Flagellar protein dynamics in Chlamydomonas.

Cilia and flagella appear to be stable, terminal, microtubule-containing organelles, but they also elongate and shorten in response to a variety of signals. To understand mechanisms that regulate flagellar dynamics, Chlamydomonas cells with nongrowing flagella were labeled with (35)S, and flagella and basal body components were examined for labeled polypeptides. Maximal incorporation of label into the flagella occurred within 3 h. Twenty percent of the flagellar polypeptides were exchanged. These included tubulins, dyneins, and 80 other axonemal and membrane plus matrix polypeptides. The most stable flagellar structure is the PF-ribbon, which comprises part of the wall of each doublet microtubule and is composed of tubulin and three other polypeptides. Most (35)S was incorporated into the high molecular weight ribbon polypeptide, rib240, and little, if any, (35)S is incorporated into PF-ribbon-associated tubulin. Both wild-type (9 + 2) and 9 + 0 flagella, which lack central microtubules, exhibited nearly identical exchange patterns, so labeling is not due to turnover of relatively labile central microtubules. To determine if flagellar length is balanced by protein exchange, (35)S incorporation into disassembling flagella was examined, as was exchange in flagella in which microtubule assembly was blocked by colchicine. Incorporation of (35)S-labeled polypeptides was found to occur into flagellar axonemes during wavelength-dependent shortening in pf18 and in fla10 cells induced to shorten flagella by incubation at 33 degrees C. Colchicine blocked tubulin addition but did not affect the exchange of the other exchangeable polypeptides; nor did it induce any change in flagellar length. Basal bodies also incorporated newly synthesized proteins. These data reveal that Chlamydomonas flagella are dynamic structures that incorporate new protein both during steady state and as flagella shorten and that protein exchange does not, alone, explain length regulation.

VEGF increases BMEC monolayer permeability by affecting occludin expression and tight junction assembly.

Tight junctions between brain microvessel endothelial cells (BMECs) maintain the blood-brain barrier. Barrier breakdown is associated with brain tumors and central nervous system diseases. Tumor cell-secreted vascular endothelial growth factor (VEGF) increases microvasculature permeability in vivo and is correlated with the induction of clinically severe brain tumor edema. Here we investigated the permeability-increasing effect and tight junction formation of VEGF. By measuring [(14)C]sucrose flux and transendothelial electrical resistance (TER) across BMEC monolayer cultures, we found that VEGF increased sucrose permeability and decreased TER. VEGF also caused a loss of occludin and ZO-1 from the endothelial cell junctions and changed the staining pattern of the cell boundary. Western blot analysis of BMEC lysates revealed that the level of occludin but not of ZO-1 was lowered by VEGF treatment. These results suggest that VEGF increases BMEC monolayer permeability by reducing occludin expression and disrupting ZO-1 and occludin organization, which leads to tight junction disassembly. Occludin and ZO-1 appear to be downstream effectors of the VEGF signaling pathway.

Cytoplasmic dynein heavy chain 1b is required for flagellar assembly in Chlamydomonas.

A second cytoplasmic dynein heavy chain (cDhc) has recently been identified in several organisms, and its expression pattern is consistent with a possible role in axoneme assembly. We have used a genetic approach to ask whether cDhc1b is involved in flagellar assembly in Chlamydomonas. Using a modified PCR protocol, we recovered two cDhc sequences distinct from the axonemal Dhc sequences identified previously. cDhc1a is closely related to the major cytoplasmic Dhc, whereas cDhc1b is closely related to the minor cDhc isoform identified in sea urchins, Caenorhabditis elegans, and Tetrahymena. The Chlamydomonas cDhc1b transcript is a low-abundance mRNA whose expression is enhanced by deflagellation. To determine its role in flagellar assembly, we screened a collection of stumpy flagellar (stf) mutants generated by insertional mutagenesis and identified two strains in which portions of the cDhc1b gene have been deleted. The two mutants assemble short flagellar stumps (<1-2 micrometer) filled with aberrant microtubules, raft-like particles, and other amorphous material. The results indicate that cDhc1b is involved in the transport of components required for flagellar assembly in Chlamydomonas.

Gene knockouts reveal separate functions for two cytoplasmic dyneins in Tetrahymena thermophila.

In many organisms, there are multiple isoforms of cytoplasmic dynein heavy chains, and division of labor among the isoforms would provide a mechanism to regulate dynein function. The targeted disruption of somatic genes in Tetrahymena thermophila presents the opportunity to determine the contributions of individual dynein isoforms in a single cell that expresses multiple dynein heavy chain genes. Substantial portions of two Tetrahymena cytoplasmic dynein heavy chain genes were cloned, and their motor domains were sequenced. Tetrahymena DYH1 encodes the ubiquitous cytoplasmic dynein Dyh1, and DYH2 encodes a second cytoplasmic dynein isoform, Dyh2. The disruption of DYH1, but not DYH2, resulted in cells with two detectable defects: 1) phagocytic activity was inhibited, and 2) the cells failed to distribute their chromosomes correctly during micronuclear mitosis. In contrast, the disruption of DYH2 resulted in a loss of regulation of cell size and cell shape and in the apparent inability of the cells to repair their cortical cytoskeletons. We conclude that the two dyneins perform separate tasks in Tetrahymena.

Regulation of flagellar length in Chlamydomonas.

The length of eukaryotic cilia and flagella depends on the cell cycle-regulated assembly and disassembly of at least 9 doublet and 2 central microtubules, their associated proteins, and the surrounding membrane. In light-synchronized Chlamydomonas cells, flagella assembled to 10-14 microm in length near the beginning of the light period and they disassembled prior to cell division, during the dark period. Flagella on light-synchronized pf18 Chlamydomonas mutants grew to 10-12 microm near the beginning of the light period but shortened by 50% or more by the end of the light period. Flagellar length was cell-cycle regulated: when flagella were amputated at various times during the light period, new flagella regenerated to the lengths of control cells at that time of the light cycle. The later in the cycle pf18 cells were deflagellated, the shorter were the regenerated flagella. Flagellar shortening was not affected, in either pf18 or wild-type (wt) cells, by inhibitors of protein synthesis or of microtubule assembly, so flagellar length cannot depend on protein turnover. Shortening in pf18 was attenuated by Li+, which stimulated flagellar growth in wt cells, by red light, by protein kinase inhibitors, and by the Ca2+ channel blockers La3+ and Cd2+. Shortening was increased by cAMP, Na+, K+, and EGTA. Ca2+-CAM blockers did not affect pf18 shortening but they increased shortening in wt and fa1 cells. We propose that flagellar length is regulated by a signal transduction pathway that is sensitive to Ca2+ levels and red light.

Mitotic arrest in Ptk(2) cells induced by microinjection of a rabbit antiserum and affinity-purified antibodies against a 66-kDa PtK(2) cell polypeptide.

Cell division was arrested by injection of a preimmune rabbit serum, B-61, into PtK(2) cells during interphase and prometaphase. Identical results were obtained by injection of whole B-61 antiserum and of antibodies affinity-purified from the serum against a 66-kDa PtK(2) cell polypeptide. When injected into interphase cells, the antibodies arrested further development and cell division. When injected into prometaphase and metaphase cells, spindles shortened and poles moved together at a rate of 0.2-0.4 mu m/min, approximately half the rate of anaphase A chromosome movements in normally dividing PtK(2) cells. Chromosomes decondensed and cells did not reenter division. Both whole antisera and affinity-purified antibodies stained antigens diffusely localized throughout the cytoplasm in dividing and interphase cells. These results suggest that the 66-kDa antigen is a nonspindle protein that may regulate mitotic progression in PtK(2) cells.

The binding of a ciliary microtubule plus-end binding protein complex to microtubules is regulated by ciliary protein kinase and phosphatase activities.

Using a human autoimmune CREST antiserum, we identified a 97-kDa polypeptide at the plus ends of Tetrahymena ciliary microtubules and an antigen associated with mammalian kinetochores (Miller, J.M., Wang, W., Balczon, R., and Dentler, W.L. (1990) J. Cell. Biol. 110, 703-714). The ciliary protein is part of a 1,500-2,000-kDa complex that can be released from ciliary microtubules and from in vitro assembled brain microtubules with ATP and ATP gamma S (Wang, W., Suprenant, K.A., and Dentler, W. L. (1993) J. Biol. Chem. 268, 24796-24807). Here we show that the ATP-dependent release of the 97-kDa protein from microtubules is inhibited, in a concentration-dependent manner, by calf intestine phosphatase and by the protein kinase inhibitor 6-dimethylaminopurine. Sodium orthovanadate, a phosphotyrosine phosphatase inhibitor, stimulated the ATP-dependent release of the 97-kDa protein from microtubules. Therefore, the ciliary fraction contains both protein kinase and phosphatase activities, and selective inhibition of these activities is necessary for the ATP-dependent binding and release of the 97-kDa protein from microtubules. When incubated with [gamma-32P]ATP, a portion of the 97-kDa protein is phosphorylated as are several other polypeptides associated with it. ATP sensitivity requires a low molecular weight heat-stable factor associated with axonemes. These results suggest that the association of the 97-kDa protein with microtubules is regulated by protein phosphorylation by axoneme-associated kinases and phosphatases.

Reversible association of a 97-kDa protein complex found at the tips of ciliary microtubules with in vitro assembled microtubules.

Using a human autoimmune CREST antiserum, we identified a 97-kDa polypeptide in Tetrahymena cilia at the plus ends of ciliary microtubules and mammalian kinetochores (Miller, J. M., Wang, W., Balczon, R., and Dentler, W. L. (1990) J. Cell Biol. 110, 703-714). In this study, we examined the interactions of the ciliary 97-kDa protein with microtubules assembled from purified bovine brain tubulin. The 97-kDa protein binds to microtubules and is released from them with 75 mM MgCl2, the same condition used to release it from ciliary microtubules. The 97-kDa protein-microtubule association can be disrupted by ATP and by adenosine 5'-O-(thio-triphosphate), and this ATP sensitivity requires a soluble factor in the crude 97-kDa protein fraction. Fractionation of the crude 97-kDa protein fractions by gel filtration chromatography or by sucrose gradient centrifugation causes the loss of the microtubule binding activity of the 97-kDa protein. Fractions containing a high molecular weight protein complex (molecular mass, approximately 1500-2000 kDa) from the column or gradient fractions can restore the microtubule binding ability of the 97-kDa protein. These results suggest that the 97-kDa protein is part of a high molecular weight protein complex and that the complex, not the 97-kDa protein alone, is required for the 97-kDa protein-microtubule association. The association of the 97-kDa protein with microtubules is sensitive to ATP, which suggests that the 97-kDa protein-microtubule interaction may be regulated by an ATPase(s) or protein kinase(s)/phosphatase(s).

Flagellar microtubule dynamics in Chlamydomonas: cytochalasin D induces periods of microtubule shortening and elongation; and colchicine induces disassembly of the distal, but not proximal, half of the flagellum.

To study the mechanisms responsible for the regulation of flagellar length, we examined the effects of colchicine and Cytochalasin D (CD) on the growth and maintenance of Chlamydomonas flagella on motile wild type cells as well as on pf 18 cells, whose flagella lack the central microtubules and are immobile. CD had no effect on the regeneration of flagella after deflagellation but it induced fully assembled flagella to shorten at an average rate of 0.03 microns-min. Cells remained fully motile in CD and even stubby flagella continued to move, indicating that flagellar shortening did not selectively disrupt machinery necessary for motility. To observe the effects of the drug on individual cells, pf 18 cells were treated with CD and flagella on cells were monitored by direct observation over a 5-hour period. Flagella on control pf 18 cells maintained their initial lengths throughout the experiment but flagella on CD-treated cells exhibited periods of elongation, shortening, and regrowth suggestive of the dynamic behavior of cytoplasmic microtubules observed in vitro and in vitro. Cells behaved individually, with no two cells exhibiting the same flagellar behavior at any given time although both flagella on any single cell behaved identically. The rate of drug-induced flagellar shortening and elongation in pf 18 cells varied from 0.08 to 0.17 microns-min-1, with each event occurring over 10-60-min periods. Addition of colchicine to wild type and pf 18 cells induced flagella to shorten at an average rate of 0.06 microns-min-1 until the flagella reached an average of 73% of their initial length, after which they exhibited no further shortening or elongation. Cells treated with colchicine and CD exhibited nearly complete flagellar resorption, with little variation in flagellar length among cells. The effects of these drugs were reversible and flagella grew to normal stable lengths after drug removal. Taken together, these results show that the distal half to one-third of the Chlamydomonas flagellum is relatively unstable in the presence of colchicine but that the proximal half to two-thirds of the flagellum is stable to this drug. In contrast to colchicine, CD can induce nearly complete flagellar microtubule disassembly as well as flagellar assembly. Flagellar microtubules must, therefore, be inherently unstable, and flagellar length is stabilized by factors that are sensitive, either directly or indirectly, to the effects of CD.

Identification of Tetrahymena ciliary surface proteins labeled with sulfosuccinimidyl 6-(biotinamido) hexanoate and Concanavalin A and fractionated with Triton X-114.

Tetrahymena thermophila cells were labeled with sulfosuccinimidyl 6-(biotinamido) hexanoate, a sensitive nonradioactive probe for cell surface proteins, and Western blots of axonemes and ciliary membrane vesicles were compared to cilia fractionated with Triton X-114 (TX-114) in order to study the orientation of ciliary membrane proteins. Greater than 40 ciliary surface polypeptides, from greater than 350 kDa to less than 20 kDa, were resolved. The major surface 50-60 kDa proteins are hydrophobic and partition into the TX-114 detergent phase. Two high molecular weight proteins, one of which is biotinylated, comigrate with the heavy chains of ciliary dynein, sediment at 14S in a sucrose gradient, and partition into the TX-114 aqueous phase. Fractions containing these high molecular weight proteins as well as fractions enriched in 88-kDa and 66-kDa polypeptides contain Mg(2+)-ATPase activities. Detergent-solubilized tubulins partition into the TX-114 aqueous phase, are not biotinylated, and must not be exposed to the ciliary surface. The detergent-insoluble axoneme and membrane fraction contains a 36-kDa polypeptide and a portion of the 50-kDa polypeptides that otherwise partition into the detergent phase. These polypeptides could not be solubilized by ATP or by NaCl extraction and appear to be associated with pieces of ciliary membrane tightly linked to the axoneme. The ciliary membrane polypeptides were also tested for Concanavalin A binding and at least sixteen Con A-binding polypeptides were resolved. Of the major Con A-binding polypeptides, three are hydrophobic and partition into the TX-114 detergent phase, three partition into the TX-114 aqueous phase, and four partition exclusively in the detergent-insoluble fraction, which contains axonemes and detergent-resistant membrane vesicles.

Ciliary microtubule capping structures contain a mammalian kinetochore antigen.

Structures that cap the plus ends of microtubules may be involved in the regulation of their assembly and disassembly. Growing and disassembling microtubules in the mitotic apparatus are capped by kinetochores and ciliary and flagellar microtubules are capped by the central microtubule cap and distal filaments. To compare the ciliary caps with kinetochores, isolated Tetrahymena cilia were stained with CREST (Calcinosis/phenomenon esophageal dysmotility, sclerodactyly, telangiectasia) antisera known to stain kinetochores. Immunofluorescence microscopy revealed that a CREST antiserum stained the distal tips of cilia that contained capping structures but did not stain axonemes that lacked capping structures. Both Coomassie blue-stained gels and Western blots probed with CREST antiserum revealed that a 97-kD antigen copurifies with the capping structures. Affinity-purified antibodies to the 97-kD ciliary protein stained the tips of cap-containing Tetrahymena cilia and the kinetochores in HeLa, Chinese hamster ovary, and Indian muntjak cells. These results suggest that at least one polypeptide found in the kinetochore is present in ciliary microtubule capping structures and that there may be a structural and/or functional homology between these structures that cap the plus ends of microtubules.

Release of intact microtubule-capping structures from Tetrahymena cilia.

The distal ends of ciliary microtubules are attached to the membrane by microtubule-capping structures. The capping structures are located at the sites of tubulin addition and loss in vivo and may be part of the regulatory system that directs ciliary and flagellar microtubule assembly. This study describes conditions for the release and stabilization of microtubule capping structures as a first step in their purification. Two types of capping structures, the distal filaments and the central microtubule caps, are selectively and independently released from the axoneme by CaCl2 and MgCl2 but not by MgSO4, ZnCl2, NaCl, KCl, or KI. The release of the caps and filaments is specific for Ca+2, Mg+2, and Cl- and is not simply a function of ionic strength. The capping structures are released without major disruption of the axonemal structure. In addition to providing a means to purify and identify the cap and filament components, these results suggest ways in which their binding to the axoneme may be modulated during periods of microtubule growth or shortening. This report also reveals that the distal filaments are composed of two separable components, a small bead inserted into the end of each A-tubule and a "Y"-shaped plug and filament that slips through the bead.

Fractionation of Tetrahymena ciliary membranes with triton X-114 and the identification of a ciliary membrane ATPase.

Cilia were isolated from Tetrahymena thermophila, extracted with Triton X-114, and the detergent-soluble membrane + matrix proteins separated into Triton X-114 aqueous and detergent phases. The aqueous phase polypeptides include a high molecular mass polypeptide previously identified as a membrane dynein, detergent-soluble alpha and beta tubulins, and numerous polypeptides distinct from those found in axonemes. Integral membrane proteins partition into the detergent phase and include two major polypeptides of 58 and 50 kD, a 49-kD polypeptide, and 5 polypeptides in relatively minor amounts. The major detergent phase polypeptides are PAS-positive and are phosphorylated in vivo. A membrane-associated ATPase, distinct from the dynein-like protein, partitions into the Triton X-114 detergent phase and contains nearly 20% of the total ciliary ATPase activity. The ATPase requires Mg++ or Ca++ and is not inhibited by ouabain or vanadate. This procedure provides a gentle and rapid technique to separate integral membrane proteins from those that may be peripherally associated with the matrix or membrane.

Development of microtubule capping structures in ciliated epithelial cells.

Although capping structures are present at the tips of microtubules in both growing cilia and mature cilia, previous work has not determined the time of cap formation. The results reported here reveal that the large caps of mature palate cilia appear in cilia with lengths as short as 1.75 micron. In the growing palate cilium, a disk-shaped plate is formed at the tip during the first micron of growth. As the cilium elongates to 1.5-2.0 microns, a small plate forms underneath the disk-shaped plate that gives an asymmetrical appearance to the whole cap structure. The structure of the cap is complete in cilia longer than 2.0 microns. The hair-like structures that form the extraciliary crown appear on the membrane at the ciliary tip at the same time as the mature cap is forming. The formation of a cap structure is discussed in relation to microtubule assembly during ciliogenesis.