Containment of extended length polymorphisms in silk proteins.

The spider silk gene family to the current date has been developed by gene duplication and homogenization events as well as conservation of crucial sequence parts. These evolutionary processes have created an amazing diversity of silk types each associated with specific properties and functions. In addition, they have led to allelic and gene variants within a species as exemplified by the major ampullate spidroin 1 gene of Nephila clavipes.

Composition and hierarchical organisation of a spider silk.

Albeit silks are fairly well understood on a molecular level, their hierarchical organisation and the full complexity of constituents in the spun fibre remain poorly defined. Here we link morphological defined structural elements in dragline silk of Nephila clavipes to their biochemical composition and physicochemical properties. Five layers of different make-ups could be distinguished.

The conserved C-termini contribute to the properties of spider silk fibroins.

Spider silk fibroins can adopt different structural states at high protein concentrations. They are soluble within the spinning dope of the glands, but readily converted into insoluble polymers upon extrusion. A contribution of the C-termini to the maintenance and conversion of these states is suggested by their predicted secondary structures and biochemical behavior in vitro.

Lipopolysaccharide-caused fragmentation of individual microtubules in vitro observed by video-enhanced differential interference contrast microscopy.

Microtubule disassembly is commonly believed to be a process of endwise tubulin dimer release. The present study demonstrates by video interference contrast microscopy that Escherichia coli lipopolysaccharide (LPS) caused microtubule disassembly in vitro by both endwise shortening and fragmentation. In contrast, the microtubules were only shortened from their ends in the presence of DNA, used as another example of a macromolecular microtubule effector.

Kinesin-driven microtubule motility in the presence of alkaline-earth metal ions: indication for a calcium ion-dependent motility.

We studied the effect of alkaline-earth metal ions on the kinesin-driven gliding of microtubules, using a narrow glass chamber enabling the exchange of buffer components without interrupting microscopic observation. Under standard conditions (0.5 mM Mg2+), microtubules were found to glide at a mean velocity of about 0.

Tubulin assembly in the presence of calcium ions and taxol: microtubule bundling and formation of macrotubule-ring complexes.

It has been confirmed that taxol is able to prevent Ca(2+)-induced inhibition of microtubule formation from tubulin in the presence of microtubule-associated proteins. However, by means of electron microscopy and scanning force microscopy it could be demonstrated that assembly in the presence of Ca2+ and taxol leads to structural aberrations. The kind of aberration depends on the order of addition of taxol and Ca2+ to tubulin.

Scanning force microscopy of microtubules and polymorphic tubulin assemblies in air and in liquid.

We have investigated microtubules (MTs) and polymorphic assemblies, formed in vitro from isolated microtubule protein, by scanning force microscopy (SFM) in air and in liquid. Immobilization of MTs was achieved by placing a drop of the assembly solution on a polylysine-coated coverslip. After washing with taxol and air drying, the characteristic microtubular fibrous morphology appeared in the SFM.

Effects of the fluorescence dye DAPI on microtubule structure in vitro: formation of novel types of tubulin assembly products.

It has been found that the DNA fluorescence dye 4',6-diamidino-2-phenylindole (DAPI) is able to stain also microtubules. However, electron microscopy revealed that DAPI changed microtubule structure and induced the formation of a broad spectrum of polymorphic tubulin assembly products. Upon addition of DAPI to microtubules assembled from 10 to 15 mumol tubulin (molar DAPI/tubulin ratios of 10 to 40) in the presence of microtubule-associated proteins, most of the microtubules were decorated with additional protofilaments usually running parallel to the protofilaments of the microtubule wall (microtubule-protofilament complexes).

Fluorenone-azomethines, a novel class of microtubule inhibitors that specifically affect cell proliferation.

The effects of various azomethine derivatives on microtubule (MT) assembly in vitro as well as on cell proliferation, cell shape, and the cytoskeleton of some cultured murine cell lines were studied. 3 of them, the alpha-diphenylene-N-(p-[bis-(beta-hydroxyethyl)-amino]-phenyl)-nit rone (DHPN), alpha-diphenylene-N-(p-[N-(hydroxyethyl)-N-(gamma-hydroxypropyl)- amino]-phenyl)-nitrone, and alpha-diphenylene-N-(p-diethylaminophenyl)-nitrone, strongly inhibit the assembly of microtubules (MTs) in vitro (50% inhibition at 4 to 7 mumol/l). The same compounds are also able to disrupt preformed microtubules.

Synergistic cytotoxicity of human recombinant tumour necrosis factor alpha combined with microtubule effectors.

Combinations of human recombinant tumour necrosis factor alpha (rhTNF alpha) with each of four different agents disturbing the microtubule system of the cellular cytoskeleton were tested for synergistic cytotoxic action against murine melanoma B16K and L-M(S) cells. In addition to the known microtubule effectors colchicine, vincristine, and taxol, the influence of the fluorenone-azo-methine derivative alpha-diphenylene-N-(p-[bis-(beta-hydroxyethyl-amino]-phenyl)- nitrone (DHPN) on the rhTNF alpha cytotoxicity was studied. Applying a novel computer-based isobole method [Suehnel J (1990) Antiviral Res 13:23-40] concentration ranges of synergistic, zero, and antagonistic interaction were found after in vitro combination of rhTNF alpha with each of the drugs tested in a 72-h cytotoxicity assay.

Can coated vesicles bind directly to microtubules?

Using an ultrathin-sectioning electron microscopic procedure, no efficient binding of coated vesicles to microtubules (both purified from brain tissue) could be achieved, independently of the presence of microtubule-associated proteins. Addition of the ATP analogue AMP-PNP or the inorganic tripolyphosphate, known to cause tight associations of (uncoated) vesicles to microtubules by means of specific motor proteins, could not enhance the binding efficiency. Moreover, crude preparations of clathrin, the major protein of the coat, did not affect the turbidity course of microtubule assembly.

Measuring of the in-vitro assembly of microtubules by dynamic light scattering.

The kinetics of in-vitro assembly of microtubule protein (MTP) to microtubules (MTs) was followed under various conditions (temperature, GTP, ultrasonic treatment) by dynamic light scattering (DLS) and turbidimetric measurements. The results of both methods roughly coincide, but DLS additionally allows to differentiate between MTs and aggregates and to follow their growth. The complexity of these investigations, however, causes serious restrictions in the interpretation of the DLS data.

Influence of 1,4-benzoquinone derivatives and azomethines on microtubule formation in vitro and experimental leukemias.

Using two groups of substances (derivatives of 1,4-benzoquinone and azomethines) it was compared their effect on the microtubule formation in vitro and on experimental leukemias. 9 from the 28 substances tested acted cancerostatically, 4 substances inhibited microtubule assembly. 3 compounds (fluorenoneazomethines) revealed both effects.

Inhibition of microtubule assembly in vitro by anti-tubulin monoclonal antibodies.

Five monoclonal antibodies against N-terminal domains of alpha- or beta-tubulin were tested for their ability to interfere with the in vitro formation of microtubules. Although all the antibodies exhibited similar association constants for immobilized tubulin, they differed in their inhibitory effect on microtubule assembly. For the most potent antibody, TU-13, the antibody/tubulin molar ratio of about 1:320 was sufficient for a 50% inhibition.

Nucleation of macrotubules on double-walled microtubule seeds.

It is known that histone H1 is able to cause the formation of double-walled microtubules from microtubule protein. Now, we demonstrate that in dependence on the mass ratio H1/microtubule protein upon addition of tubulin to short pieces of double-walled microtubules either their inner or their outer wall elongates resulting in normal microtubules or in macrotubules, respectively. Because of their genesis we suggest that macrotubules like double-walled microtubules (see Unger et al.

Effect of MAP 1, MAP 2, and tau-proteins on structural parameters of tubulin assemblies.

When temperature-dependent recycling procedures for purification were used, tubulin is usually accompanied by a mixture of microtubule-associated proteins (MAPs) primarily comprising MAP 1, MAP 2, and the tau-proteins. Formerly we reported that microtubules formed from tubulin in the presence of these MAPs have more protofilaments than those formed without MAPs. Furthermore, these MAPs suppress the formation of aberrant assemblies (Böhm et al.

[Mechanism of action of alloxan on pancreatic B-cells with special regard to the alloxan-metal-complex theory. II. Actions of alloxan, alloxanic acid, Zn2+ and ethyleneglycol-bis-(beta-aminoethylether)-N,N'tetraacetic acid (EGTA) on the assembly of microtubule proteins (MTP) into microtubules or MPT sheets in vitro].

Analyses of the cell structures in the islets of Langerhans revealed the presence of 2 predominant cations, calcium (beta-granules and saccules, mitochondria, sac membranes, and cell membranes) and zinc (secretory granules, encasing membraneous sacs) in association with organelles which involve directional secretion. Both elements are known to interact with microtubules influencing their structural and functional properties, e.g.

Structural diversity and dynamics of microtubules and polymorphic tubulin assemblies.

Tubulin, the main protein of microtubules (MTs), has the potency of forming a variety of other assembly products in vitro: rings, ring-crystals, C- and S-shaped ribbons, 10 nm fibres, hoops, sheets, heaped sheets, MT doublets, MT triplets, double-wall MTs, microtubules, curled ribbons, and paracrystals. The supramolecular subunits of all of them are the protofilaments which might be arranged either parallel to the axis (e.g.

Structural changes within mixed populations of microtubules and protofilament ribbons caused by dilution and cold incubation.

By means of electron microscopy we have investigated the influence of dilution and cold incubation (0 degree C) on mixed populations of tubulin assemblies consisting of microtubules (MTs) and protofilament ribbons with C- and S-shaped profiles formed in the presence of glycerol. Dilution results in a partial disappearance of ribbons, whereas cold incubation causes a decrease of the percentage of MTs in favour of C-ribbons, probably produced by splitting of MT ends. In the case of dilution, we assume a lower dynamic stability of ribbons compared with MTs, which was already observed during long-time incubation of mixed population (Böhm et al.

Effect of sodium chloride on the structure of tubulin assemblies.

By use of a taxol-containing assembly medium, it has been demonstrated that the mean protofilament number of microtubule populations is significantly lower at elevated NaCl concentrations. Assembly of microtubule protein, i.e.

Determination of the protofilament number in microtubules by templates.

We have used microtubules (MTs) and double-walled microtubules (dwMTs), both fragmented, as templates for MT formation from phosphocellulose-purified tubulin. In both cases the mean protofilament number of the nucleated MTs corresponds to that of the templates. The results confirm the observations of Scheele et al.

Structural comparison of assemblies from brain microtubule proteins of different vertebrates.

Formerly, we reported for microtubule protein (MTP), i.e. tubulin plus microtubule-associated proteins (MAPs), from porcine brain that the protofilament number of microtubules and the percentage of aberrant assemblies depend on taxol and MAP activity (Böhm et al.

Formation of double-walled microtubules and multilayered tubulin sheets by basic proteins.

Some basic proteins enable microtubule protein to form special assembly products in vitro, known as double-walled microtubules. Using histones (H1, core histones) as well as the human encephalitogenic protein to induce the formation of double-walled microtubules, we made the following electron microscopic observations: (1) Double-walled microtubules consist of an "inner" microtubule which is covered by electron-dense material, apparently formed from the basic protein, and by a second tubulin wall. (2) The tubulin of the second wall seems to be arranged as protofilaments, surrounding the inner microtubule in a helical or ring-like manner.