Monomer-polymer equilibria in the axon: direct measurement of tubulin and actin as polymer and monomer in axoplasm

The monomer-polymer equilibria for tubulin and actin were analyzed for the cytoskeleton of the squid giant axon. Two methods were evaluated for measuring the concentrations of monomer, soluble (equilibrium) polymer, and stable polymer in extruded axoplasm. One method, the Kinetic Equilibration Paradigm ( KEP ), employs the basic principles of diffusion to distinguish freely diffusible monomer from proteins that are present in the form of polymer. The other method is pharmacological and employs either taxol or phalloidin to stabilize the microtubules and microfilaments, respectively. The results of the two methods agree and demonstrate that 22-36% of the tubulin and 41-47% of the actin are monomeric. The in vivo concentration of monomeric actin and tubulin were two to three times higher than the concentration required to polymerize these proteins in vitro, suggesting that assembly of these proteins is regulated by additional mechanisms in the axon. A significant fraction of the polymerized actin and tubulin in the axoplasm was stable microtubules and microfilaments, which suggests that the dissociation reaction is blocked at both ends of these polymers. These results are discussed in relationship to the axonal transport of the cytoskeleton and with regard to the ability of axons to change their shape in response to environmental stimuli.     

A calcium-activated protease which preferentially degrades the 160-kDa component of the neurofilament triplet

A calcium-dependent protease fully active with 0.2 mM Ca2+ was found associated with the neurofilament-enriched cytoskeleton of the rat spinal cord prepared by the treatment with Triton X-100. The enzyme preferentially degrades the 160-kDa component of the neurofilament triplet. In addition, a soluble calcium-dependent protease activity was found in the supernatant from the spinal cord, which degraded a variety of cytoskeletal proteins including the neurofilament triplet, glial fibrillary acidic (GFA) protein, actin, tubulin, and a high molecular weight protein associated with microtubules. The possibility that the cytoskeleton-bound activity is an artefactual association of the soluble enzyme to the cytoskeleton seems to be negated on the basis of the following dissociation and reassociation experiments. The protease activity remained associated with the cytoskeleton in the physiological ionic strength, and was not completely dissociated from it until the KC1 concentration was raised to 0.6 M. When the 0.6 M KCl-extract was dialysed against salt-free buffer to remove KC1, and added back to the protease-free cytoskeletal pellet, proteolytic activity was partially restored. Full activity returned only when the extract and the protease-free cytoskeletal pellet were first combined in the presence of 0.6 M KC1, and then slowly reassociated by dialysis against salt-free buffer. Dissociated enzyme was rapidly inactivated at 37 degrees C in the presence of Ca2+. These results suggest the structural association of the protease with the cytoskeleton under the physiological condition.     

Characterization of a cyclic nucleotide- and calcium-independent neurofilament protein kinase activity in axoplasm from the squid giant axon

The phosphorylation activity associated with a neurofilament-enriched cytoskeletal preparation isolated from the squid giant axon has been studied and compared to the phosphorylation activities in intact squid axoplasm. The high molecular weight (greater than 300 kDa) and 220-kDa neurofilament proteins are the major endogenous substrates for the kinases in the axoplasm and the neurofilament preparation, whereas 95- and less than 60-kDa proteins are the major phosphoproteins in the ganglion cell preparation. The squid axon neurofilament (SANF) protein kinase activity appeared to be both cAMP and Ca2+ independent and could phosphorylate both casein (Km = 40 microM) and histone (Km = 180 microM). The SANF protein kinase could utilize either ATP or GTP in the phosphotransferase reaction, with a Km for ATP of 58 microM and 129.4 microM for GTP when casein was used as the exogenous substrate; and 25 and 98.1 microM for ATP and GTP, respectively, when the endogenous neurofilament proteins were used as substrates. The SANF protein kinase activity was only slightly inhibited by 2,3-diphosphoglycerate and various polyamines at high concentrations and was poorly inhibited by heparin (34% inhibition at 100 micrograms/ml). The failures of heparin to significantly inhibit and the polyamines to stimulate the SANF protein kinase indicate that it is not a casein type II kinase. The relative efficacy of GTP as a phosphate donor indicates that SANF protein kinase differs from known casein type I kinases. Phosphorylated (32P-labeled) neurofilament proteins were only slightly dephosphorylated in the presence of axoplasm or stellate ganglion cell supernatants, and the neurofilament-enriched preparation did not dephosphorylate 32P-labeled neurofilament proteins. The axoplasm and neurofilament preparations had no detectable protein kinase inhibitor activity, but a strong inhibitor activity, which was not dialyzable but was heat inactivatable, was found in ganglion cells. This inhibitor activity may account for the low phosphorylation activity found in the stellate ganglion cells and may indicate inhibitory regulation of SANF protein kinase activity in the ganglion cell bodies.     

Two 68-kDa Proteins in Slow Axonal Transport Belong to the 70-kDa Heat Shock Protein Family and the Annexin Family

The major 68-kDa protein found selectively in the faster of the two subcomponents of slow axonal transport [group IV or slow component b (SCb)] in the rat sciatic nerve has been characterized. It was found to contain two distinct classes of proteins, S1 and S2, both of which have isoelectric points of 5.7, but differ in their solubility in the presence of calcium. The S1 protein, which contributes up to 70% of the 68-kDa component, was soluble in the presence or absence of calcium, whereas the S2 protein was bound to the cytoskeleton in a calcium-dependent manner. Further characterization of the two proteins by peptide mapping and immunological methods revealed that the S1 protein belonged to a family of proteins related to the 70-kDa heat shock protein, whereas the S2 protein was identical to 68-kDa calelectrin (annexin VI). Selective occurrence in SCb of these proteins with potential abilities to regulate protein-protein or protein-membrane interactions suggests that they may play important roles in the control of cytoskeletal organization in the axon, because SCb contains mainly cytoskeletal proteins in a more dynamic form compared with the slowest rate component, slow component a, which is enriched in the stably polymerized form of these proteins.     

Many cytoskeletal proteins associate with the hela cytoskeleton during translation in vitro

Observations that cytoskeletal proteins assemble in vivo close to the time and site of synthesis have been confirmed and extended by an in vitro translation system. HeLa cytoskeletons prepared with Triton in a translation-extraction buffer without reticulocyte or wheat germ lysate efficiently incorporate 35S-methionine into polypeptides, and are stable during this translation. Cytoskeletal proteins translated in this way associate with the HeLa cytoskeleton independent of the concentration of soluble proteins. These associations are puromycin-resistant before the proteins are complete; the protein associations made in vitro show only minor differences from those made in vivo. The protein associations are not simply a consequence of protein solubility in the buffers used, as the associations require initiation in vivo. These results indicate that many cytoskeletal proteins associate with the cytoskeleton during translation.     

The actin cytoskeleton is required for maintenance of posterior pole plasm components in the Drosophila embryo.

Localization of mRNAs is one of many aspects of cellular organization that requires the cytoskeleton. In Drosophila, microtubules are known to be required for correct localization of developmentally important mRNAs and proteins during oogenesis; however, the role of the actin cytoskeleton in localization is less clear. Furthermore, it is not known whether either of these cytoskeletal systems are necessary for maintenance of RNA localization in the early embryo. We have examined the contribution of the actin and microtubule cytoskeletons to maintenance of RNA and protein localization in the early Drosophila embryo. We have found that while microtubules are not necessary, the actin cytoskeleton is needed for stable association of nanos, oskar, germ cell-less and cyclin B mRNAs and Oskar and Vasa proteins at the posterior pole in the early embryo. In contrast, bicoid RNA, which is located at the anterior pole, does not require either cytoskeletal system to remain at the anterior.     

Water and the cytoskeleton.

The diffusion of intracellular fluid and solutes is mainly limited by the density and the geometry of crossbridges between cytoskeletal polymers mediating the formation of an integrated cytoplasmic scaffold. Evidence for specific relationships between water and cytoskeletal polymers arises from the effect of heavy water on their polymerization process in vitro and on the cytoskeleton of living cells. The hydration of cytoskeletal subunits is modified through polymerization, a mechanism which may be involved in the direct contribution of the cytoskeleton to the osmotic properties of cells together with changes of hydration of polymers within networks. The dynamic properties of the hydration layer of cytoskeletal polymers may reflect the repetitive distribution of the surface charges of subunits within the polymer lattice, thus inducing a local and long range ordering of the diffusion flows of water and solutes inside polymer networks. The interactions between subunits in protofilaments and between protofilaments determine the specific viscoelastic properties of each type of polymer, regulated by associated proteins, and the mechanical properties of the cell through the formation of bundles and gels. Individual polymers are interconnected into dynamic networks through crossbridging by structural associated proteins and molecular motors, the activity of which involves cooperative interactions with the polymer lattice and likely the occurence of coordinated modifications of the hydration layer of the polymer surface. The cytoskeletal polymers are polyelectrolytes which constitute a large intracellular surface of condensed anionic charges and form a buffering structure for the sequestration of cations involved in the regulation of intracellular events. This property allows also the association of cytoplasmic enzymes and multimolecular complexes with the cytoskeleton, facilitating metabolic channelling and the localization of these complexes in specific subdomains of the cytoplasm. The consequences of interactions between membranes and the cytoskeleton in all cellular compartments range from the local immobilization and clustering of lipids and membrane proteins to the regulation of water and ion flows by the association of cytoskeletal subunits or polymers with transmembrane channels. The possibility that the polyelectrolyte properties of the cytoskeletal polymers contribute to the modulation of membrane potentials supports the hypothesis of a direct involvement of the cytoskeleton in intercellular communications.     

Early structural changes in the axoplasmic cytoskeleton after axotomy studied by cryofixation

Summary Alterations in the cytoskeleton were studied in the axoplasm of neurites at the tips of proximal stumps of transected chicken sciatic nerves. The studies were carried out using cryofixation with a nitrogen-cooled propane jet. The most immediate effect is the almost complete disassembly of axoplasmic microtubules. This consequently causes the axonal transport of membrane-bounded organelles to cease and results in an accumulation of mitochondria and vesicles of the smooth endoplasmic reticulum. The neurofilament network is partially disorganized. Neurofilaments become shorter and fragmented, and are linked by a large number of anastomosed cross-linkers. The neurofilaments become newly aligned to the axis of the axoplasm and are of normal length 48–72 h after the transsection. At this stage the newly formed neurofilament bundles are in close proximity to the anastomosed cisternae and profiles of the smooth endoplasmic reticulum. The axonal sprouts always show a normally organized cytoskeletal network. These studies support the idea that the rapid remodelling of the neurofilament network is apparently a local event, not dependent on the slow transport of cytoskeletal materials to the tip of the proximal stump. The repair of the degraded cytoskeleton may be in accordance with the function of the endoplasmic reticulum as Ca²⁺-sequestering membrane system, which may be involved in restoring the physiological conditions of the axoplasm.     

A method for analysis of the detergent-resistant cytoskeleton of cells within organs

We describe a method for the preparation of the detergent-resistant cytoskeleton and nuclear matrix of cells within organs and tissues. Such cells were previously inaccessible to study because the three-dimensional organization of cells in organs prevented uniform distribution of the detergent throughout the multiple cell layers. We use the method presented here to compare the proteins present in the cytoskeleton, nuclear matrix and soluble fractions of cells from different histotypes. SDS-gel analysis demonstrates that soluble and nuclear matrix proteins differ greatly between histotypes while cytoskeletal proteins are relatively similar. Immunocytochemical analysis of tissue prepared using this procedure also demonstrates that the intracellular structure of cells within organs differs from that of in vitro cultured cells.     

Calcium-Activated Proteolysis of Neurofilament Proteins in the Squid Giant Neuron

The phosphorylation and proteolysis of squid neurofilament proteins by endogenous kinase and calcium-activated protease activities, respectively, were studied. When axoplasm was incubated in the presence of [gamma-32P]ATP, most of the phosphate was incorporated into two neurofilament proteins: a 220-kilodalton (NF-220) and a high-molecular-weight (HMW) protein. When this phosphorylated axoplasm was subjected to endogenous calcium-activated proteolysis, two significant phosphorylated fragments were generated, i.e., a soluble 110K fragment and a pelletable 100K fragment. Immunochemical and other analyses suggest that the pelletable 100K fragment contains the common helical neurofilament rod region and that the soluble 110K protein is the putative side arm of the NF-220. In contrast, neither the HMW or the NF-220 was detected in the region of the stellate ganglion which contains the cell bodies of the giant axon. However, this region did contain a number of proteins that were sensitive to calcium-activated proteolysis and reacted with a monoclonal intermediate filament antibody. This intermediate filament antibody reacts with most of the axoplasmic proteins that copurify with neurofilaments, i.e., in the order of their intermediate filament antibody staining intensity, a 60K, 65K, 220K, and 74K protein. In the cell body preparation, the intermediate filament antibody labeled, in order of their staining intensity, a 65K, 60K, 74K, and 180K protein. In both the axoplasmic and cell body preparations, endogenous calcium-activated proteolysis generated characteristic fragments that could be labeled with the anti-intermediate filament antibody.     

Cell Shape Can Mediate the Spatial Organization of the Bacterial Cytoskeleton

The bacterial cytoskeleton guides the synthesis of cell wall and thus regulates cell shape. Because spatial patterning of the bacterial cytoskeleton is critical to the proper control of cell shape, it is important to ask how the cytoskeleton spatially self-organizes in the first place. In this work, we develop a quantitative model to account for the various spatial patterns adopted by bacterial cytoskeletal proteins, especially the orientation and length of cytoskeletal filaments such as FtsZ and MreB in rod-shaped cells. We show that the combined mechanical energy of membrane bending, membrane pinning, and filament bending of a membrane-attached cytoskeletal filament can be sufficient to prescribe orientation, e.g., circumferential for FtsZ or helical for MreB, with the accuracy of orientation increasing with the length of the cytoskeletal filament. Moreover, the mechanical energy can compete with the chemical energy of cytoskeletal polymerization to regulate filament length. Notably, we predict a conformational transition with increasing polymer length from smoothly curved to end-bent polymers. Finally, the mechanical energy also results in a mutual attraction among polymers on the same membrane, which could facilitate tight polymer spacing or bundling. The predictions of the model can be verified through genetic, microscopic, and microfluidic approaches.     

Cytoskeletal changes in platelets induced by thrombin and phorbol myristate acetate (PMA).

Changes in shape, and aggregation that accompanies platelet activation, are dependent on the assembly and reorganization of the cytoskeleton. To assess the changes in cytoskeleton induced by thrombin and PMA, suspensions of aspirin-treated,32P-prelabeled, washed pig platelets in Hepes buffer containing ADP scavengers were activated with thrombin, and with PMA, an activator of protein kinase C. The cytoskeletal fraction was prepared by adding Triton extraction buffer. The Triton-insoluble (cytoskeletal) fraction isolated by centrifugation was analysed by SDS-PAGE and autoradiography. Incorporation of actin into the Triton-insoluble fraction was used to quantify the formation of F-actin. Thrombin-stimulated platelet cytoskeletal composition was different from PMA-stimulated cytoskeletal composition. Thrombin-stimulated platelets contained not only the three major proteins: actin (43 kDa), myosin (200 kDa) and an actin-binding protein (250 kDa), but three additional proteins of Mr56 kDa, 80 kDa and 85 kDa in the cytoskeleton, which were induced in by thrombin dose-response relationship. In contrast, PMA-stimulated platelets only induced actin assembly, and the 56 kDa, 80 kDa and 85 kDa proteins were not found in the cytoskeletal fraction. Exposure of platelets to thrombin or PMA induced phosphorylation of pleckstrin parallel to actin assembly. Staurosporine, an inhibitor of protein kinase C, inhibited actin assembly and platelet aggregation induced by thrombin or PMA, but did not inhibit the incorporation of 56 kDa, 80 kDa and 85 kDa into the cytoskeletal fraction induced by thrombin. These three extra proteins seem to be unrelated to the induction of protein kinase C. We conclude that actin polymerization and platelet aggregation were induced by a mechanism dependent on protein kinase C, and suggest that thrombin-activated platelets aggregation could involve additional cytoskeletal components (56 kDa, 80 kDa, 85 kDa) of the cytoskeleton, which made stronger actin polymerization and platelet aggregation more.     

Neurofilament protein is phosphorylated in the squid giant axon

We have observed the phosphorylation of neurofilament protein from squid axoplasm. Phosphorylation is demonstrated by 32P labeling of protein during incubation of axoplasm with [gamma-32P]ATP. When the labeled proteins are separated by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), two bands, at 2.0 x 10(5) daltons and greater than 4 x 10(5) daltons, contain the bulk of the 32P. The 2.0 x 10(5)-dalton phosphorylated polypeptide comigrates on SDS-PAGE with one of the subunits of squid neurofilament protein. Both major phosphorylated polypeptides co-fractionate with neurofilaments in discontinuous sucrose gradient centrifugation and on gel filtration chromatography on Sepharose 4B. The protein-phosphate bond behaves like a phospho-ester, and labeled phospho-serine is identified in an acid hydrolysate of the protein. The generality of this phenomenon in various species and its possible physiological significance are discussed.     

Topographic regulation of cytoskeletal protein phosphorylation by multimeric complexes in the squid giant fiber system

In mammalian and squid nervous systems, the phosphorylation of neurofilament proteins (NFs) seems to be topographically regulated. Although NFs and relevant kinases are synthesized in cell bodies, phosphorylation of NFs, particularly in the lys‐ser‐pro (KSP) repeats in NF‐M and NF‐H tail domains, seem to be restricted to axons. To explore the factors regulating the cellular compartmentalization of NF phosphorylation, we separated cell bodies (GFL) from axons in the squid stellate ganglion and compared the kinase activity in the respective lysates. Although total kinase activity was similar in each lysate, the profile of endogenous phosphorylated substrates was strikingly different. Neurofilament protein 220 (NF220), high‐molecular‐weight NF protein (HMW), and tubulin were the principal phosphorylated substrates in axoplasm, while tubulin was the principal GFL phosphorylated substrate, in addition to highly phosphorylated low‐molecular‐weight proteins. Western blot analysis showed that whereas both lysates contained similar kinases and cytoskeletal proteins, phosphorylated NF220 and HMW were completely absent from the GFL lysate. These differences were highlighted by P13^suc1 affinity chromatography, which revealed in axoplasm an active multimeric phosphorylation complex(es), enriched in cytoskeletal proteins and kinases; the equivalent P13 GFL complex exhibited six to 20 times less endogenous and exogenous phosphorylation activity, respectively, contained fewer cytoskeletal proteins and kinases, and expressed a qualitatively different cdc2‐like kinase epitope, 34 kDa rather than 49 kDa. Cell bodies and axons share a similar repertoire of molecular consitutents; however, the data suggest that the cytoskeletal/kinase phosphorylation complexes extracted from each cellular compartment by P13 are fundamentally different. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 89–102, 1999     

Topographic regulation of phosphorylation in giant neurons of the squid, Loligo pealei: role of phosphatases

In previous studies of phosphorylation in squid stellate ganglion neurons, we demonstrated that a specific multimeric phosphorylation complex characterized each cellular compartment. Although the endogenous protein profile of cell body extracts (giant fiber lobe, GFL), as determined by Coomassie staining, was similar to that of axoplasm from the giant axon, in this study we show that the protein phosphorylation profiles are qualitatively different. Whereas many axoplasm proteins were phosphorylated, including most cytoskeletal proteins, virtually all phosphorylation in perikarya was confined to low molecular weight compounds (<6 kDa). Because phosphorylation of exogenous substrates, histone and casein, was equally active in extracts from both compartments, failure to detect endogenous protein phosphorylation in cell bodies was attributed to the presence of more active phosphatases. To further explore the role of phosphatases in these neurons, we studied phosphorylation in the presence of serine/threonine and protein tyrosine phosphatase (PTP) inhibitors. We found that phosphorylation of axonal cytoskeletal proteins was modulated by okadaic acid-sensitive ser/thr phosphatases, whereas cell body phosphorylation was more sensitive to an inhibitor of protein tyrosine phosphatases, such as vanadate. Inhibition of PTPs by vanadate stimulated endogenous phosphorylation of GFL proteins, including cytoskeletal proteins. Protein tyrosine kinase activity was equally stimulated by vanadate in cell body and axonal whole homogenates and Triton X-100 free soluble extracts, but only the Triton X soluble fraction (membrane bound proteins) of the GFL exhibited significant activation in the presence of vanadate, suggesting higher PTP activities in this fraction than in the axon. The data are consistent with the hypothesis that neuronal protein phosphorylation in axons and cell bodies is modulated by different phosphatases associated with compartment-specific multimeric complexes.     

Changes in Organization and Axonal Transport of Cytoskeletal Proteins During Regeneration

Changes in solubility and transport rate of cytoskeletal proteins during regeneration were studied in the motor fibers of the rat sciatic nerve. Nerves were injured by freezing at the midthigh level either 1-2 weeks before (experiment I) or 1 week after radioactive labeling of the spinal cord with L-[35S]methionine (experiment II). Labeled proteins in 6-mm consecutive segments of the nerve 2 weeks after labeling were analyzed following fractionation into soluble and insoluble populations with 1% Triton at 4 degrees C. When axonal transport of newly synthesized cytoskeleton was examined in the regenerating nerve in experiment I, a new faster component enriched in soluble tubulin and actin was observed that was not present in the control nerve. The rate of the slower main component containing most of the insoluble tubulin and actin together with neurofilament proteins was not affected. A smaller but significant peak of radioactivity enriched in soluble tubulin and actin was also detected ahead of the main peak when the response of the preexisting cytoskeleton was examined in experiment II. It is thus concluded that during regeneration changes in the organization take place in both the newly synthesized and the preexisting axonal cytoskeleton, resulting in a selective acceleration in rate of transport of soluble tubulin and actin.     

Epithelial cytoskeletal framework and nuclear matrix-intermediate filament scaffold: three-dimensional organization and protein composition

Madin-Darby canine kidney (MDCK) cells grow as differentiated, epithelial colonies that display tissue-like organization. We examined the structural elements underlying the colony morphology in situ using three consecutive extractions that produce well-defined fractions for both microscopy and biochemical analysis. First, soluble proteins and phospholipid were removed with Triton X-100 in a physiological buffer. The resulting skeletal framework retained nuclei, dense cytoplasmic filament networks, intercellular junctional complexes, and apical microvillar structures. Scanning electron microscopy showed that the apical cell morphology is largely unaltered by detergent extraction. Residual desmosomes, as can be seen in thin sections, were also well- preserved. The skeletal framework was visualized in three dimensions as an unembedded whole mount that revealed the filament networks that were masked in Epon-embedded thin sections of the same preparation. The topography of cytoskeletal filaments was relatively constant throughout the epithelial sheet, particularly across intercellular borders. This ordering of epithelial skeletal filaments across contiguous cell boundaries was in sharp contrast to the more independent organization of networks in autonomous cells such as fibroblasts. Further extraction removed the proteins of the salt-labile cytoskeleton and the chromatin as separate fractions, and left the nuclear matrix-intermediate filament (NM-IF) scaffold. The NM-IF contained only 5% of total cellular protein, but whole mount transmission electron microscopy and immunofluorescence showed that this scaffold was organized as in the intact epithelium. Immunoblots demonstrate that vimentin, cytokeratins, desmosomal proteins, and a 52,000-mol-wt nuclear matrix protein were found almost exclusively in the NM-IF scaffold. Vimentin was largely perinuclear while the cytokeratins were localized at the cell borders. The 52,000-mol-wt nuclear matrix protein was confined to the chromatin- depleted matrix and the desmosomal proteins were observed in punctate polygonal arrays at intercellular junctions. The filaments of the NM-IF were seen to be interconnected, via the desmosomes, over the entire epithelial colony. The differentiated epithelial morphology was reflected in both the cytoskeletal framework and the NM-IF scaffold.     

The push and pull of the bacterial cytoskeleton

A crucial function for eukaryotic cytoskeletal filaments is to organize the intracellular space: facilitate communication across the cell and enable the active transport of cellular components. It was assumed for many years that the small size of the bacterial cell eliminates the need for a cytoskeleton, because simple diffusion of proteins is rapid over micron-scale distances. However, in the last decade, cytoskeletal proteins have indeed been found to exist in bacteria where they have an important role in organizing the bacterial cell. Here, we review the progress that has been made towards understanding the mechanisms by which bacterial cytoskeletal proteins influence cellular organization. These discoveries have advanced our understanding of bacterial physiology and provided insight into the evolution of the eukaryotic cytoskeleton.     

Cytoskeletal reorganization during early mammalian development: analysis using embedment-free sections

We have examined cytoskeletal reorganization during early embryonic development in the hamster by employing detergent extraction to remove soluble components of the embryos and reveal the underlying structural network. This procedure allows examination of both the cortical cytoskeleton and the cytoskeleton of the egg interior. Sections of eggs and embryos were prepared for transmission electron microscopy with the removable embedding medium, diethylene glycol disterate which allows thicker sections than conventional embedment procedures thereby providing more spatial cues for studying organization. The cytoskeleton reorganizes after fertilization, at the time of compaction and again at the blastocyst stage. These cytoskeletal reorganizations are considered in terms of the blastomere polarity hypothesis and the involvement of the cytoskeleton with early embryonic development.     

A bacterial linear motor: cellular and molecular organization of the contractile cytoskeleton of the helical bacterium Spiroplasma melliferum BC3

The Mollicutes (Mycoplasma, Acholeplasma, and Spiroplasma) are the smallest, simplest and most primitive free-living and self-replicating known cells. These bacteria have evolved from Clostridia by regressive evolution and genome reduction to the range of 5.8 x 10(5)-2.2 x 10(6) basepairs (bp). Structurally, the Mollicutes completely lack cell walls and are enveloped by only a cholesterol containing cell membrane. The Mollicutes contain what can be defined as a bacterial cytoskeleton. The Spiroplasmas are unique in having a well-defined, dynamic, helical cell geometry and a flat, monolayered, membrane-bound cytoskeleton, which follows, intracellularly, the shortest helical line on the cellular coil. By applying cryo-electron-microscopy to whole cells, isolated cytoskeletons and cytoskeletal fibrils and subunits, as well as by selective extraction of cellular components, we determined, at a resolution of approximately 25 A, the cellular and molecular organization of the cytoskeleton. The cytoskeleton is assembled from a 59 kDa protein. The 59 kDa protein, has an equivalent sphere diameter of approximately 50 A. Given the approximately 100 A axial and lateral spacings in the cytoskeletal ribbons and the near-circular shape of the subunit, we suggest that the subunit is a tetramer of 59 kDa monomers; the tetramers assemble further into flat fibrils, seven of which form a flat, monolayered, well-ordered ribbon. The cytoskeleton may function as a linear motor by differential and coordinated length-changes of the fibrils driven by conformational changes of the tetrameric subunits, the shape of which changes from near circular to elliptical. The cytoskeleton controls both the dynamic helical shape and the consequent motility of the cell. A stable cluster of proteins co-purifies with the cytoskeleton. These apparent membrane and membrane-associated proteins may function as anchor proteins.