Evidence for rapid structural and functional changes of the melanophore microtubule-organizing center upon pigment movements

Melanophores of the angelfish, pterophyllum scalare, have previously been shown to display approximately 2,400 microtubules in cells wih pigment dispersed; these microtubules radiate from a presumptive organizing center, the central apparatus (CA), and their number is reduced to approximately 1,000 in the state with aggregated pigment (M. Schliwa and U. Euteneuer, 1978, J. Supramol. Struct. 8:177-190). In an attempt to elucidate the factors controlling this rapid reorganization of the microtubule apparatus, structure and function of the CA have been investigated under different physiological conditions. As a function of the state of pigment distribution, melanophores differ markedly with respect to CA organization. A complex of dense amorphous aggregates and associated fuzzy material, several micrometers in diameter, surrounds the centrioles in cells with pigment dispersed, and numerous microtubules emanate from this complex in a radial fashion. In the aggregated state, on the other hand, few microtubules are observed in the pericentiolar region, and the amount of fibrous material is greatly reduced. These changes in CA morphology as a function of the state of pigment distribution are associated with a marked difference in its capacity to initiatiate the assembly of microtubules from exogenous pure porcine brain tubulin in lysed cell preparations. After complete removal of preexisting microtubules, cells lysed in the dispersed state into a solution of 1-2 mg/ml pure tubulin have numerous microtubules associated with the CA in radial fashion, while cells lysed in the aggregated state nucleate the assembly of only a few microtubules. We conclude that it is the activity of the CA that basically regulates the expression of microtubules. This regulation is achieved through a variation in the capacity to initiate microtubule assembly. Increase or decrease in the amount of dense material, as readily observed in the cell system studied here, seems to be a morphologic expression of such a physiologic function.     

Firm structural associations between migratory pigment granules and microtubules in crayfish retinula cells

The morphology of associations between mobile pigment granules and microtubules of the crayfish retinula cells was examined with transmission electron microscopy. Many pigment granules were found associated with microtubules through linkages of fuzzy appearance in thin sections. The linkages were revealed as discrete strands of variable shape in rotary-shadowed replicas of freeze-fractured and deep- etched specimens. The only feature of constant morphology among these connections consisted of 2-4-nm filaments projecting laterally from the microtubules. The firmness of the pigment granule-microtubule associations was judged by their ability to hold up during cell disruption procedures of increasing disaggregation effects in a low- Ca++ stabilization buffer. The results of these tests were inspected with scanning electron microscopy and with transmission electron microscopy of negatively stained preparations. Numerous pigment granules remained associated with a stable microtubule framework after the plasma membrane had been stripped away. Moreover, granule- microtubule attachments survived breakdown of this framework into free fascicles of microtubules. The pigment granules were associated with the free microtubules either individually or as clusters entangled in a fibrous material interwoven with 10-nm filaments. These findings attest that many pigment granules are bound to microtubules through linkages that constitute effective attachments. Further, it is demonstrated that a highly cohesive substance associates the pigment granules with one another. These conclusions are discussed in terms of a pigment transport mechanism in which a network of interconnected granules would establish firm transient interactions with a supporting skeleton of microtubules.     

The oral apparatus of Tetrahymena pyriformis, strain WH-6. IV. Observations on the organization of microtubules and filaments in the isolated oral apparatus and the differential effect of potassium chloride on the stability of oral apparatus microtubules.

This report is an ultrastructural analysis of the organization of the isolated oral apparatus of Tetrahymena pyriformis, strain WH-6, syngen 1. Attention has been focused on the organization of microtubules and filaments in oral apparatus membranelles. Oral apparatus membranellar basal bodies were characterized with respect to structural differentiations at the distal and proximal ends. The distal region of membranellar basal bodies contains the basal plate, accessory microtubules and filaments. The proximal end contains a dense material from which emanate accessory microtubules and filaments. There are at least two possibly three different arrangements of accessory structures at the proximal end of membranellar basal bodies. All membranellar basal bodies appear to have a dense material at the proximal end from which filaments emanate. Some of these basal bodies have accessory microtubules and filaments emanating from this dense material. A possible third arrangement is represented by basal bodies which have lateral projections, from the proximal end, of accessory microtubules and filaments which constitute cross or peripheral connectives. There are at least three examples of direct associations between oral apparatus microtubules and filaments: (1) filaments which form links between basal body triplet microtubules, (2) filaments which link the material of the basal plate to internal basal body microtubules, (3) filaments which link together microtubule bundles from membranellar connectives. KCl extraction of the isolated oral apparatus resulted in the selective solubilization of oral apparatus basal bodies, remnants of ciliary axonemes and fused basal plates. Based on their response to KCl extraction two distinct sets of morphologically similar micro tubules can be identified: (a) microtubules which constitute the internal structure of basal bodies and ciliary axonemes, (b) microtubules which constitute the fiber connectives between basal bodies.     

胎脑提取液对衰老小鼠大脑皮质神经元的影响

目的 观察胎脑提取液对衰老小鼠大脑皮质神经元酸性磷酸酶(ACP)活性和尼氏体含量的影响,探讨胎脑提取液的抗衰老作用。方法 选用健康昆明种小白鼠30只,随机分为3组;采用D-半乳糖制备亚急性衰老模型;组织化学方法显示大脑皮质神经元内的酸性磷酸酶(ACP)和尼氏体;显微图像分析仪进行定量分析。结果 衰老模型组与正常对照组相比,小鼠大脑皮质神经元ACP活性明显升高,尼氏体含量明显减少;给药组与衰老模型组相比,小鼠大脑皮质神经元ACP活性明显降低,尼氏体含量明显增加。结论 胎脑提取液可以稳定大脑皮质神经元的内环境,减少神经元的损伤,促进神经元蛋白质的合成,具有一定的抗衰老作用。     

Changes in organization and microtubule assembly activity of the centrosome during lymphocyte stimulation

Changes in the organization of centrosomes in mouse splenic T lymphocytes stimulated by concanavalin A (con A) were examined by electron microscopy of serial sections. In both resting and stimulated lymphocytes the single centrosome consists of a pair of centrioles, satellite bodies, and pericentriolar material. In resting cell centrosomes the satellite bodies are preferentially associated with, and appear to be attached by short stalks to, one of the centrioles. The satellite bodies are the primary sites of microtubule termination in the resting cell centrosome. During stimulation by con A there is a several-fold increase in microtubule content. This is correlated with an overall increase in centrosome size, an apparent increase in the size and in the number of satellite bodies, and a redistribution of satellite bodies to occupy a position between the two centrioles. Increased numbers of microtubules are detected terminating on the satellite bodies and in the pericentriolar material of the stimulated cell centrosome. Microtubule assembly from centrosomes in vitro was assessed by electron microscopy using detergent-permeabilized lymphocytes that had been pretreated to remove endogenous microtubules and supplied with purified bovine brain tubulin. These studies indicate that satellite bodies are major sites of microtubule assembly in both resting and stimulated cell centrosomes and show that the centrosomes of stimulated cells assemble more microtubules in vitro than resting cell centrosomes. This parallels the increase in microtubule content in intact lymphocytes stimulated by con A and suggests that the changes in centrosome organization and microtubule assembly capacity that occur during stimulation are causally related.     

Changes in organization and microtubule assembly activity of the centrosome during lymphocyte stimulation

Changes in the organization of centrosomes in mouse splenic T lymphocytes stimulated by concanavalin A (con A) were examined by electron microscopy of serial sections. In both resting and stimulated lymphocytes the single centrosome consists of a pair of centrioles, satellite bodies, and pericentriolar material. In resting cell centrosomes the satellite bodies are preferentially associated with, and appear to be attached by short stalks to, one of the centrioles. The satellite bodies are the primary sites of microtubule termination in the resting cell centrosome. During stimulation by con A there is a several-fold increase in microtubule content. This is correlated with an overall increase in centrosome size, an apparent increase in the size and in the number of satellite bodies, and a redistribution of satellite bodies to occupy a position between the two centrioles. Increased numbers of microtubules are detected terminating on the satellite bodies and in the pericentriolar material of the stimulated cell centrosome. Microtubule assembly from centrosomes in vitro was assessed by electron microscopy using detergent-permeabilized lymphocytes that had been pretreated to remove endogenous microtubules and supplied with purified bovine brain tubulin. These studies indicate that satellite bodies are major sites of microtubule assembly in both resting and stimulated cell centrosomes and show that the centrosomes of stimulated cells assemble more microtubules in vitro than resting cell centrosomes. This parallels the increase in microtubule content in intact lymphocytes stimulated by con A and suggests that the changes in centrosome organization and microtubule assembly capacity that occur during stimulation are causally related.     

Pigment movements in fish melanophores: Morphological and physiological studies

Summary The ultrastructure of the melanophores of Pterophyllum scalare was studied with respect to changes in cell shape during melanosome migration and the number and distribution of microtubules within the cell extensions. Cells were fixed with pigment fully aggregated or fully dispersed. All measurements were carried out on cross sections of cell processes, i.e. sections cut perpendicular to the long axis of the cell extensions. Cross sections of processes of melanophores with dispersed pigment are more or less ovoid in shape, and microtubules are arranged predominantly just below the cell membrane. These microtubules exhibit a relatively constant centre-to-centre spacing of about 55–65 nm. Processes of melanophores with aggregated pigment seem to be collapsed; their volume is substantially decreased but their circumference equals that of dispersed melanophores. The number of microtubules is reduced, and their regular arrangement is lost. The differences in microtubule number associated with the aggregated or dispersed state occur irrespective of the nature of the agent inducing dispersion or aggregation. In addition, apparent insertion of microtubules into the plasma membrane of the cell processes and associations of microtubules with cytoplasmic densities in the cell centre are described.The results indicate a rapid disassembly and assembly of microtubules associated with pigment movements. The possible role of microtubule associations with cell membrane and densities as sites of microtubule polymerization is briefly discussed.This work was supported by a grant from the Deutsche Forschungsgemeinschaft.     

Human and rat brain lipofuscin proteome

The accumulation of an autofluorescent pigment called lipofuscin in neurons is an invariable hallmark of brain aging. So far, this material has been considered to be waste material without particular relevance for cellular pathology. However, two lines of evidence argue that lipofuscin may play a yet unidentified role for pathological cellular functions: (i) Genetic forms of premature accumulation of similar autofluorescent material in neuronal ceroid lipofuscinosis indicate a direct disease-associated link to lipofuscin; (ii) Retinal pigment epithelium cell lipofuscin is mechanistically linked to age-associated macular degeneration. Here, we purified autofluorescent material from the temporal and hippocampal cortices of three different human individuals by a two-step ultracentrifugation on sucrose gradients. For human brain lipofuscin, we could identify a common set of 49 (among > 200 total) proteins that are mainly derived from mitochondria, cytoskeleton, and cell membrane. This brain lipofuscin proteome was validated in an interspecies comparison with whole brain rat lipofuscin (total > 300 proteins), purified by the same procedure, yielding an overlap of 32 proteins (64%) between lipofuscins of both species. Our study is the first to characterize human and rat brain lipofuscin and identifies high homology, pointing to common cellular pathomechanisms of age-associated lipofuscin accumulation despite the huge (40-fold) difference in the lifespan of these species. Our identification of these distinct proteins will now allow research in disturbed molecular pathways during age-associated dysfunctional lysosomal degradation.     

Changes in the ageing brain in health and disease.

The brains of individuals, who are cognitively normal, show age-related changes that include an overall reduction in brain volume and weight, which are associated with gyral atrophy and widening of the sulci of the cerebral cortex, and enlargement of the brain ventricles. These changes are partly the result of nerve cell loss but accurate estimates of neuronal loss are notoriously difficult to make. Microscopically, there are increasing amounts of the age-related pigment, lipofuscin, granulovacuolar degeneration in neurones, Hirano bodies, variable amounts of diffuse deposits of beta-amyloid in the parenchyma, the presence of neurofibrillary tangles mainly confined to the hippocampus and amygdala, and sparse numbers of senile plaques in these brain regions and also in other cortical areas. Of these changes, neurofibrillary tangles and senile plaques are the neuropathological hallmark of Alzheimer''s disease in which they are more abundant and widespread. Alzheimer''s disease has therefore been regarded as accelerated brain ageing; however, the realization that there is a strong genetic contribution to developing the disease at least implies that it may not be the inevitable, even if frequent, consequence of old age. Understanding the molecular basis of plaque and tangle formation is advancing greatly and is the main focus of research into the cellular and molecular changes observed in the ageing brain.     

Residual bodies resulting from photosensory membrane degradation are taken up by pigment cells in the eyes of the flyLucilia sp.

Retinae of blowflies (Lucilia sp.) were exposed to light for 12 h and then investigated by routine electron microscopy. Residual bodies and multi-vesicular bodies containing electron-dense structures were found in the photoreceptor cells. These structures appeared indistinguishable from material inside the pigment granules of secondary pigment cells. The residual bodies were found in interdigitations between photoreceptor and pigment cells and were often in close contact with mitochondria. Lamellar bodies and pigment granules were also found in the extracellular space between photoreceptor and pigment cells. In a second set of experiments, a membrane-impermeable reagent [sulfosuccinimidyl-6-(biotinamido) hexanoate] that should covalently biotinylate the surface of the photosensory membrane was introduced into the ommatidial cavity. The marker was detected, 4 h after application, inside the ommatidial cavity, on the rhabdomeric microvilli, and on residual bodies inside the photoreceptor cells, by streptavidin-gold binding on ultrathin sections. After 6 h of exposure to the reagent, pigment granules of the adjacent pigment cells were also labeled. The results suggest that the photosensory membrane is taken up and degraded together with the marker. Residual bodies resulting from this degradative process may thus be transported into the pigment cells; eventually material originating from photosensory membrane degradation may then be involved in pigment granule synthesis.     

Hybrid microtubules from mixtures of human fibroblast homogenates and chick brain microtubules : Absence of high molecular weight associated proteins

Microtubules have been assembled from a mixture of chick-brain microtubule protein and total soluble protein of cultured human fibroblasts. In this system microtubules were assembled which did not have any high molecular weight (HMW) microtubule-associated protein (MAP). Since the fibroblasts were human in origin, the hybrid microtubules were compared to microtubules assembled from human brain, which do include HMW-MAPs. To determine whether HMW-MAP is unique to brain, microtubules were assembled from mixtures of soluble proteins from non-neural mouse organs and chick brain microtubules. These hybrid microtubules contain similar HMW-MAPs to those of the chick brain alone. The absence of HMW-MAPs from the hybrid microtubules does not appear to be due to proteolysis. SDS-gel electrophoresis of all fractions prepared during the process of assembly of the hybrid microtubules reveals that the HMW-MAPs of the mixture are sedimented away from disassembled microtubules during the first centrifugation. The exclusion of the HMW-MAPs from the hybrid microtubules suggests that the assembly process in these mixtures, and in fibroblasts, may be qualitatively different from that found in extracts from brain and other organs.     

THE ROLE OF MICROTUBULES IN THE MOVEMENT OF PIGMENT GRANULES IN TELEOST MELANOPHORES

When microtubules in teleost melanophores are disrupted with antimitotic agents, colchicine, high hydrostatic pressure, low temperature, and vinblastine, the alignment and movement of the pigment granules in these cells disappear; during recovery, the return of alignment and movement corresponds in both time and space with the repolymerization of microtubules. Furthermore, analysis of nearest neighbor distances in untreated melanophores reveals that pigment granules are closely associated with microtubules. Other structures such as microfilaments, the endoplasmic reticulum, and the cytoplasmic matrix do not appear to be involved. Thus we conclude that microtubules determine the alignment and are essential for the selective movements of the pigment granules in these cells. Investigations of the mechanism of movement show that microtubules are required for both centrifugal and centripetal migrations and that they do not change in number or location during redistribution of pigment. Our results further indicate that microtubules in melanophores behave as semistable organelles as determined by investigation with colchicine and hydrostatic pressure. These observations and others rule out a push-pull mechanism based on the polymerization and depolymerization of microtubules or one which distinguishes two operationally different sets of microtubules. We propose instead that particles move by sliding along a fixed array of microtubules.     

Microtubule polarity confers direction to pigment transport in chromatophores

The cellular mechanisms used to direct translocating organelles are poorly understood. It is believed that the intrinsic structural polarity of microtubules may play a role in this process. We have examined the effects that differently oriented microtubules have upon the direction of pigment transport in surgically severed melanophore arms. In a previous paper (McNiven, M. A., M. Wang, and K. R. Porter, 1984, Cell, 37:753-765) we reported that after isolation, arms repolarized and reoriented their microtubules outward from their centers as if to form new "microcells." Pigment aggregation in these arms was toward a new focal point located at the arm centers. In this study we monitored pigment movement in isolated arms containing taxol- stabilized microtubules to test if the reversal in direction of pigment transport is dependent upon the repolarization of microtubules. We report that taxol delays both the microtubule reorientation and reversal in transport direction in a concentration-dependent manner. These and other presented data suggest that the polarity of the microtubule population within a melanophore confers direction on pigment transport.     

Dynein, dynactin, and kinesin II's interaction with microtubules is regulated during bidirectional organelle transport

The microtubule motors, cytoplasmic dynein and kinesin II, drive pigmented organelles in opposite directions in Xenopus melanophores, but the mechanism by which these or other motors are regulated to control the direction of organelle transport has not been previously elucidated. We find that cytoplasmic dynein, dynactin, and kinesin II remain on pigment granules during aggregation and dispersion in melanophores, indicating that control of direction is not mediated by a cyclic association of motors with these organelles. However, the ability of dynein, dynactin, and kinesin II to bind to microtubules varies as a function of the state of aggregation or dispersion of the pigment in the cells from which these molecules are isolated. Dynein and dynactin bind to microtubules when obtained from cells with aggregated pigment, whereas kinesin II binds to microtubules when obtained from cells with dispersed pigment. Moreover, the microtubule binding activity of these motors/dynactin can be reversed in vitro by the kinases and phosphatase that regulate the direction of pigment granule transport in vivo. These findings suggest that phosphorylation controls the direction of pigment granule transport by altering the ability of dynein, dynactin, and kinesin II to interact with microtubules.     

SOLUBLE PROTEINS IN NORMAL and DISEASED HUMAN BRAIN

Abstract– Six brain regions (frontal cortex, parts of the basal ganglia, thalamus and substantia nigra) were examined from over 80 human brains obtained at post-mortem. After elimination of patients with evidence of either 'cerebral hypoxia', lingering modes of death or abnormal brain morphology brain extracts were found to contain a characteristic pattern of 6 major soluble-acidic protein bands (neuronin-type proteins). As judged by studies using cortical biopsy specimens these proteins are relatively unaffected by post-mortem changes. Moreover, in adulthood the pattern is not noticeably age-dependant. Two of the protein bands have been identified as S-100 (neuronin S-1 and 2) while a third (neuronin S-5) is similar in most respects to antigen α (14-3-2). S-100 is increased in brains with evidence of marked gliosis. The other protein bands have not been identified. Two of them (neuronin S-3 and 4) are rarely depleted while the concentration of neuronin S-6 is affected particularly in extracortical regions in controls with either lingering modes of death and/or 'cerebral hypoxia' and in all regions in most patients with Alzheimer's disease, senile dementia and mixed senile and vascular dementia.     

On the ultrastructure of differentiating secondary xylem in willow

Summary Studies of differentiating xylem inSalix fragilis L. show the immediate cambial derivatives to be ultrastructurally similar. The Golgi apparatus is important at all stages of wall synthesis, possibly producing (amongst other substances) hemicellulose material which is carried to the wall in vesicles or multivesicular bodies. The endoplasmic reticulum also contributes one or more components to the developing wall: at some stages during differentiation the endoplasmic reticulum produces electron opaque bodies which appear to be guided towards the wall by microtubules. Compact structures formed from concentric membranes (myelin-like bodies) have been found joined to rough endoplasmic reticulum, but their presence is not explained.Two types of plasmalemma elaboration occur: invagination of the plasmalemma itself to form vesicles which may contain cytoplasmic material; and vesicles between the plasmalemma and cell wall which are the result of single vesicles or multivesicular bodies traversing the plasmalemma. Both systems provide a means for transporting cytoplasmic material across the plasmalemma.Microtubules have been seen associated with all vesicles derived from the cytoplasm which appear to be moving towards the wall. The presence of microtubules may generally be explained in terms of orientation of vesicles, even if they also happen coincidentally to parallel the supposed orientation of microfibrils in the wall itself. It is possible to resolve connections between the microtubules and the plasmalemma.     

Stereo high voltage electron microscopy of melanophores : Matrix transformations during pigment movements and the effects of cold and colchicine

Pigment migration in isolated melanophores of the angelfish, Pterophyllum scalare, has been studied by high voltage electron microscopy. Cells were isolated from the scales by collagenase and allowed to spread on Formvar and carbon-coated gold grids. Melanophores were then fixed by glutaraldehyde and osmium tetroxide and critical-point dried for viewing of whole cells in a high voltage electron microscope (1000 kV). The three-dimensional organization of the cytoplasmic matrix was stereoscopically examined in different states of pigment distribution, as well as under cold and colchicine treatment. The most prominent matrix constituent is an extensive mesh of cytoplasmic filaments (microtrabeculae) 2–18 nm in diameter that make contact to microtubules, pigment granules, and mitochondria. Microtrabeculae undergo dramatic changes in structural appearance in association with different phases of pigment movements. Cells fixed in the process of pigment aggregation are characterized by thickened and beaded trabeculae which may form irregular clots. Part of this material trails behind centripetally moving melanosomes. In dispersing cells, microtrabeculae are straight and of relatively uniform thickness throughout their length and form a highly ordered three-dimensional lattice. Reconstruction of the mesh in part precedes the arrival of pigment granules.Under the influence of cold or colchicine treatment, microtrabeculae show a high degree of polymorphism, being beaded, branched, or flattened with globose ends. Rather formless heaps are found associated with the surface of pigment granules. Since, however, these treatments also remove microtubules, the other important component of the cytoplasmic frame, alterations in microtrabecular structure may simply be mediated through removal of this organelle. In an attempt to separate the effects on microtrabeculae and microtubules from one another, cells have been cold-treated for only 15 min, a procedure that leaves a considerable portion of microtubules intact. Also under these conditions, microtrabeculae are beaded or transformed to globose heaps and flattened sheets.The observations suggest an involvement of microtrabeculae in the process of granule movement. Centripetal melanosome migration thereby seems associated with a collapse of microtrabeculae which again are reconstructed during pigment dispersion. The cold and colchicine experiments indicate direct effects of these agents on the structure and possibly also the function of the trabecular mesh. The significance and possible chemical composition of microtrabeculae is discussed.     

Fibrogranular Material,Annulate Lamellae and Microtubules During Spermiogenesis in Drosophila melanogaster

During spermiogenesis in Drosophila melanogaster, a “perinuclear plasm’ accumulates between the fenestrated portion of the nuclear envelope and an adjacent lamella of ER in the young spermatid. Microtubules appear within the perinuclear plasm and become especially concentrated in a nuclear concavity. Cytoplasmic pores are present locally within the lamella of ER. In addition, localized or discrete bodies composed of fibrogranular material become closely associated with single pore complexes in the lamella of ER. A close association exists between pore complexes (annulate lamellae), the small granular and fibrillar subunits of the fibrogranular bodies, polyribosomes and the nuclear-associated microtubules during much of spermiogenesis. While the fibrogranular material becomes less concentrated during spermiogenesis, the number of pore complexes in a single section increases such that two, three or even four short annulate lamellae are intercalated within many longitudinally oriented microtubules which are present in the furrow of the spermatid nucleus. Structural relationships observed between cytoplasmic pores (annulate lamellae), fibrogranular bodies, polyribosomes and microtubules are discussed in relation to information about the timing of RNA and protein synthesis. This study extends previous observations about the distribution and structural variations of annulate lamellae elsewhere in the spermatid cytoplasm.     

Comparison of the ultrastructure of stimulated and unstimulated mechanoreceptors in the taste hairs of the blowfly Phaenicia serricata

The structure of mechanoreceptors at the base of labeilar taste hairs of the blowfly Phaenicia serricata were examined in stimulated and unstimulated conditions (i.e. with the hair bent or unbent). Physiological recordings from the mechanoreceptor showed that the receptors responded when the hair is bent dorsally or ventrally and when the hair is bent at extreme angles. These conditions are the same as those placed on hairs in the anatomical studies. Bending the hair toward the ventral labellar surface caused the hair base to compress and indent the tubular body and its surrounding membrane and sheath at the distal end of the mechanoreceptor dendrite. In compressed tubular bodies, microtubules oriented longitudinally were bent and separated a greater distance from each other. Separation as much as 70 nm was observed in compressed tubular bodies as compared with a maximum of 26 nm between microtubules in tubular bodies of unbent hairs. The dense amorphous material between microtubules of compressed tubular bodies formed prominent bridges 18 nm thick connecting the microtubules at intervals of 48–74 nm. Thin 10 nm filaments were also evident in the spaces between microtubules. When the hair was bent toward the proximal end of the proboscis, the tip of the tubular body was bent about 15 °. The tubular body appears to function as a firm but resilient structure over which the dendritic membrane can be stretched during mechanostimulation. Comparison of morphology of bent and unbent hairs suggests a means by which mechanical force from the movement of the hair is transferred to the receptors by structures in the hair socket region. No differences were found in ciliary structures of stimulated and unstimulated receptors.     

Axonal tubulin and axonal microtubules: biochemical evidence for cold stability

Nerve extracts containing tubulin labeled by axonal transport were analyzed by electrophoresis and differential extraction. We found that a substantial fraction of the tubulin in the axons of the retinal ganglion cell of guinea pigs is not solubilized by conventional methods for preparation of microtubules from whole brain. In two-dimensional polyacrylamide gel electrophoresis this cold-insoluble tubulin was biochemically distinct from tubulin obtained from whole brain microtubules prepared by cold cycling. Cleveland peptide maps also indicated some differences between the cold-extractable and cold- insoluble tubulins. The demonstration of cold-insoluble tubulin that is specifically axonal in origin permits consideration of the physiological role of cold-insoluble tubulin in a specific cellular structure. It appears likely that much of this material is in the form of cold-stable microtubules. We propose that the physiological role of cold-insoluble tubulin in the axon may be associated with the regulation of the axonal microtubule complexes in neurons.