis of Different Methodological Approaches to Measuring Microtubule Length in the Cytoplasm of Cultured Cells

It is generally assumed that microtubules in tissue culture cells extend from the centrosome to cell periphery, and the length of individual microtubules averages several dozens of microns. However, direct electron-microscopic measurements have cast some doubt on this assumption. In this study, the average length of microtubules in cultured Vero cells was estimated using a combined approach. The length of free cytoplasmic and centrosomal microtubules was determined by means of electron microscopy in serial sections; concurrently, the length of free microtubules in the lamella was measured in preparations stained with tubulin antibodies (an indirect immunofluorescent method), by tracing saltatory particle movements along the microtubules in living cells. According to the data of immunofluorescent microscopy, microtubule length in the lamella averaged 4.57 ± 3.69 m. However, since two or more microtubules can overlap, their length may be slightly overestimated by this method. On the other hand, saltatory movements are easy to monitor and measure fairly accurately, but their range may be shorter than the actual microtubule length because of a limited processiveness of motors (kinesin and dynein). On average, the trajectories of saltatory movements in living cells were 3.85 ± 0.72 m long. At the electron-microscopic level, microtubule length was analyzed using pseudo-three-dimensional reconstructions of the microtubule systems around the centrosome and in the lamella. The length of free microtubules in the lamella reached 18 m, averaging 3.33 ± 2.43 m; the average length of centrosomal microtubules was 1.49 ± 0.82 m. Good correspondence between the data on microtubule length and arrangement obtained by different methods allows the conclusion that most of the free microtubules in Vero cells actually have a length of 2–5 m; i.e., they are much shorter than the cell radius (about 25 m). Microtubules extending from the centrosome are shorter still and do not reach the cell periphery. Thus, most microtubules in the lamella of Vero cells are free and their ordered arrangement is not associated with their attachment to the centrosome.     

The organization of cortical microtubule arrays in the radish root hair

Summary Cortical microtubule arrays in the radish root hair were analyzed from reconstructions of serial ultra-thin sections in order to test extant hypotheses concerning the role of microtubules in the deposition of oriented microfibrils of cellulose. Passing away from the tip, root hairs exhibit a transition from random to oriented deposition of microfibrils at approximately 25 m. Along the root hair, passing back from the tip, the microtubules: a) increase in number to a plateau at 25 m; b) change their length profiles from approximately 60% less than 1 m long in the hair tip to approximately 40% less than 1 m long at 60 m; c) maintain a constant pattern of angular deviation from the long axis, which is similar to the deviation pattern of the oriented wall fibrils; d) maintain a constant (approximately 70% of tubules) close (within 50 nm) proximity to the plasma membrane (PM); e) maintain a low (approximately 20%) degree of inter-microtubule proximity (i.e., within 50 nm of one another); f) show evidence for some variable long range (>50 nm) association. Fixation with glutaraldehyde in a complete microtubule polymerization medium (MTPM), or pretreatment with cytochalasin B cause an approximate twofold increase in 1. the proportion of long microtubules in the tip region and 2. microtubules within 50 nm of one another. Fixation in incomplete MTPM (without GTP) produces results similar to phosphate buffer controls. Alternative explanations for these results are examined. A new hypothesis accounting for microtubule involvement in oriented microfibril deposition is described.     

Effects of colchicine and amiprophos-methyl on microfibril arrangement and cell shape inAdiantum protonemal cells

Summary 5 mM colchicine and 1 g/ml amiprophos-methyl, known antimicrotubule agents, were applied to fernAdiantum protonemata under red light. Both drugs caused microtubule disruption and subsequent apical swelling of protonemal cells after certain lag periods. While the lag periods for the onset of microtubule disruption after application of the two drugs were different (within 15 minutes in amiprophos-methyl, 1 hour in colchicine), the lag periods of apical swelling after microtubule disruption were nearly the same (approx. 70 minutes). The results suggest that the apical swelling is a consequence of microtubule disruption.In cells examined 1 hour after microtubule disruption by either drug, the microfibril arrangement of the innermost layer of the cell wall was random at the tip, transverse in the subapical region, and roughly longitudinal in the cylindrical region. This pattern of microfibrils was similar to that of untreated cells in which the microtubules show a similar arrangement (Murata and Wada 1989). Surprisingly, even after approx. 4 hours of microtubule disruption, when apical swelling had occurred in most cells, the pattern of microfibril deposition was not altered. The role of microtubules in oriented microfibril deposition and the mechanism of control of cell shape are discussed.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - MT(s) microtubule(s) - PBS phosphate buffered saline     

The effects of microtubule and microfilament disrupting agents on cytoskeletal arrays and wall deposition in developing cotton fibers

Summary The effects of various cytoskeletal disrupting agents (cholchicine, oryzalin, trifluralin, taxol, cytochalasins B and D) on microtubules, microfilaments and wall microfibril deposition were monitored in developing cotton fibers, using immunocytochemical and fluorescence techniques. Treatment with 10^–4 M colchicine, 10^–6 M trifluralin or 10^–6 M oryzalin resulted in a reduction in the number of microtubules, however, the drug-stable microtubules still appear to influence wall deposition. Treatment with 10^–5 M taxol increased the numbers of microtubules present within 15 minutes of application. New microtubules were aligned parallel to the existing ones, however, some evidence of random arrays was observed. Microtubules stabilized with taxol appeared to function in wall organization but do not undergo normal re-orientations during development. Microtubule disrupting agent had no detectable affect on the microfilament population. Exposure to either 4×10^–5 M cytochalasin B or 2×10^–6M cytochalasin D resulted in a disruption of microfilaments and a re-organization of microtubule arrays. Treatment with either cytochalasin caused a premature shift in the orientation of microtubules in young fibers, whereas in older fibers the microtubule arrays became randomly organized. These observations indicate that microtubule populations during interphase are heterogeneous, differing at least in their susceptibility to disruption by depolymerizing agents. Changes in microtubule orientation (induced by cytochalasin) indicate that microfilaments may be involved in regulating microtubule orientation during development.     

The cytoskeleton of Cobaea seed hairs:

The cell wall of Cobaea scandens seed hairs developed in a characteristic sequence, with the deposition of a cellulose thread onto a pectic swelling layer was the final event. The cellulose thread was intracellularly accompanied by a band of 10–18 microtubules. During the formation of the swelling layer the microtubules were homogeneously distributed; they ran circumferentially normal to the cell axis. When cellulose-thread formation started, the microtubules became arranged in a helical band. The density of the microtubules varied during the different phases of development. The highest density was observed before cellulosethread formation and ranged from 6–15 m·m^-2. The length of the microtubules, 20–30 m, was determined by direct measurements, as well as estimated from the total microtubular length in a given area and the counted free ends. With the indirect immunofluorescence technique the microtubules of the band stained inhomogeneously. Those which were located at the edges of the band fluoresced more intensely than those of the central part. Attempts to visualize actin filaments in the hair cells with rhodaminyl-conjugated phalloidin resulted in a homogeneous staining of the area of the microtubular band, indicating that actin filaments may be present in this region. Though, in thin sections and dry-cleaved cells, filamentous structures were observed between the microtubules, caution is expressed that the observed fluorescence was, indeed, due to actin filaments. The role of the filamentous structures is discussed with respect to formation and maintenance of the microtubular band. Microtubules apparently did not cross coated pits which were visualized in the plasma membrane through the dry-cleaving technique.Abbreviations IFT indirect immunofluorescence technique - RP rhodaminyl-conjugated phalloidin - SEM scanning electron microscopy     

Origin of kinetochore microtubules in Chinese hamster ovary cells

We have attempted to determine whether chromosomal microtubules arise by kinetochore nucleation or by attachment of pre-existing microtubules. The appearance of new microtubules was investigated in vivo on kinetochores to which microtubules had not previously been attached. The mitotic apparatus of Chinese hamster ovary cells was reconstructed in three dimensions from 0.25 m thick serial sections, and the location of chromosomes, kinetochore outer disks, centrioles, virus-like particles and microtubules determined. Central to the interpretation of these data is a synchronization scheme in which cells entered Colcemid arrest without forming mitotic microtubules. Cells were synchronized by the excess thymidine method and exposed to 0.3 g/ml Colcemid for 8 h. Electron microscopic examination showed that this Colcemid concentration eliminated all microtubules. Mitotic cells were collected by shaking off, and cell counts showed that over 95% of the cells were in interphase when treatment began and thus were arrested without the kinetochores having been previously attached to microtubules. Cells were then incubated in fresh medium and fixed for high voltage electron microscopy at intervals during recovery. — In early stages of recovery, short microtubules were observed near and in contact with kinetochores and surrounding centrioles. Microtubules were associated with kinetochores facing away from centrosomes and far from any centrosomal microtubules, and thus were not of centrosomal origin. At a later stage of recovery, long parallel bundles of microtubules, terminating in the kinetochore outer disk, extended from kinetochores both toward and away from centrosomes. Because microtubules had never been attached to kinetochores, the possibility that kinetochore microtubles were initiated by microtubule stubs resistant to Colcemid was eliminated. Therefore we conclude that mammalian kinetochores can initiate microtubules in vivo, thus serving as microtubule organizing centers for the mitotic spindle, and that formation of kinetochore-microtubule bundles is not dependent on centrosomal activity.     

Microtubule organization in sperm cells in the pollen tubes ofBrassica oleracea L.

Summary Microtubules tightly cross-linked into bundles are described in the sperm cells ofBrassica oleracea pollen tubes. The sperm cells are lobed and tailed and the microtubule bundles are often located in these parts of the cells. In the present paper we suggest that the cross-linked microtubule organization could determine an intertubular sliding, probably generating a motility system that propels the sperm cells through the tube.Abbreviations GC generative cell - Mfs microfilaments - Mts microtubules - SC sperm cell - VC vegetative cell - VN vegetative nucleus     

A model for the pattern of deposition of microfibrils in the cell wall of Glaucocystis

Freeze-fracturing of Glaucocystis nostochinearum Itzigsohn cells during cell-wall microfibril deposition indicates that unidirectionally polarized microfibril ends are localized in a zone of synthesis covering about 30% of the sarface area of the plasma membrane. Within this zone there are about 6 microfibril ends/m² cell surface. It is proposed that microfibrils are generated by the passage of their tips over the cell surface and that the pattern of microfibril organization at the poles of the cells, in which microfibrils of alternate layers are interconnected at 3 rotation centres, results directly from the pattern of this translation of microfibril tips. In a model of the deposition pattern it is proposed that the zone of synthesis may split into 3 sub-zones as the poles are approached, each sub-zone being responsible for the generation of one rotation centre. It is demonstrated that the microfibrillar component of the entire wall could be generated by the steady translation of the microfibril tips (at which synthesis is presumed to occur) over the cell surface at a rate of 0.25–0.5 m min^-1. Microcinematography indicates that the protoplast rotates during cell-wall deposition, and it is proposed that this rotation may play a role in the generation of the microfibril deposition pattern.     

Induction of multipolar mitoses in cultured cells: Decay and restructuring of the mitotic apparatus and distribution of centrioles

During recovery after a long (up to 12 h) treatment of pig embryo culture cells (PK) with nocodazole at concentrations of 0.02 g/ml and 0.2 g/ml all c-metaphase cells divide normally into two daughter cells. During recovery after a short (1–4 h) treatment with 0.6 g/ml nocodazole only multipolar mitoses (as a rule tripolar) arise. At the ultrastructural level, the increasing nocodazole concentration leads to progressive disruption of the mitotic spindle. At a nocodazole concentration of 0.2 g/ml kinetochores are not associated with microtubules. At a nocodazole concentration of 0.6 g/ml there are no microtubules around the centrosomes, and in every cell one of the two diplosomes disintegrates. In tripolar telophase centrioles are distributed among the spindle poles generally in a 2:2:0 pattern. Mother and daughter centrioles are always disoriented but not separated. The centriole-free pole contains a cloud of electron-dense material. During tripolar division two of the three daughter cells mainly fuse shortly after telophase forming one binucleate cell. Thus a multipolar mitosis arises as a result of the uncoupling of mother centrioles and spindle microtubules, but not of the duration of the c-mitotic arrest. Centriole-free poles account for the divergence of chromosomes, but mainly they are unable to ensure the normal cytokinesis of daughter cells.by M. Trendelenburg     

Temporal and spatial changes of cellulose synthesis inClosterium acerosum (Schrank) Ehrenberg during cell growth

The amount and distribution of wall microfibril synthesis were investigated in the cell-division cycle ofClosterium acerosum. Electron-microscopic examination and a methylation analysis of alkali-extracted wall fragments showed that alkali-extracted wall was mainly composed of microfibrils and that the microfibrils ofC. acerosum were 4-linked glucans, i.e., cellulose. Cellulose synthesis was measured as incorporation of¹⁴C, fed to cells as NaHCO₃, into extracted wall fragments. Extensive cellulose synthesis was coincident with septum formation, continued for more than 6 h and then ceased. It was found by microautoradiography that cellulose synthesis after cell division was essentially restricted to the expanding new semicells. Such a restricted distribution of cellulose synthesis was maintained for more than 6 h after septum formation, i.e., for more than 2 h after the cessation of expansion; afterwards, cellulose synthesis in some, but not all, cells became extended to the old semicells, and then ceased. Considerable cellulose synthesis also took place in the band-like expanding part of non-divided cells, indicating that cell division was not necessarily required for the induction of cellulose synthesis and the latter was coupled with cell expansion. Extension of cellulose synthesis to old semicells was brought about in divided cells by treatment with 3 mM colchicine, 28 M vinblastine, 50 M isopropyl-N-phenylcarbamate or 1 M isopropyl-N(3-chlorophenyl)carbamate, indicating that microtubules are involved in the limitation of cellulose synthesis to the new semicells.Abbreviations CIPC isopropyl-N(3-chlorophenyl)carbamate - DPO 2,5-diphenyloxazole - IPC isopropyl-N-phenylcarbamate     

The fine structure of the olfactory tract in the teleost Carassius carassius L.

Summary Electronmicrographic montages of the olfactory tract at two levels in each of two fish (Carassius carassius L.) were constructed and fibre diameters measured using a Zeiss TGZ 3 particle size analyzer. Medial and lateral tract divisions, rhinocele and dorsal tela were identified. Ciliated ependymal cells line the rhinocele. Meninges form the outer covering of both tract divisions and the tela roofing the central canal.The lateral tract consists of 10–14 fasciculi in which myelinated nerve fibres are prominent. These fibres range in diameter between 0.2 and 1.8 (mean 0.7 ) consistent with conduction velocities averaging 0.6 m/sec recorded in the carp lateral olfactory tract.The medial division of the olfactory tract contains two larger fasciculi within which are numerous fine unmyelinated nerve fibres (mean diameter 0.17 ) arranged in bundles partly enveloped by glial cell processes. Myelinated nerve fibres are unevenly distributed within both fasciculi and have mean diameters of 0.6 .An interesting observation is the consistent presence of synapses within the largest bundle of the medial tract at all levels.Supported by Grant 5 Ro5 TW00154-03 from the National Institutes of Health, United States Public Health Service.The authors are indebted to the Fisheries and Wildlife Department who generously provided the fish from Snob's Creek Fish Hatchery, and gratefully acknowledge the technical assistance of Mr. T. Armitage, Mr. J. Simmons and Miss D. Harrison.     

Possible involvement of membrane fluidity in helicoidal microfibrillar orientation in the coenocytic green alga,Boergesenia forbesii

Summary Microfibrillar textures and orientation of cellulose microfibrils (MFs) in the coenocytic green alga,Boergesenia forbesii, were investigated by fluorescence and electron microscopy. Newly formed aplanosporic spherical cells inBoergesenia start to form cellulose MFs on their surfaces after 2 h of culture at 25°C. Microfibrillar orientation becomes random, fountain-shaped, and helicoidal after 2, 4, and 5 h, respectively. The fountain orientation of MFs is usually apparent prior to helicoidal MF orientation and thus may be considered to initiate helicoid formation. Microfibrils continue to take on the helicoidal arrangement during the growth ofBoergesenia thallus. The helicoidal orientation of MFs occurs through gradual counterclockwise change in MF deposition by terminal complexes (TCs) viewed from inside the cell. On the dorsal side of curving TC impressions in helicoidal texture formation on a freeze-fractured plasma membrane, the aggregation of intramembranous particles (IMPs) occurs. Membrane flow may thus possibly affect the regulation of helicoidal orientation inBoergesenia. Following treatment with 3 M amiprophos-methyl (APM) or 1 mM colchicine, cortical microtubules (MTs) completely disappear within 24 h but helicoidal textures formation is not affected. With 15 M cytochalasin B or 30 M phalloidin, however, the helicoidal orientation of MFs becomes random. Treatment with CaCl₂ (10 mM) causes the helicoidal MF orientation of cells to become random, but co-treatment with N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide (W-7) (100 mM) prevents this effect, though W-7 has no effect on the helicoidal MF formation. It thus follows that MF orientation inBoergesenia possibly involves actin whose action may be regulated by calmodulin.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - IMP intramembranous particle - MF microfibril - MT microtubule - TC terminal complex; W-7 N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide     

Endocytosis in rat cultured astrocytes is inhibited by unconjugated bilirubin

Excessive hyperbilirubinemia can cause irreversible neurological damage in the neonatal period. However, the complete understanding of the pathogenesis of unconjugated bilirubin (UCB) encephalopathy remains a matter of debate. This study investigates whether UCB inhibits the endocytosis of cationized ferritin (CF) by cultured rat astrocytes. The relationship between endocytosis and MTT reduction, as well as changes on tubulin and glial fibrillary acidic protein (GFAP) assembly, were also evaluated. Inhibition of endocytosis was complete in the presence of 171 M UCB, while a marked decrease of CF labeling was noticed for 86 M UCB. In addition, MTT reduction was inhibited by 60 to 76% as UCB concentrations changed from 17 to 171 M, while alterations on both GFAP and microtubule morphology were only achieved by cell exposure to 171 M UCB. These findings indicate that inhibition of CF endocytosis in rat cortical astrocytes by UCB is a concentration-dependent process that appears to be primarily related to a direct effect on the cell membrane and not to any alteration of cytoskeletal microtubules and intermediate filaments.     

The fine structure of a microplate-microtubule array,microfilaments and polyhedral body associated microtubules in several species of Anabaena

A microplate-microtubule array was observed in Anabaena sp. (B-378). This structure consists of an arched plate, about 8 nm thick, and various microtubules, 12 nm in diameter and 50 nm long, arranged in rows. The microtubules project at right angles from one side of the plate into the cytoplasm or towards the plasma membrane. Up to twelve microplate-microtubule arrays were observed in a single section of a cell.Microfilaments, about 2.8 nm in diameter and of undetermined length, were observed in four isolates of Anabaena. The microfilaments were always found in bundles, which varied in size, up to 0.63 m across and 0.91 long.Microtubules, 10 nm in diameter and about 150 nm in length, were observed associated with one facet of polyhedral bodies in 8 out of 20 isolates of Anabaena. The microtubules occurred in groups of up to 20 or more, and were always oriented with the long axis parallel to a facet of a polyhedral body. In cross section, the microtubules had an electron transparent lumen 5 nm wide and a wall 2.5 nm thick.These structures are compared to previously deseribed microtubules and microfilaments.     

Phosphate-limited growth of Chromatium vinosum in continuous culture

Chromatium vinosum DSM 185 was grown in continuous culture at a constant dilution rate of 0.071 h^-1 with sulfide as the only electron donor. The organism was subjected to conditions ranging from phosphate limitation (S _R-phosphate=2.7 M and S _R-sulfide=1.8 mM) to sulfide limitation (S _R-phosphate=86 M and S _R-sulfide=1.8 mM). At values of S _R-phosphate below 7.5 M the culture was washed out, whereas S _R-phosphate above this value resulted in steady states. The saturation constant (K ) for growth on phosphate was estimated to be between 2.6 and 4.1 M. The specific phosphorus content of the cells increased from 0.30 to 0.85 mol P mg^-1 protein with increasing S _R-phosphate. The specific rate of phosphate uptake increased with increasing S _R-phosphate, and displayed a non-hyperbolic saturation relationship with respect to the concentration of phosphate in the inflowing medium. Approximation of a hyperbolic saturation function yielded a maximum uptake rate (V _max) of 85 nmol P mg^-1 protein h^-1, and a saturation constant for uptake (K _t) of 0.7 M. When phosphate was supplied in excess 8.5% of the phosphate taken up by the cells was excreted as organic phosphorus at a specific rate of 8 nmol P mg^-1 protein h^-1.Non-standard abbreviations BChla bacteriochlorophyll a - D dilution rate; _max, maximum specific growth rate - maximum specific growth rate if the substrate were not inhibitory - K saturation constant for growth on phosphate - V _max maximum rate of phosphate uptake - K _i saturation constant for phosphate uptake - K _i inhibition constant for growth in the presence of sulfide - S _R concentration of substrate in the inflowing medium     

Optimization of in vivo tumor targeting in SCID mice with divalent forms of 741F8 anti-c-erbB-2 single-chain Fv: effects of dose escalation and repeated i.v. administration

Single-chain Fv molecules in monovalent (sFv) and divalent [(sFv')₂] forms exhibit highly specific tumor targeting in mice as a result of their small size and rapid systemic clearance. As a consequence, there is a rapid reversal of the sFv blood/tumor gradient, resulting in diminished retention of sFv species in tumors. In this report we investigate two distinct strategies, dose escalation and repetitive intravenous (i.v.) dosing, aiming to increase the absolute selective retention of radiolabeled anti-c-erbB-2¹²⁵I-741F8 (sFv')₂ in c-erbB-2-overexpressing SK-OV-3 tumors in mice with severe combined immunodeficiency (SCID). A doseescalation strategy was applied to single i.v. injections of¹²⁵I-741F8 (sFv')₂. Doses from 50 g to 1000 g were administered without a significant decrease in tumor targeting or specificity. High doses resulted in large increases in the absolute retention of¹²⁵I-741F8 (sFv')₂. For example, raising the administered dose from 50 g to 1000 g increased the tumor retention 24 h after injection from 0.46 g/g to 9.5 g/g, and resulted in a net increase of greater than 9 /g. Over the same dose range, the liver retention rose from 0.06 g/g to 1 g/g, and resulted in a net increase of less than 1 g/g. The retention of 9.5 g/g in tumor 24 h fllowing the 1000-g dose of (sFv')₂ was comparable to that seen 24 h after a 50-g dose of¹²⁵I-741F8 IgG, indicating that the use of large doses of (sFv')₂ may partially offset their rapid clearance. When two doses were administered by i.v. injection 24 h apart, the specificity of delivery to tumor observed after the first dose was maintained following the second injection. Tumor retention of¹²⁵I-741F8 (sFv')₂ was 0.32 g/g at 24 h and 0.22 g/g at 48 h following a single injection of 20 g/g, while 0.04 g/ml and 0.03 g/ml were retained in blood at the same assay times. After a second 20-g injection at the 24-h assay time, tumor retention increased to 0.49 g/g, and blood retention was 0.06 g/ml, at the 48-h point. These results suggest that multiple high-dose administrations of radiolabeled 741F8 (sFv')₂ may lead to the selective tumor localization of therapeutic radiation doses.Supported by National Cancer Institute (NCI) National Cooperative Drug Discovery Group grant U01 CA51880, CA06927, an appropriation from the Commonwealth of Pennsylvania, and the Bernard A. and Rebecca S. Bernard Foundation     

Establishing and maintaining axial growth: wall mechanical properties and the cytoskeleton

Organ morphology depends on cell placement and directional cell expansion. Microtubules are involved in both of these processes so genetic approaches to understand the role microtubules play in organ expansion are not straightforward. Our use of the temperature-sensitive mor1-1 mutants led to the surprising discovery that Arabidopsis thaliana (L.) Heynh. root cells can establish and maintain transverse cellulose texture without well organized microtubule arrays. This work also demonstrated that cells can lose the ability to expand anisotropically without losing transversely oriented cellulose microfibrils. We suggest that microtubule disruption affects the cells ability to generate long cellulose microfibrils, which may be essential for achieving growth anisotropy. Thus organ shape may depend not only on the orientation but also on the relative length of cellulose microfibrils during axis establishment and growth. More recent work has shown an important correlation between microtubule organization and the deposition patterns of the glycosylphosphatidylinositol (GPI)-anchored wall protein COBRA. Loss of microtubule organization is associated with the dissipation of transverse banding patterns of COBRA, suggesting that COBRAs function in maintaining anisotropic expansion may be microtubule-dependent.     

Progress in understanding the role of microtubules in plant cells

Microtubules have long been known to play a key role in plant cell morphogenesis, but just how they fulfill this function is unclear. Transverse microtubules have been thought to constrain the movement of cellulose synthase complexes in order to generate transverse microfibrils that are essential for elongation growth. Surprisingly, some recent studies demonstrate that organized cortical microtubules are not essential for maintaining or re-establishing transversely oriented cellulose microfibrils in expanding cells. At the same time, however, there is strong evidence that microtubules are intimately associated with cellulose synthesis activity, especially during secondary wall deposition. These apparently conflicting results provide important clues as to what microtubules do at the interface between the cell and its wall. I hypothesize that cellulose microfibril length is an important parameter of wall mechanics and suggest ways in which microtubule organization may influence microfibril length. This concept is in line with current evidence that links cellulose synthesis levels and microfibril orientation. Furthermore, in light of new evidence showing that a wide variety of proteins bind to microtubules, I raise the broader question of whether a major function of plant microtubules is in modulating signaling pathways as plants respond to sensory inputs from the environment.     

Feeding in the rotifer Brachionus calyciflorus

Summary The laboratory feeding behavior of Brachionus calyciflorus varies depending upon the type of food cell available in suspension. When feeding on the yeast Rhodotorula glutinis, rotifers show a continuous increase in ingestion with increased cell density between 0.01 and 1000 g dry weight ml^-1. Effective clearance rates drop from ca. 50 l animal^-1 h^-1 to less than 0.5 l animal^-1 h^-1 over this food density range. When feeding on Englena gracilis, B. calyciflorus ingestion rates are constant between 1.0 and 100 g ml^-1 of available food, averaging close to 25 ng animal^-1 h^-1. The decrease in clearance rate is more striking than with R. glutinis, dropping from 45 l animal^-1 h^-1 at 0.1 g ml^-1 to 0.13 l animal^-1 h^-1 at 100 g ml^-1. Differences between the patterns obtained with the two food types indicate fundamental dissimilarities in the feeding behavior of this rotifer species when presented with these different foods.     

Re-organization of microtubules during preprophase band development inAdiantum protonemata

Summary Microtubule organization during preprophase band development was investigated using immunofluorescence microscopy in filamentous protonemal cells (approx. 600 m in length, 20 m in width) ofAdiantum capillus-veneris L. Protonemata pre-cultured under red light were transferred to continuous blue light or total darkness to induce synchronous cell division. Preprophase bands were found under both light conditions. In an early stage of development, the preprophase band which is transverse to the cell axis overlapped with an interphase cortical array of microtubules which is random or parallel to the cell axis. The interphase cortical array disappeared thereafter. While the width of the preprophase band became narrow during development under dark conditions, under blue light conditions it did not.Spatial and temporal aspects of the disappearance of the interphase cortical array of microtubules were also investigated. The interphase cortical array began to disappear at nearly the same time as the beginning of preprophase band formation. Under blue light, the disruption of cortical microtubules started at approx. 150 m from the tip (approx. 120 m from the nucleus), and spread toward the tip as far as the nuclear region and toward the base to an area approx. 300–400 m from the tip. Cortical microtubules remained in the basal part of the protonema. The pattern of disappearance between the tip and nucleus could not be determined. Under dark conditions, the pattern of the disappearance of cortical microtubules was somewhat different in many cells from that encountered with exposure to blue light. Microtubules first re-oriented from longitudinal to transverse, and then gradually disappeared. In some cells, the pattern of disappearance was similar to that observed under blue light.Abbreviations DAPI 4, 6-diamidino-2-phenylindole - ICM interphase cortical microtubules - PBS phosphate buffered saline - PPB preprophase band - MT microtubule