Polyglutamylation of atlantic cod tubulin: immunochemical localization and possible role in pigment granule transport.

In higher organisms, there is a large variety of tubulin isoforms, due to multiple tubulin genes and extensive post-translational modification. The properties of microtubules may be modulated by their tubulin isoform composition. Polyglutamylation is a post-translational modification that is thought to influence binding of both structural microtubule associated proteins (MAPs) and mechano-chemical motors to tubulin. The present study investigates the role of tubulin polyglutamylation in a vesicle transporting system, cod (Gadus morhua) melanophores. We did this by microinjecting an antibody against polyglutamylated tubulin into these cells. To put our results into perspective, and to be able to judge their universal application, we characterized cod tubulin polyglutamylation by Western blotting technique, and compared it to what is known from mammals. We found high levels of polyglutamylation in tissues and cell types whose functions are highly dependent on interactions between microtubules and motor proteins. Microinjection of the anti-polyglutamylation antibody GT335 into cultured melanophores interfered with pigment granule dispersion, while dynein-dependent aggregation was unaffected. Additional experiments showed that GT335-injected cells were able to aggregate pigment even when actin filaments were depolymerized, indicating that the maintained ability of pigment aggregation in these cells was indeed microtubule-based and did not depend upon actin filaments. The results indicate that dynein and the kinesin-like dispersing motor protein in cod melanophores bind to tubulin on slightly different sites, and perhaps depend differentially on polyglutamylation for their interaction with microtubules. The binding site of the dispersing motor may bind directly to the polyglutamate chain, or more closely than dynein.

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MAP 0, a 400-kDa microtubule-associated protein unique to teleost fish.

Microtubules from neural tissues of the Atlantic cod, Gadus morhua, and of several species of Antarctic teleosts are composed of tubulin and several microtubule-associated proteins (MAPs), one of which has an apparent molecular weight of approximately 400-430 kDa. Because its apparent molecular weight exceeds those of the MAP 1 proteins, we designate this high molecular weight teleost protein MAP 0. Cod MAP 0 failed to cross-react with antibodies specific for MAPs 1A, 1B and 2 of mammalian brain, for MAP H1 of squid optic lobe, and for chicken erythrocyte syncolin, which suggests that it has a novel structure. Similarly, MAP 0 from the Antarctic fish was not recognized by an antibody specific for bovine MAP 2. Together, these observations suggest that MAP 0 is a novel MAP that may be unique to fish. To determine the tissue specificity and phylogenetic distribution of this protein, we generated a rabbit polyclonal antibody against cod MAP 0. Using this antibody, we found that MAP 0 was present in microtubule proteins isolated from cod brain tissues and spinal cord but was absent in microtubules from heart, liver, and spleen. At the subcellular level, MAP 0 was distributed in cod brain cells in a punctate pattern coincident with microtubules but was absent in skin cells. MAP 0 was also detected in cells of the peripheral nervous system. A survey of microtubule proteins from chordates and invertebrates showed that anti-MAP 0-reactive homologs were present in five teleost species but not in more primitive fish and invertebrates or in higher vertebrates. MAP 0 bound to cod microtubules by ionic interaction at a site recognized competitively by bovine MAP 2. Although its function is unknown, MAP 0 does not share the microtubule-binding properties of the motor proteins kinesin and dynein. We propose that MAP 0 is a unique, teleost-specific MAP.

Detyrosination of tubulin is not correlated to cold-adaptation of microtubules in cultured cells from the Atlantic cod (Gadus morhua).

Isolated cod brain microtubules from the cold-adapted Atlantic cod (Gadus morhua) have previously been shown to be highly detyrosinated, a post-translational modification of tubulin usually found in stable subsets of microtubules. In this study we found this was not restricted only to isolated brain microtubules. Microtubules in primary cultures of brain and skin cells were composed of both tyrosinated (Tyr)- and detyrosinated (Glu)-tubulin seen by immunocytochemistry. Immunoelectron microscopy of isolated microtubules showed that individual microtubules were composed of a mixture of Tyr- and Glu-tubulin. Leukocytes with extending lamellopodia contained only microtubules stained with the antibody against Tyr-tubulin, and isolated heart tubulin lacked both Tyr- and Glu-tubulin, suggesting that a relative high level of detyrosination is a characteristic of most, but not all, cod microtubules. Brain cell microtubules were more resistant to mitotic inhibitors than skin cell microtubules, but this was not correlated to a difference in detyrosination. Brain and skin cell microtubules were only partially disassembled when incubated at 0 degrees C. Upon reassembly of microtubules at 12 degrees C, microtubules were still made of mixtures of Tyr- and Glu-tubulin, indicating that detyrosination of assembled microtubules is rapid and/or that in cod cells in contrast to mammalian cells, Glu-tubulin can reassemble to microtubules. Our data show that most cod microtubules are highly detyrosinated, but this is not the cause of their cold adaptation or drug stability.

Localization of kinesin and cytoplasmic dynein in cultured melanophores from Atlantic cod, Gadus morhua.

In this study we have analyzed pigment translocation in cultured melanophores from the cold-tempered Atlantic cod, Gadus morhua. The transport process was found to be cold-adapted, as it proceeded at low temperatures. Both the typical morphology of the melanophores with long cytoplasmic processes, and the ability to translocate pigment granules, were found to be highly dependent on microtubules. Microtubules in melanophores were relatively stable to vinblastine treatment compared to microtubules in other skin cells. Extensive posttranslational modifications of tubulin were found. Detyrosinated and polyglutamylated microtubules were frequent, while acetylated microtubules only comprised a subpopulation or domains of microtubules. Both cod kinesin and dynein were distributed in a punctate pattern throughout the melanophores in close proximity to microtubules. The motors accumulated together with pigment granules during aggregation and were dispersed during translocation of pigment granules to the periphery. Individual melanosomes were occasionally found to rapidly change direction during translocation. Our data raise the interesting possibility that both kinesin and dynein are bound to pigment granules. This is of functional significance, since pigment granules are transported back and forth in the melanophores, and may be activated differently during aggregation and dispersion to generate translocation.

Distribution of acetylated tubulin in cultured cells and tissues from the Atlantic cod (Gadus morhua). Role of acetylation in cold adaptation and drug stability.

The Atlantic cod (Gadus morhua) is a poikilothermic animal living at temperatures between 2-15 degrees C. Isolated cod brain tubulin is, in contrast to mammalian brain tubulin, posttranslationally modified by acetylation to a high extent. To investigate the role of acetylation in cold adaptation, microtubules were isolated by a taxol-dependent procedure from different organs of the cod, and cells from different tissues were cultured. All cells from skin and brain were able to grow between 4 degrees C and room temperature. Microtubules in the cultured cells were sometimes severed near the periphery of the cells. Microtubules in brain cells were in general more stable to vinblastine and colchicine, when compared to skin cells. Acetylated microtubules were found only in brain cells, in peripheral nerves on scales and in nerves of the intestinal tract and in microtubules isolated from neuronal tissue. Our results show that acetylated microtubules are found both in the central and peripheral nervous system, but that there is no correlation between acetylation and cold-adaptation.

Estramustine induces disorganization of microtubules, perinuclear retraction of vimentin and endoplasmatic reticulum, and inhibits cell migration.

The effects of the mitotic inhibitor estramustine on the cytoskeleton of DU 145 and AG 1518 cells were studied. Estramustine caused a partial disassembly of microtubules and withdrawal of microtubules from the cell periphery, disorganized microtubules and delayed regrowth of disassembled microtubules. It also induced a spheroid cellular morphology and affected cellular adhesion and survival. Sometimes microtubules seemed to be organized from several microtubule-organizing centers. The cytoskeleton-dependent cell migration was inhibited in the presence of estramustine and the microtubule-interacting vimentin and endoplasmatic reticulum retracted to the perinuclear area. Our results show that not only a complete disassembly of microtubules, but also disturbances of the microtubule network can have dramatic effects on microtubule-dependent processes and localization of cellular organelles. These effects could be of importance in the treatment of prostatic carcinoma with estramustine.

The effect of estramustine derivatives on microtubule assembly in vitro depends on the charge of the substituent.

Estramustine, and derivatives of estramustine with a charged substituent at position 17 on the estrogen moiety, have been investigated for their effects on bovine brain microtubules in vitro. The negatively charged estramustine phosphate has been found previously to be a microtubule-associated protein (MAP)-dependent microtubule inhibitor [Wallin M, Deinum J and Fridén B, FEBS Lett 179: 289-293, 1985]. In the present study the binding of estramustine phosphate to MAP2 and tau was investigated. Both these MAPs were found to have two to three binding sites for estramustine phosphate which is compatible with the reported number of basic amino acid repeats of these MAPs, considered to be the ultimate tubulin binding domains. The Kd for the binding of estramustine phosphate to MAP2 was estimated to be 20 microM at 4 degrees, and for the binding of tau, 200 microM. The rate of dissociation was very low (T1/2 greater than 2 hr), which indicates that the binding of estramustine phosphate may stabilize the protein-drug complex by changing the protein conformation. Two new negatively charged estramustine derivatives, estramustine sulphate and estramustine glucuronide, were found to be similar MAP-dependent microtubule inhibitors. The concentration for 50% inhibition of assembly was 100 microM for the sulphate derivative, the same as found previously for estramustine phosphate, and 250 microM for the more bulky estramustine glucuronide. A positively charged derivative, estramustine sarcosinate, did not inhibit microtubule assembly or alter the composition of the coassembled MAPs. The morphology of the microtubules was, however, affected. The uncharged estramustine bound to both tubulin and MAPs, but no effects were seen on microtubule assembly, the composition of coassembled MAPs or the microtubule morphology. Our results suggest that only negatively charged estramustine derivatives have a MAP-dependent microtubule inhibitory effect. The two new negatively charged derivatives could therefore be valuable tools in the study of tubulin-MAP interactions. The results also confirm that these interactions between tubulin and MAPs are mainly electrostatic.

Proteolytic cleavage of high-molecular-weight microtubule-associated proteins by the prostatic estramustine-binding protein.

The rat prostatic estramustine-binding protein was found to inhibit assembly of microtubules in a concentration-dependent manner. The inhibition was caused by a proteolytic cleavage of the high-molecular-weight microtubule associated proteins (MAPs), as judged by sodium dodecyl sulfate-gel electrophoresis. A proteolytic fragment with a molecular weight of 199 kDa appeared, which remained bound to the assembled microtubules. Fragments of lower molecular weights (170, 149 kDa) were also found, but they did not bind to the assembled microtubules. Fragments with identical molecular weights were also found after incubation of purified MAP2 with the estramustine-binding protein, indicating that the fragments derive from MAP2. No proteolysis of tubulin, albumin, or casein was found. The estramustine-binding protein was found to be a Zn2+-dependent protease; it was inhibited by EDTA and reactivated by addition of 1 mM Zn2+. Its proteolytic activity was not affected by binding of the antimitotic drug estramustine.

Transplantation of enzyme-treated teeth in the monkey Macaca fascicularis.

Homologous tooth transplants evoke immunogenic rejection against antigens within donor periodontal ligaments cells and ground substance. Eight maxillary incisors of 6 juvenile animals were extracted, crowns and pulps removed by gutta percha; the roots were incubated serially in enzyme solutions and glutaraldehyde at 37 degrees C for 5 h to destroy cells, glycoproteins and proteoglycans. Seven control teeth from the same 6 animals were incubated in saline at 37 degrees C for 15 min. All teeth were then speedily transplanted to other animals which were killed at 6 wk or 3 months. Radiographs and histologic sections revealed extensive resorption and inflammation of all control teeth. Enzyme-treated teeth showed less inflammation with resorption mostly on the surface of the cut coronal dentine. A loose fibrous attachment usually formed on most aspects of the root surface with deposition of new cellular cementum within the donor ligament. Inflammation, where present, may have resulted from incomplete removal of periodontal ligament cells, ground substance, or from salivary bacterial contamination.

Pulpal response to the application of phosphoric acid to dentin.

Experimental cavities were prepared in forty-six clinically intact premolars of young individuals to evaluate the biologic effects of 50 per cent phosphoric acid etchant containing 7 percent zinc oxide by weight. The experimental periods ranged from 30 minutes to 150 days. The remaining dentin thickness varied from 1.8 to 3.5 mm. The teeth treated with the acid showed no more than a moderate pulpal response at the varying time periods. All of the acid-treated teeth demonstrated pulpal imflammation in the absence of clinical pain. Acid etchants should not be used on exposed or unprotected dentin surfaces.