Characterization of a microtubule-stimulated adenosinetriphosphatase activity associated with microtubule gelation-contraction.

A microtubule-stimulated ATPase is associated with particles that are responsible for microtubule gelation-contraction in vitro. These particles have been proposed to be slow axonal transport, component a, particulates (SCAPs) [Weisenberg, R. C., Flynn, J. J., Gao, B., Awodi, S., Skee, F., Goodman, S., & Riederer, B. (1987) Science (Washington, D.C.) 238, 1119-1122]. The SCAP ATPase activity is stimulated approximately twofold by microtubules. The microtubule-stimulated ATPase activity correlates with the occurrence of microtubule gelation-contraction. Both microtubule-stimulated ATPase activity and microtubule gelation-contraction are inhibited by millimolar calcium, 0.3 M KCl plus 2 mM ethylenediaminetetraacetic acid (EDTA), 5 microM vanadate, and millimolar N-ethylmaleimide (NEM). Neither the ATPase activity nor microtubule gelation-contraction is affected by high magnesium concentrations (up to 8 mM) or by the anti-ATPase drugs ouabain, oligomycin, sodium azide, and erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA). Magnesium is required for both ATPase activity and microtubule gelation-contraction. Microtubule-stimulated hydrolysis of GTP, CTP, ITP, and UTP is less than 50% of ATP hydrolysis, and microtubule gelation-contraction is reduced in these nucleotides. On the basis of these results we propose that the microtubule-stimulated ATPase activity associated with SCAPs is a previously undescribed enzyme that is responsible for microtubule gelation-contraction in vitro and that is the likely motor for component a of slow axonal transport.

Microtubule gelation-contraction in vitro and its relationship to component a of slow axonal transport.

Microtubule proteins, isolated by cycles of assembly, will undergo ATP-dependent gelation-contraction in vitro. A particulate component is present in these preparations, which is required for the gelation-contraction of microtubules assembled from purified tubulin. These particulates contain tubulin, neurofilament, spectrin, MAP2, and other as yet unidentified proteins. The particulates have a microtubule-stimulated ATPase that may be unique and is the likely motor for microtubule gelation-contraction. The basic structural unit of these particulates appears to be a crescent-shaped, or hemispherical, granule about 20 nm in diameter. The particles move along microtubule walls at a rate of about 1 micron. When compared to known physiological phenomena, microtubule gelation-contraction has striking similarities to component a of slow axonal transport (SCa), but displays no relationship to slow component b or to fast transport. On the basis of their similarities in composition, solubility, and rate of movement, we have proposed that the particulates responsible for microtubule gelation-contraction are the insoluble protein complexes, which have been suggested to be the transported component of SCa. We have termed these structures "slow component a particulates" or "SCAPs." It is probable that similar motile protein complexes exist in cells other than neurons, and we propose the term "dynasome" to describe such structures in general.

Microtubule gelation-contraction: essential components and relation to slow axonal transport.

Preparations of microtubule proteins isolated by assembly and disassembly undergo gelation-contraction after addition of adenosine triphosphate (ATP). A particulate fraction from these preparations that is required, along with purified tubulin, to produce ATP-dependent microtubule gelation-contraction in vitro has been isolated. The particulates exhibited microtubule-stimulated adenosine triphosphatase activity and moved slowly (about 1 micrometer per minute) along microtubule walls in the presence of ATP. The particulates contained tubulin, neurofilament, and spectrin polypeptides. The composition, solubility, and motility of the particulates are consistent with those of slow component a of axonal transport.

ATP-dependent formation and motility of aster-like structures with isolated calf brain microtubule proteins.

Microtubule proteins isolated from calf brain will undergo gelation-contraction in the presence of ATP. We have now examined this process by video-enhanced contrast microscopy. After ATP addition to steady-state microtubules, slow (1-5 micron/min), linear movements of particles and microtubules toward aggregation centers occur. The resulting structures resemble mitotic spindle asters. During the time when gel contraction occurs, asters move (at 1-5 micron/min) toward other nearby asters. This is accompanied by the apparent shortening of the microtubules running between the asters. This is the first example of isolated microtubules undergoing a process that has similarities to half-spindle shortening during anaphase A. Formation of aster-like structures without preformed microtubule organizing centers raises the possibility that a similar process may contribute to microtubule organization in vivo.

ATP-induced gelation--contraction of microtubules assembled in vitro.

We report here an ATP-dependent formation and contraction, or syneresis, of a microtubule gel using microtubule proteins prepared from calf brains. Gel contraction is typically observable 15-30 min after ATP addition to microtubules assembled to steady state, and is complete after approximately 60 min, at which time the gel volume is reduced by as much as 75%. In contracted gels, microtubule bundles and aster-like structures are observable. Gelation-contraction requires only microtubule proteins present after purification by three cycles of assembly and disassembly.

Kinetic and steady-state analysis of microtubules in the presence of colchicine.

The effects of colchicine on bovine brain microtubules under steady-state conditions have been studied by combined kinetic and equilibrium analysis. Colchicine induces an initially rapid rate of depolymerization when added to microtubules which are at steady state. The initial rate of disassembly follows the kinetics of colchicine binding to free tubulin. However, disassembly is incomplete, and a new steady-state concentration of microtubules is established provided that a sufficient concentration of colchicine-tubulin is present. When steady state is attained from the disassembly direction, colchicine decreases the formation the fraction of tubulin which is participating in the assembly reaction, without measurably changing the apparent critical concentration for polymerization. The extent of depolymerization of microtubules by colchicine is greater the lower the content of microtubule-associated proteins (MAPs). Microtubules at steady state in the presence of either colchicine or GDP do not exhibit subunit flow which occurs in microtubules at steady state in GTP. Colchicine-tubulin will stabilize microtubules in the presence of MAPs but will not support microtubule elongation. Microtubules at steady state in the presence of colchicine depolymerize upon dilution at about the same rate as untreated microtubules, and, in either case, disassembly appears to occur from both ends of the microtubule. These observations appear to be inconsistent with simple reversible assembly mechanisms but may be explained by a model based upon the cooperative interactions of MAP-tubulin oligomers.

Invited review: the role of nucleotide triphosphate in actin and tubulin assembly and function.

Both actin and tubulin, the major proteins of the cytoskeleton, bind nucleotide triphosphate (NTP) and exhibit the phenomenon of "polymerization-coupled" NTP hydrolysis. In this report I review the nature of polymerization-coupled NTP hydrolysis, and its possible role in the cellular function of actin and tubulin. Polymerization-coupled hydrolysis may be viewed as simply reflecting differences in the NTPase activity of free subunit as compared to polymer. Making assumptions concerning the values of various rate constants, it is possible to write expressions for the effects of NTP hydrolysis on the kinetics of polymerization. The role of NTP hydrolysis may be viewed in at least three different ways: 1) Hydrolysis alters the kinetics of assembly and disassembly. This leads to a consideration of the role of subunit flow in microtubule and microfilament function. 2) Hydrolysis is an essentially irreversible step that separates the assembly and disassembly reactions. This suggests a role of NTP in the regulation of polymer content during cellular cycles of assembly and disassembly. 3) NTP may allow transient stabilization of intersubunit bonds. This suggests a role of NTP in nucleation and possible regulation of nonequilibrium states of assembly.

Tubulin-nucleotide interactions during the polymerization and depolymerization of microtubules.

The interactions of nucleotides and their role in the polymerization of tubulin have been studied in detail. GTP promotes polymerization by binding to the exchangeable site (E site) of tubulin. The microtubules formed contain only GDP at the E site, indicating that hydrolysis of E site GTP occurs during or shortly after polymerization. Tubulin prepared by several cycles of polymerization and depolymerization will polymerize in the presence of ATP as well as GTP. Polymerization in ATP is preceded by a distinct lag period which is shorter at higher concentrations of ATP. As reported by others ATP will transphosphorylate bound GDP to GTP. Under polymerizing conditions the maximum level of GTP formation occurs at about the same time as the onset of polymerization, and the lag probably reflects the time necessary to transphosphorylate a critical concentration of tubulin. The transphosphorylated protein can be isolated and will polymerize without further addition of nucleotide. The transphosphorylated GTP is hydrolyzed and the phosphate released during polymerization. About 25% of the phosphate transferred from ATP is noncovalently bound to the subunit as inorganic phosphate and this fraction is also released during polymerization. The nonhydrolyzable analogue of GTP, GMPPNP, will promote microtubule assembly at high concentration. GMPPNP assembled microtubules do not depolymerize in Ca concentrations several fold greater than that which will completely depolymerize GTP assembled tubules; however, addition of Ca prior to inducing polymerization in GMPPNP prevents the formation of microtubules. Thus GTP hydrolysis appears to promote depolymerization rather than polymerization. GDP does not promote microtubule assembly but can inhibit GTP binding and GTP induced polymerization. GDP does not, however, induce the depolymerization of formed microtubules. These experiments demonstrate that tubulin polymerization can not be treated as a thermodynamically reversible process, but must involve one or more irreversible steps. Exchange experiments with [3H]GTP indicate that the "E" site on both microtubules and ring aggregates of tubulin is blocked and does not exchange rapidly. However, during polymerization and depolymerization induced by raising or lowering the temperature, respectively, all the E sites become transiently available and will exchange their nucleotide. This observation does not suggest a direct morphological transition between rings and microtubules. The presence of a blocked E site on the rings explains the apparent transphosphorylation and hydrolysis of "N" site nucleotide reported by others.

Effects of RNase and RNA on in vitro aster assembly.

RNase alters the in vitro assembly of spindle asters in homogenates of meiotically dividing surf clam (Spisula solidissima) oocytes. Some effects of RNase, such as reduced astral fiber length, appear nonenzymatic and probably result from RNase binding to tubulin. However, RNase-induced changes in the microtubule organizing center are also observed. Since other polycations can mimic RNase effects, the existence of an RNA component of the spindle organizing center remains uncertain. Effects of RNase and other polycations on astral fiber length can be prevented and reversed by the RNase inhibitor, polyguanylic acid. Polyguanylic acid can also augment astral fiber length in the absence of added RNase or other polycations. Augmentation by polyguanylic acid is favored by high ionic strength, and can be duplicated by polyuridylic acid and, with less efficiency, by polyadenylic acid. Polycytidylic acid and unfractionated yeast RNA, however, are unable to augment aster assembly. Polyguanylic acid can also augment the length of astral fibers on complete spindles isolated under polymerizing conditions. These results demonstrate that specific polyribonucleotides can alter spindle assembly in vitro. The presence of an inhibitor of microtubule assembly in Spisula oocytes, which can be inactivated by specific RNAs, is suggested.

In vitro polymerization of microtubules into asters and spindles in homogenates of surf clam eggs.

The eggs of the surf clam Spisula solidissima were artificially activated, homogenized at various times in cold 0.5 M MES buffer, 1mM EGTA at pH 6.5, and microtubule polymerization was induced by raising the temperature to 28 degrees C. In homogenates of unactivated eggs few microtubules form and no asters are observed. By 2.5 min after activation microtubules polymerize in association with a dense central cylinder, resulting in the formation of small asterlike structures. By 4.5 min after activation the asters formed in vitro contain a distinct centriole, and microtubules now radiate from a larger volume of granular material which surrounds the centriole. By 15 min (metaphase I) the granular material is more disperse and only loosely associated with the centriole. Microtubules are occasionally observed which appear to radiate directly from one end of the centriole. The organizing center can be partially isolated by centrifugation of homogenates of metaphase eggs and will induce aster formation if mixed with tubulin from either activated or unactivated eggs. Pretreatment of the eggs with colchicine does not prevent the formation of a functional organizing center. Complete spindles can also be obtained under polymerizing conditions by either homogenizing the eggs directly into warm buffer or by adding a warm high-speed supernate to spindles which have been isolated in a microtubule stabilizing medium. Extensive addition of new tubulin occurs onto the isolated spindles, resulting primarily in growth of astral fibers, although there occasionally appears to be growth of chromosomal fibers and of pole-to-pole fibers. Negatively stained aster microtubules have a strong tendency to associate side by side, and under some conditions distinct cross bridges can be observed. However, under other conditions large numbers of 300-400-A particles surround the microtubules; the presence of stain between particles can give the appearance of cross bridges.

Microtubule formation in vitro in solutions containing low calcium concentrations.

Isolated rat brain tubulin can be repolymerized in vitro in solutions containing adenosine triphosphate or guanosine triphosphate, magnesium ions, and a good calcium chelator. The extreme sensitivity of tubulin to calcium ions explains the failure of previous efforts to obtain polymerization and suggests a possible mechanism for regulation of microtubule polymerization in vivo.

Changes in the organization of tubulin during meiosis in the eggs of the surf clam, Spisula solidissima.

Polymerized tubulin can be stabilized in Kane's spindle isolation medium (HGL solution), isolated by differential centrifugation and then assayed by colchicine binding activity. In the eggs of the surf clam, Spisula solidissima, the level of particulate tubulin undergoes a series of specific changes during first meiotic division. In either unactivated ("interphase") eggs or metaphase eggs the amount of particulate tubulin was about 13% of the total at 23 degrees C. The amount of particulate tubulin decreased shortly after activation, reaching a minimum value at about 5 min, the time of nuclear membrane breakdown. The particulate tubulin concentration then rose, reaching a maximum at metaphase, and then decreased again during anaphase, reaching a minimum at first polar body formation. In HGL homogenates of unactivated eggs a structure is present which has been shown to contain the interphase particulate tubulin (IPT). This structure consists essentially of a 10-20 micro granular sphere attached to a membranous material which is probably part of the egg cortex. These particles are absent at the time of nuclear membrane breakdown, when the level of particulate tubulin is minimal and when the first signs of spindle formation are visible. Electron microscopy of these particles by negative staining indicates that they are composed of microtubules associated with a granular matrix which may be a polymorphic aggregate of tubulin.