The role of motor proteins in signal propagation.

The signaling and transport systems of eucaryotic cells are tightly interconnected: intracellular transport along microtubules and microfilaments is required to position signaling-pathway components, while signaling molecules control activity of motor proteins and their interaction with tracks and cargoes. Recent data, however, give evidence that active transport is engaged in signaling as a means of signal transduction. This review focuses on this specific aspect of the interaction of two systems.

An isoform of kinesin light chain specific for the Golgi complex.

Conventional kinesin is a motor protein implicated in the transport of a variety of cytoplasmic organelles along microtubules. The kinesin molecule consists of two heavy chains with motor domains at their amino termini and two light chains, which, together with the carboxyl termini of the heavy chains, are proposed to mediate binding to cargoes. Since the light chains are represented by multiple isoforms diverging at their carboxyl termini they are presumed to specify kinesin targeting to organelles. Previously, we isolated five cDNAs, encoding hamster kinesin light chain isoforms, and found that one of them (B or C) preferentially associated with mitochondria. To obtain additional evidence proving the specific location of various kinesin light chain isoforms on organelles, we made an antibody against a 56 amino-acid sequence found at the carboxyl-terminal regions of the hamster D and E isoforms. By indirect immunofluorescence, this antibody specifically labeled the Golgi complex in cultured cells. In western blots of total cell homogenates, it recognized two close polypeptides, one of which co-purified with the Golgi membranes. Thus, the results of this and previous studies demonstrate that different kinesin light chains are associated with different organelles in cells.

A specific light chain of kinesin associates with mitochondria in cultured cells.

The motor protein kinesin is implicated in the intracellular transport of organelles along microtubules. Kinesin light chains (KLCs) have been suggested to mediate the selective binding of kinesin to its cargo. To test this hypothesis, we isolated KLC cDNA clones from a CHO-K1 expression library. Using sequence analysis, they were found to encode five distinct isoforms of KLCs. The primary region of variability lies at the carboxyl termini, which were identical or highly homologous to carboxyl-terminal regions of rat KLC B and C, human KLCs, sea urchin KLC isoforms 1-3, and squid KLCs. To examine whether the KLC isoforms associate with different cytoplasmic organelles, we made an antibody specific for a 10-amino acid sequence unique to B and C isoforms. In an indirect immunofluorescence assay, this antibody specifically labeled mitochondria in cultured CV-1 cells and human skin fibroblasts. On Western blots of total cell homogenates, it recognized a single KLC isoform, which copurified with mitochondria. Taken together, these data indicate a specific association of a particular KLC (B type) with mitochondria, revealing that different KLC isoforms can target kinesin to different cargoes.

Kinesin-associated transport is involved in the regulation of cell adhesion.

It has been recently shown that deploymerization of microtubules induces the elongation of focal contacts at the leading edge. On the other hand, cell shape and pseudopodial activity were found to depend on the microtubule-based motor kinesin. In this paper, we examine whether kinesin is involved in controlling the dynamics of adhesive structures at the cell surface. Microinjection of an antiblocking kinesin activity in vitro causes focal contact elongation similar to the effect of microtubule-depolymerizing drugs. Thus, the role of microtubules in cell adhesion lies in the supporting kinesin-based transport to the adhesion sites.

Microtubule-dependent control of cell shape and pseudopodial activity is inhibited by the antibody to kinesin motor domain.

One of the major functions of cytoplasmic microtubules is their involvement in maintenance of asymmetric cell shape. Microtubules were considered to perform this function working as rigid structural elements. At the same time, microtubules play a critical role in intracellular organelle transport, and this fact raises the possibility that the involvement of microtubules in maintenance of cell shape may be mediated by directed transport of certain cellular components to a limited area of the cell surface (e.g., to the leading edge) rather than by their functioning as a mechanical support. To test this hypothesis we microinjected cultured human fibroblasts with the antibody (called HD antibody) raised against kinesin motor domain highly conserved among the different members of kinesin superfamily. As was shown before this antibody inhibits kinesin-dependent microtubule gliding in vitro and interferes with a number of microtubule-dependent transport processes in living cells. Preimmune IgG fraction was used for control experiments. Injections of fibroblasts with HD antibody but not with preimmune IgG significantly reduced their asymmetry, resulting in loss of long processes and elongated cell shape. In addition, antibody injection suppressed pseudopodial activity at the leading edge of fibroblasts moving into an experimentally made wound. Analysis of membrane organelle distribution showed that kinesin antibody induced clustering of mitochondria in perinuclear region and their withdrawal from peripheral parts of the cytoplasm. HD antibody does not affect either density or distribution of cytoplasmic microtubules. The results of our experiments show that many changes of phenotype induced in cells by microtubule-depolymerizing agents can be mimicked by the inhibition of motor proteins, and therefore microtubule functions in maintaining of the cell shape and polarity are mediated by motor proteins rather than by being provided by rigidity of tubulin polymer itself.

Coalignment of vimentin intermediate filaments with microtubules depends on kinesin.

Intermediate filaments in most types of cultured cells coalign with microtubules. Depolymerization of microtubules results in collapse of vimentin and desmin intermediate filaments to the nucleus where they form a perinuclear cap. Collapse can also be induced by microinjection of antibodies against intermediate filament or microtubule proteins. Thus, two filament systems interact with each other. But the molecules mediating this interaction are unknown. One of the candidates for this role is a microtubule motor kinesin. Recent data showed that kinesin is involved in the plus end-directed movement of the membranous organelles along microtubules such as radial extension of lysosomes in macrophages and centrifugal movement of pigment in melanophores. Here we report that injection of the anti-kinesin antibody into human fibroblasts results in the redistribution of intermediate filaments to a tight perinuclear aggregate but had no effect on the distribution of microtubules. Thus, kinesin is involved not only in organelle movement but also in interaction of the two major cytoskeletal systems, intermediate filaments and microtubules.

Kinesin is responsible for centrifugal movement of pigment granules in melanophores.

Kinesin is a mechanochemical ATPase that induces translocation of latex beads along microtubules and microtubule gliding on a glass surface. This protein is thought to be a motor for the movement of membranous organelles in cells. Recently Hollenbeck and Swanson [Hollenbeck, P. J. & Swanson, J. A. (1990) Nature (London) 346, 864-866] showed that kinesin is involved in the positioning of tubular lysosomes in macrophages. However, the role of this protein in the movement of organelles was not yet clear. We used a polyclonal antibody against the kinesin heavy chain that inhibited kinesin-dependent microtubule gliding in vitro to study the role of kinesin in the movement of pigment granules in melanophores of the teleost black tetra (Gymnocorymbus ternetzi). Microinjection of the antibody into cultured melanophores did not produce any specific effect on the aggregation of pigment granules in melanophores, but it did result in a strong dose-dependent inhibition of the dispersion. Immunoblotting of melanophore extracts showed that the kinesin antibody reacted in these cells with a single protein component with a molecular mass of 135 kDa. Thus, kinesin is responsible for the movement of pigment granules from the center to the periphery of the melanophore.

Microtubule-associated proteins and microtubule-based translocators have different binding sites on tubulin molecule.

It has been previously shown that a class of microtubule proteins, the so-called microtubule-associated proteins (MAPs), binds to the C-terminal part of tubulin subunits. We show here that microtubules composed of tubulin whose 4-kDa C-terminal domain was cleaved by subtilisin (S-microtubules) are unable to bind MAPs but can still bind the anterograde translocator protein kinesin and the retrograde translocator dynein. Binding of both motors to S-microtubules, like their binding to normal microtubules, was ATP-dependent. In addition, direct competition experiments showed that binding sites for kiensin and MAPs on the microtubule surface lattice do not overlap. Furthermore, S-microtubules stimulated the ATPase activity of kinesin at least 8-fold, and the affinities of kinesin for control and S-microtubules were identical. S-microtubules were able to glide along kinesin-coated coverslips at a rate of 0.2 microns/s, the same rate as control microtubules. We conclude, that unlike MAPs, kinesin and cytoplasmic dynein bind to the tubulin molecule outside the C-terminal region.

Vimentin intermediate filaments in fish melanophores.

The distribution and chemical composition of intermediate filaments in cultured melanophores of two teleost species - Gymnocorymbus ternetzi and Pterophyllum scalare - were studied by immunofluorescence staining and immunoblotting techniques. The immunofluorescence staining of the melanophores with monoclonal and polyclonal antibodies to the intermediate filament protein vimentin revealed a system of fibrils radiating from the cell centre. These fibrils were resistant to 0.6 M-KCl and nocodazole treatments as has been found in other cell types. Transmission electron microscopy confirmed the presence of intermediate filaments in melanophores. Immunoblotting experiments showed the presence of the intermediate filament protein vimentin in melanophore lysates. Therefore, teleost melanophores possess a developed radial system of vimentin intermediate filaments.