Effect of microtubule-associated proteins on the protofilament number of microtubules assembled in vitro

In order to demonstrate the effect of microtubule-associated proteins on the protofilament number of microtubules, we used different systems of microtubule formation in vitro in which these proteins are either functionally eliminated (by DNA or glycerol) or absent (purified tubulin). The results obtained by electron microscopy of ultrathin-sectioned material indicate that under standard conditions in the presence of microtubule-associated proteins microtubules are formed consisting predominantly of 14 protofilaments. In cases of deficiency of microtubule-associated proteins, the mean value of the protofilament number is lower, and the protofilament number within the microtubule population varies remarkably. On the other hand, the action of microtubule-associated proteins is enhanced by histones resulting in increased protofilament numbers. A model is proposed illustrating that the quality and the quantity of microtubule-associated proteins bound to microtubules determine the curvature between the protofilaments and restrict the variety of their binding angles. In this way the microtubule-associated proteins may be regarded as an important factor in determining the structural fidelity of microtubules.     

Interaction of microtubule-associated proteins with actin filaments. Studies using the fluorescence-photobleaching recovery technique

The interaction of microtubule-associated proteins with actin filaments has been investigated by measuring the diffusion coefficient of either the filament or the microtubule-associated proteins. Experiments were performed using the technique of fluorescence photobleaching recovery with actin labeled with iodoacetamidotetramethyl rhodamine or microtubule-associated proteins labeled with iodoacetamidofluorescein. Actin filaments composed of pure rhodamine-labeled actin are not immobilized under a variety of conditions (Tait, J. F., and Frieden, C. (1982c) Biochemistry 21, 6046-6053). We find that addition of microtubule-associated proteins to rhodamine-labeled actin in a ratio as low as 1:1000 can cause immobilization, presumably cross-linking actin into a network of nondiffusible filaments. Immobilization occurs after polymerization is complete, suggesting either a length redistribution of actin filaments, a redistribution of the cross-links between filaments, or the slow addition of actin filaments to other filaments via the microtubule-associated protein. Experiments using fluorescein-labeled microtubule-associated proteins show that these proteins are bound to actin filaments as they are formed and that binding depended on actin concentration, indicating that there are a number of binding sites on the actin filaments. However, while the actin filaments become completely immobilized, the microtubule-associated proteins become only partially immobilized suggesting at least two different classes of binding affinities. The large peptide obtained from trypsin-treated fluorescein-labeled microtubule-associated proteins is not able to immobilize actin filaments since it does not bind to the filaments.     

Vinblastine-induced aggregation of brine shrimp (Artemia) tubulin

Tubulin from the brine shrimp Artemia readily assembles in vitro in the absence of microtubule-associated proteins under conditions which do not permit assembly of tubulin from brain. Heated microtubule-associated protein preparations from bovine brain do, however, interact with Artemia tubulin, resulting in stimulation of tubulin assembly and formation of morphologically normal cold-sensitive microtubules. Addition of vinblastine to mixtures containing microtubules assembled in the presence of neural microtubule-associated proteins caused a drop and then a rise in turbidity of the solution. The turbidity changes were accompanied by the appearance of coils, presumably derived from the microtubules which disappeared upon addition of vinblastine. Coils also resulted when microtubule-associated proteins and vinblastine were added to tubulin before polymerization was initiated. Vinblastine prevented normal assembly and caused disruption of Artemia microtubules polymerized in the absence of microtubule-associated proteins. Under these conditions clumped or compact coils, different in appearance from those formed in the presence of the microtubule-associated proteins, were observed. The data confirm that tubulin from Artemia, an organism that is phylogenetically far removed from mammals, has retained binding sites for vinblastine and microtubule-associated proteins and that the interrelationship of these sites has been at least partially preserved. The incomplete depolymerization of Artemia microtubules in response to vinblastine when microtubule-associated proteins are absent suggests that the longitudinal tubulin-tubulin interactions involved in microtubule formation are more stable for Artemia than for neural tubulin.     

Cysteine oxidation of tau and microtubule-associated protein-2 by peroxynitrite: modulation of microtubule assembly kinetics by the thioredoxin reductase system

Alterations in the redox status of proteins have been implicated in the pathology of several neurodegenerative conditions including Alzheimer and Parkinson diseases. We report that peroxynitrite- and hydrogen peroxide-induced disulfides in the neuron-specific microtubule-associated proteins tau and microtubule-associated protein-2 are substrates for the ubiquitous thioredoxin reductase system composed of thioredoxin reductase, human or Escherichia coli thioredoxin, and NADPH. Tau and microtubule-associated protein-2 cysteine oxidation and reduction were quantitated by monitoring the incorporation of 5-iodoacetamidofluorescein, a thiol-specific labeling reagent. Cysteine oxidation of tau and microtubule-associated protein-2 to disulfides altered the ability of the proteins to promote the assembly of microtubules from purified porcine tubulin. Treatment of tau and microtubule-associated protein-2 with either the thioredoxin reductase system or small molecule reductants fully restores the ability of the MAPs to promote microtubule assembly. Thus changes in the redox state of microtubule-associated proteins may regulate microtubule polymerization in vivo.     

Higher plant microtubule-associated proteins (MAPs): A survey

Summary— Microtubule-associated proteins (MAPs) are one of the factors which regulate the different properties of microtubules during cell cycle and differentiation. They have been characterized as proteins which promote tubulin assembly in a concentration-dependent manner and bind to the outer surface of the polymers in vitro. Most of our knowledge comes from studies of neural microtubule-associated proteins and recent results highlight their implication in neuronal morphogenesis. In contrast, until recently, few data are available about the proteins that associate with plant tubulins. This is due principally to the fact that plant microtubule-associated proteins cannot be purified by the standard procedures used for neural microtubule-associated proteins. First, we will describe methods which have been used to isolate these proteins in plant cells. We will then discuss the biochemical and immunological properties of the plant microtubule-associated proteins which have been isolated. From these results, putative functions can be proposed for these proteins n the particular plant cytoskeleton activities.     

Redox modulation of tau and microtubule-associated protein-2 by the glutathione/glutaredoxin reductase system

Alterations in the redox status of proteins have been implicated in the pathology of several neurodegenerative diseases including Alzheimer's and Parkinson's. We report that peroxynitrite and H2O2-induced disulfides in the porcine brain microtubule-associated proteins tau and microtubule-associated protein-2 are substrates for the glutaredoxin reductase system composed of glutathione reductase, human or Escherichia coli glutaredoxin, reduced glutathione, and NADPH. Oxidation and reduction of cysteines in tau and microtubule-associated protein-2 were quantitated by monitoring the incorporation of 5-iodoacetamido-fluorescein, a thiol-specific labeling reagent. Reduction of disulfide bonds in the microtubule-associated proteins by the glutaredoxin reductase system restored their ability to promote the assembly of microtubules composed of purified porcine tubulin. Thiol-disulfide exchange between oxidized glutathione and the microtubule-associated proteins was detected by monitoring protein oxidation and was quantitated by measuring reduced glutathione by HPLC.     

Interaction of estramustine phosphate with microtubule-associated proteins

We have reported [(1984) Cancer Res., in press] that estramustine phosphate inhibits microtubule assembly and disassembled preformed microtubules. We now present evidence that estramustine phosphate inhibits microtubule assembly by binding to the microtubule-associated proteins. We have found that: additional microtubule-associated proteins relieved the inhibition of assembly by estramustine phosphate; 3H-labelled estramustine phosphate bound predominantly to the microtubule-associated proteins; and the content of the microtubule-associated proteins was reduced in taxol reversed estramustine phosphate-inhibited microtubules.     

Plant microtubule-associated proteins: the HEAT is off in temperature-sensitive mor1.

Microtubules perform essential functions in plant cells and govern, with other cytoskeletal elements, cell division, formation of cell walls and morphogenesis. For microtubules to perform their roles in the cell their organization and dynamics must be regulated and microtubule-associated proteins bear the main responsibility for these activities. We are just beginning to identify these plant microtubule-regulating proteins. Biochemical, molecular and genetic procedures have identified plant homologues of known microtubule-associated proteins, such as kinesins, katanin and XMAP215, and novel classes of plant microtubule-associated proteins, such as MAP65 and MAP190. Showing how these proteins coordinate the microtubule cytoskeleton in vivo is now the challenge. The recent identification and characterization of the Arabidopsis thaliana microtubule organization mutant, mor1, begins to address this challenge and here we highlight the significance of this work.     

Tubulin and high molecular weight microtubule-associated proteins as endogenous substrates for protein carboxymethyltransferase in brain

The endogenous substrate for protein carboxymethyltransferase in brain was examined. Several polypeptides were methylated when brain slices were incubated with L-methionine or when subcellular fractions of brain, such as the cytosolic fraction, were incubated with S-adenosyl L-methionine. Two methyl-accepting proteins in the cytoplasm were identified as tubulin and high molecular weight microtubule-associated proteins (300 kDa), which are components of microtubules. Tubulin behaved as a 43 kDa protein in acidic polyacrylamide gel electrophoresis, but as a 55 kDa protein in SDS-polyacrylamide gel electrophoresis. The methyl moiety transferred to these proteins from L-methionine was labile at alkaline pH. The high molecular weight microtubule-associated proteins showed higher methyl-accepting activity than tubulin or ovalbumin, which was used as a standard substrate: about 20 mmol of high molecular weight microtubule-associated proteins, 2 mmol of tubulin and 10 mmol of ovalbumin were methylated per mol of each protein in 30 min under the experimental conditions used.     

Secondary cell wall patterning during xylem differentiation

Xylem cell differentiation involves temporal and spatial regulation of secondary cell wall deposition. The cortical microtubules are known to regulate the spatial pattern of the secondary cell wall by orientating cellulose deposition. However, it is largely unknown how the microtubule arrangement is regulated during secondary wall formation. Recent findings of novel plant microtubule-associated proteins in developing xylem vessels shed new light on the regulation mechanism of the microtubule arrangement leading to secondary wall patterning. In addition, in vitro culture systems allow the dynamics of microtubules and microtubule-associated proteins during secondary cell wall formation to be followed. Therefore, this review focuses on novel aspects of microtubule dynamics leading to secondary cell wall patterning with a focus on microtubule-associated proteins.     

Ascorbic acid reduction of microtubule protein disulfides and its relevance to protein S-nitrosylation assays

The biotin switch assay was developed to aid in the identification of S-nitrosylated proteins in different cell types. However, our work with microtubule proteins including tubulin and its associated proteins tau and microtubule-associated protein-2 shows that ascorbic acid is not a selective reductant of protein S-nitrosothiols as described in the biotin switch assay. Herein we show that ascorbic acid reduces protein disulfides in tubulin, tau, and microtubule-associated protein-2 that are formed by peroxynitrite anion. Reduction of microtubule-associated protein disulfides by ascorbic acid following peroxynitrite treatment restores microtubule polymerization kinetics to control levels. We also show that ascorbic acid reduces the disulfide dithiobis(2-nitrobenzoic acid), a reagent commonly used to detect protein thiols. Not only do we describe a new reactivity of ascorbic acid with microtubule proteins but we expose an important limitation when using the biotin switch assay to detect protein S-nitrosylation.     

Coordinate release of myosin and a high molecular weight microtubule-associated protein from PC12 cytoskeletons by ATP

The association of two high molecular weight (HMW) structural proteins with the cytoskeletons of rat pheochromocytoma cells, PC12, is regulated by ATP and other nucleotides. Exposure of PC12 cytoskeletons to ATP resulted in the selective solubilization of two HMW proteins, identified as myosin and a 280 kD microtubule-associated protein. These two proteins were rapidly released from the cytoskeleton following incubation with ATP, GTP, CTP, and ADP; non-hydrolysable ATP analog caused protein release to a less marked extent. The effect of the latter two nucleotides indicated that the release of the myosin and the HMW microtubule-associated protein was likely to be the result of nucleotide-induced conformational changes in one or both proteins. Myosin and the HMW microtubule-associated proteins interact with actin in vitro in a nucleotide-sensitive manner. The present data demonstrate that similar interactions are likely to exist within the intact cytoskeleton and suggest that the associations of these structural proteins with the cytoskeleton are regulated by common mechanisms. The results also suggest that the cells may differentially regulate the stability of a subset of these structural proteins in their interactions with other cytoskeletal elements.     

Molecular weight dependency of heparin inhibition of microtubule assembly in vitro

Low molar ratios of heparin inhibited in vitro assembly of bovine brain microtubule proteins and disassembled preformed microtubules. Addition of purified microtubule-associated proteins counteracted the assembly inhibition by heparin. Our results suggest that the polyanion heparin affects microtubule assembly by binding to the microtubule-associated proteins. This complex can not support nucleation or stabilize the microtubule structure although it still can associate with the tubulin polymer. In the presence of heparin, the critical concentration needed for microtubule assembly was increased. Furthermore, the absolute assembly difference induced by heparin, the delta A350, was only dependent on the concentration and the molecular weight of heparin, not of the total microtubule protein concentration, or the addition of microtubule-associated proteins. Commercial, standard heparin (Mr 6000-25 000) had an I50 of about 0.1/tubulin dimer. The heparin fraction(s) with a high molecular weight had a stronger effect than those with lower molecular weight. Substoichiometric amounts of taxol completely relieved the inhibition of assembly by heparin, although aberrant forms were present. These microtubules had a reduced amount of coassembled microtubule-associated proteins, and furthermore contained heparin.     

Going new places using an old MAP: tau, microtubules and human neurodegenerative disease

The microtubule-associated protein tau was originally identified as a protein that co-purified with tubulin in vitro, stimulated assembly of tubulin into microtubules and strongly stabilized microtubules. Recognized now as one of the most abundant axonal microtubule-associated proteins, a convergence of evidence implicates an overlapping in vivo role of tau with other axonal microtubule-associated proteins (e.g. MAP1B) in establishing microtubule stability, axon elongation and axonal structure. Missense and splice-site mutations in the human tau gene are now known to be causes of inherited frontotemporal dementia and parkinsonism linked to chromosome 17, a cognitive disorder of aging. This has provided direct evidence for the hypothesis that aberrant, filamentous assembly of tau, a frequent hallmark of a series of human cognitive diseases, including Alzheimer's disease, can directly provoke neurodegeneration.     

A novel microtubule-binding motif identified in a high molecular weight microtubule-associated protein from Trypanosoma brucei

The major component of the cytoskeleton of the parasitic hemoflagellate Trypanosoma brucei is a membrane skeleton which consists of a single layer of tightly spaced microtubules. This array encloses the entire cell body, and it is apposed to, and connected with, the overlying cell membrane. The microtubules of this array contain numerous microtubule-associated proteins. Prominent among those is a family of high molecular weight, repetitive proteins which consist to a large extent of tandemly arranged 38-amino acid repeat units. The binding of one of these proteins, MARP-1, to microtubules has now been characterized in vitro and in vivo. MARP-1 binds to microtubules via tubulin domains other than the COOH-termini used by microtubule-associated proteins from mammalian brain, e.g., MAP2 or Tau. In vitro binding assays using recombinant protein, as well as transfection of mammalian cell lines, have established that the repetitive 38-amino acid repeat units represent a novel microtubule-binding motif. This motif is very similar in length to those of the mammalian microtubule-associated proteins Tau, MAP2, and MAP-U, but both its sequence and charge are different. The observation that the microtubule-binding motifs both of the neural and the trypanosomal proteins are of similar length may reflect the fact that both mediate binding to the same repetitive surface, the microtubule, while their sequence and charge differences are in agreement with the observation that they interact with different domains of the tubulins.     

Binding of microtubule proteins to DNA: specificity of the interaction.

Tubulin is detected among the DNA-binding proteins when an extract from fibroblasts is chromatographed on DNA-cellulose. Further purification of the colchicine-binding activity shows that purified tubulin from fibroblasts does not bind to DNA. Depolymerized brain microtubule proteins show a high affinity for DNA. The fraction bound is composed of tubulin and microtubule-associated proteins. Experiments with fractionated microtubule proteins indicate that tubulin-free microtubule associated proteins bind to DNA, while tubulin free of microtubule-associated proteins does not. Microtubule-associated proteins bind better to eukaryotic than to phage DNA suggesting a specificity of the interaction.     

Immunological characterization of microtubule-associated proteins specific for the immature brain

Immunoblotting analysis was used to detect the microtubule-associated proteins present at different stages of rat brain development. Polyclonal antibodies were raised against the two main adult brain microtubule-associated proteins: MAP-2 (300 kDa) and TAU (60-70 kDa). Whatever the stage of development, anti-MAP-2 serum detected high molecular mass proteins and at immature stages a protein of 62 kDa. This protein which has previously been referred to as 'young TAU slow' is, therefore, immunologically related to MAP-2. The anti-TAU serum (but not the anti-MAP-2 serum) detected at immature stages of development a 48 kDa protein which also disappears at adulthood. This 48 kDa entity which has been referred to as 'young TAU fast' is progressively replaced by the closely spaced bands (60-70 kDa) of adult TAU proteins. The 62 and 48 kDa proteins appear therefore to be immunologically distinct and represent two microtubule-associated proteins specific to the immature brain.     

Novel Thioredoxin-Like Proteins Are Components of a Protein Complex Coating the Cortical Microtubules of Toxoplasma gondii

Microtubules are versatile biopolymers that support numerous vital cellular functions in eukaryotes. The specific properties of microtubules are dependent on distinct microtubule-associated proteins, as the tubulin subunits and microtubule structure are exceptionally conserved. Highly specialized microtubule-containing assemblies are often found in protists, which are rich sources for novel microtubule-associated proteins. A protozoan parasite, Toxoplasma gondii, possesses several distinct tubulin-containing structures, including 22 microtubules closely associated with the cortical membrane. Early ultrastructural studies have shown that the cortical microtubules are heavily decorated with associating proteins. However, little is known about the identities of these proteins. Here, we report the discovery of a novel protein, TrxL1 (for Thioredoxin-Like protein 1), and an associating complex that coats the cortical microtubules. TrxL1 contains a thioredoxin-like fold. To visualize its localization in live parasites by fluorescence, we replaced the endogenous TrxL1 gene with an mEmeraldFP-TrxL1 fusion gene. Structured illumination-based superresolution imaging of this parasite line produced a detailed view of the microtubule cytoskeleton. Despite its stable association with the cortical microtubules in the parasite, TrxL1 does not seem to bind to microtubules directly. Coimmunoprecipitation experiments showed that TrxL1 associates with a protein complex containing SPM1, a previously reported microtubule-associated protein in T. gondii. We also found that SPM1 recruits TrxL1 to the cortical microtubules. Besides SPM1, several other novel proteins are found in the TrxL1-containing complex, including TrxL2, a close homolog of TrxL1. Thus, our results reveal for the first time a microtubule-associated complex in T. gondii.     

Structural and regulatory roles of nonmotor spindle proteins

Chromosome alignment and segregation during cell division rely on a highly ordered bipolar microtubule array called the mitotic spindle. The organization of microtubules into bipolar spindles with focused poles during mitosis requires numerous microtubule-associated proteins including both motor and nonmotor proteins. Nonmotor microtubule-associated proteins display extraordinary diversity in how they contribute to mitotic spindle organization. These mechanisms include regulation of microtubule nucleation and organization, direct and indirect influences on motor function, and control of cell cycle progression. Furthermore, many nonmotor spindle proteins display altered expression in cancer cells emphasizing their important roles in cell proliferation.     

High molecular weight MAPs are part of the mitotic spindle

We have found that the microtubule-associated proteins of high molecular weight are located in the mitotic spindle. Indirect immunofluorescence studies reveal that the pattern of distribution of these proteins is similar to that described for tubulin and corresponds to the known phases of mitosis.