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10. Doublecortin associates with microtubules preferentially in regions of the axon displaying actin-rich protrusive structures.

Author

Tint I, Jean D, Baas PW, and Black MM

Subjects
Actins physiology, Animals, Axons chemistry, Axons physiology, Cells, Cultured, Doublecortin Domain Proteins, Doublecortin Protein, Microtubule-Associated Proteins physiology, Microtubules chemistry, Microtubules physiology, Neuropeptides physiology, Rats, Actins metabolism, Axons metabolism, Microtubule-Associated Proteins metabolism, Microtubules metabolism, Neuropeptides metabolism
Abstract

Here we studied doublecortin (DCX) in cultured hippocampal and sympathetic neurons during axonal development. In both types of neurons, DCX is abundant in the growth cone, in which it primarily localizes with microtubules. Its abundance is lowest on microtubules in the neck region of the growth cone and highest on microtubules extending into the actin-rich lamellar regions. Interestingly, the microtubule polymer richest in DCX is also deficient in tau. In hippocampal neurons but not sympathetic neurons, discrete focal patches of microtubules rich in DCX and deficient in tau are present along the axonal shaft. Invariably, these patches have actin-rich protrusions resembling those of growth cones. Many of the DCX/actin filament patches exhibit vigorous protrusive activity and also undergo a proximal-to-distal redistribution within the axon at average rates approximately 2 microm/min and thus closely resemble the growth-cone-like waves described by previous authors. Depletion of DCX using small interfering RNA had little effect on the appearance of the growth cone or on axonal growth in either type of neuron. However, DCX depletion significantly delayed collateral branching in hippocampal neurons and also significantly lowered the frequency of actin-rich patches along hippocampal axons. Branching by sympathetic neurons, which occurs by growth cone splitting, was not impaired by DCX depletion. These findings reveal a functional relationship between the DCX/actin filament patches and collateral branching. Based on the striking resemblance of these patches to growth cones, we discuss the possibility that they reflect a mechanism for locally boosting morphogenetic activity to facilitate axonal growth and collateral branching.

Published
2009
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11. Cytoskeletal requirements in axonal transport of slow component-b.

Author

Roy S, Winton MJ, Black MM, Trojanowski JQ, and Lee VM

Subjects
Actin Cytoskeleton ultrastructure, Animals, Axons ultrastructure, Brain ultrastructure, Bridged Bicyclo Compounds, Heterocyclic pharmacology, Cells, Cultured, Cytoskeleton ultrastructure, Glyceraldehyde 3-Phosphate metabolism, Macromolecular Substances metabolism, Mice, Mice, Inbred C57BL, Microtubules metabolism, Microtubules ultrastructure, Synapsins metabolism, Thiazolidines pharmacology, Time Factors, alpha-Synuclein metabolism, Actin Cytoskeleton metabolism, Axonal Transport physiology, Axons metabolism, Brain metabolism, Cytoskeleton metabolism, Molecular Motor Proteins metabolism
Abstract

Slow component-b (SCb) translocates approximately 200 diverse proteins from the cell body to the axon and axon tip at average rates of approximately 2-8 mm/d. Several studies suggest that SCb proteins are cotransported as one or more macromolecular complexes, but the basis for this cotransport is unknown. The identification of actin and myosin in SCb led to the proposal that actin filaments function as a scaffold for the binding of other SCb proteins and that transport of these complexes is powered by myosin: the "microfilament-complex" model. Later, several SCb proteins were also found to bind F-actin, supporting the idea, but despite this, the model has never been directly tested. Here, we test this model by disrupting the cytoskeleton in a live-cell model system wherein we directly visualize transport of SCb cargoes. We focused on three SCb proteins that we previously showed were cotransported in our system: alpha-synuclein, synapsin-I, and glyceraldehyde-3-phosphate dehydrogenase. Disruption of actin filaments with latrunculin had no effect on the velocity or frequency of transport of these three proteins. Furthermore, cotransport of these three SCb proteins continued in actin-depleted axons. We conclude that actin filaments do not function as a scaffold to organize and transport these and possibly other SCb proteins. In contrast, depletion of microtubules led to a dramatic inhibition of vectorial transport of SCb cargoes. These findings do not support the microfilament-complex model, but instead indicate that the transport of protein complexes in SCb is powered by microtubule motors.

Published
2008
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12. Rapid and intermittent cotransport of slow component-b proteins.

Author

Roy S, Winton MJ, Black MM, Trojanowski JQ, and Lee VM

Subjects
Animals, Axons metabolism, Brain metabolism, Cells, Cultured, Mice, Mice, Inbred C57BL, Protein Transport physiology, Axonal Transport physiology, Glyceraldehyde-3-Phosphate Dehydrogenase (Phosphorylating) metabolism, Synapsins metabolism, alpha-Synuclein metabolism
Abstract

After synthesis in neuronal perikarya, proteins destined for synapses and other distant axonal sites are transported in three major groups that differ in average velocity and protein composition: fast component (FC), slow component-a (SCa), and slow component-b (SCb). The FC transports mainly vesicular cargoes at average rates of approximately 200-400 mm/d. SCa transports microtubules and neurofilaments at average rates of approximately 0.2-1 mm/d, whereas SCb translocates approximately 200 diverse proteins critical for axonal growth, regeneration, and synaptic function at average rates of approximately 2-8 mm/d. Several neurodegenerative diseases are characterized by abnormalities in one or more SCb proteins, but little is known about mechanisms underlying SCb compared with FC and SCa. Here, we use live-cell imaging to visualize and quantify the axonal transport of three SCb proteins, alpha-synuclein, synapsin-I, and glyceraldehyde-3-phosphate dehydrogenase in cultured hippocampal neurons, and directly compare their transport to synaptophysin, a prototypical FC protein. All three SCb proteins move rapidly but infrequently with pauses during transit, unlike synaptophysin, which moves much more frequently and persistently. By simultaneously visualizing the transport of proteins at high temporal and spatial resolution, we show that the dynamics of alpha-synuclein transport are distinct from those of synaptophysin but similar to other SCb proteins. Our observations of the cotransport of multiple SCb proteins in single axons suggest that they move as multiprotein complexes. These studies offer novel mechanistic insights into SCb and provide tools for further investigating its role in disease processes.

Published
2007
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13. Neurofilaments are transported rapidly but intermittently in axons: implications for slow axonal transport.

Author

Roy S, Coffee P, Smith G, Liem RK, Brady ST, and Black MM

Subjects
Adrenergic Fibers metabolism, Adrenergic Fibers ultrastructure, Animals, Axons ultrastructure, Cells, Cultured, Cytoskeletal Proteins genetics, Green Fluorescent Proteins, Luminescent Proteins genetics, Neurofilament Proteins genetics, Neurons cytology, Rats, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Time Factors, Transfection, Axonal Transport physiology, Axons metabolism, Cytoskeletal Proteins metabolism, Neurofilament Proteins metabolism, Neurons metabolism
Abstract

Slow axonal transport conveys cytoskeletal proteins from cell body to axon tip. This transport provides the axon with the architectural elements that are required to generate and maintain its elongate shape and also generates forces within the axon that are necessary for axon growth and navigation. The mechanisms of cytoskeletal transport in axons are unknown. One hypothesis states that cytoskeletal proteins are transported within the axon as polymers. We tested this hypothesis by visualizing individual cytoskeletal polymers in living axons and determining whether they undergo vectorial movement. We focused on neurofilaments in axons of cultured sympathetic neurons because individual neurofilaments in these axons can be visualized by optical microscopy. Cultured sympathetic neurons were infected with recombinant adenovirus containing a construct encoding a fusion protein combining green fluorescent protein (GFP) with the heavy neurofilament protein subunit (NFH). The chimeric GFP-NFH coassembled with endogenous neurofilaments. Time lapse imaging revealed that individual GFP-NFH-labeled neurofilaments undergo vigorous vectorial transport in the axon in both anterograde and retrograde directions but with a strong anterograde bias. NF transport in both directions exhibited a broad spectrum of rates with averages of approximately 0.6-0.7 microm/sec. However, movement was intermittent, with individual neurofilaments pausing during their transit within the axon. Some NFs either moved or paused for the most of the time they were observed, whereas others were intermediate in behavior. On average, neurofilaments spend at most 20% of the time moving and rest of the time paused. These results establish that the slow axonal transport machinery conveys neurofilaments.

Published
2000

14. Acute inactivation of tau has no effect on dynamics of microtubules in growing axons of cultured sympathetic neurons.

Author

Tint I, Slaughter T, Fischer I, and Black MM

Subjects
Animals, Antibodies pharmacology, Axons drug effects, Cells, Cultured, Fluorescent Antibody Technique, Indirect, Image Processing, Computer-Assisted, Microtubule-Associated Proteins immunology, Microtubule-Associated Proteins physiology, Microtubules drug effects, Nocodazole pharmacology, Precipitin Tests, Protein Processing, Post-Translational immunology, Rats, tau Proteins immunology, Adrenergic Fibers physiology, Axons physiology, Microtubules physiology, tau Proteins physiology
Abstract

Tau is a developmentally regulated microtubule (MT)-associated protein in neurons that has been implicated in neuronal morphogenesis. On the basis of test tube studies, tau has been proposed to function in axon growth by stabilizing MTs and thereby promoting MT assembly. We have tested this hypothesis by examining the effects of acute inactivation of tau on axonal MTs. Tau was inactivated by microinjecting purified antibodies against recombinant tau into neurons before they extended axons. The injected antibodies quantitatively precipitated tau into aggregates in the soma. With these conditions the neurons elaborate normal-appearing axons, and MTs extend throughout the axons and into the growth cones, but the axons and their MTs are depleted of tau. The immunodepletion of tau had no detectable effect on several parameters of the dynamics of axonal MTs. Depletion of tau also was not accompanied by a reorganization of other major MT-associated proteins or actin filaments in these neurons. Thus, neurons effectively depleted of tau can extend axons that resemble those of control cells, and the axons contain normal-appearing MT arrays with normal dynamic behavior. These observations are exactly the opposite of those expected on the basis of the hypothesis that the stability of axonal MTs is a direct function of their content of tau, indicating that tau in growing axons of cultured sympathetic neurons is not specialized to promote microtubule assembly and stability.

Published
1998

15. Microtubule transport from the cell body into the axons of growing neurons.

Author

Slaughter T, Wang J, and Black MM

Subjects
Animals, Biological Transport physiology, Cells, Cultured, Rats, Axons physiology, Cell Division physiology, Microtubules metabolism, Neurons physiology, Sympathetic Nervous System growth & development
Abstract

The present studies test the hypothesis that microtubules (MTs) are transported from the cell body into the axons of growing neurons. Dissociated sympathetic neurons were cultured using conditions that allow us to control the initiation of axon outgrowth. Neurons were injected with biotin-labeled tubulin (Bt-tub) and then stimulated to extend axons. The newly formed axons were then examined using immunofluorescence procedures for MTs with or without Bt-tub. Because the Bt-tub is fully assembly competent, all MTs that assemble after injection will contain Bt-tub. However, MTs that exist in the neuron at the time of injection and persist during the subsequent incubation will not contain Bt-tub. Because the neurons were injected before extending axons, MTs without Bt-tub are initially localized to the cell body. We specifically determined whether these MTs appeared in the newly formed axon. Such a result can only be explained by the transport of these MTs from their initial location in the cell body into the axon. The newly formed axons of many neurons contained MTs both with and without Bt-tub. MTs without Bt-tub were detected all along the axon and in some neurons represented a substantial portion of the total polymer in the proximal and middle regions of the axon. These results show that MTs are transported from the cell body into growing axons and that this transport is robust, delivering MTs to all regions of the newly formed axon.

Published
1997

16. Microtubule assembly in growing dendrites.

Author

Wang J, Yu W, Baas PW, and Black MM

Subjects
Animals, Biotin metabolism, Cells, Cultured, Cellular Senescence, Dendrites metabolism, Microtubules metabolism, Neurons physiology, Rats, Sympathetic Nervous System cytology, Sympathetic Nervous System physiology, Tubulin metabolism, Dendrites physiology, Microtubules physiology
Abstract

Dendritic microtubules (MTs) are nonuniform with respect to polarity orientation, with roughly equal proportions having a plus-end-distal or minus-end-distal orientation. In the present studies, we have microinjected biotin-labeled tubulin (Bt-tub) into cultured sympathetic neurons extending dendrites to explore the contribution of MT assembly to the elaboration and maintenance of the dendritic MT array. Within minutes of injecting Bt-tub, an enormous number of MTs were seen emanating from a point source in the cell body. Over time, this pattern changed such that by 120 min after injection, biotinylated MTs no longer emanated from a discrete site, but were distributed over a broad region that extended from the cell body into the dendrites. The observation that biotinylated MTs emanate from a point source in the soma at relatively short times after injection, but not at longer times, suggests that they undergo a redistribution subsequent to their initial nucleation rather than a simple radial expansion from the somal nucleation site. Bt-tub assembly also occurred in dendrites but, unlike in the cell body, assembly was dispersed throughout the dendrite rather than emanating from a discrete site. Immunoelectron microscopic analyses revealed that assembly in dendrites reflected the addition of Bt-tub onto the ends of both plus-end-distal and minus-end-distal MTs that existed in the cell at the time of injection. The time course of Bt-tub appearance in dendritic MTs suggested an average half-life of approximately 76 min for these MTs. We discuss these observations in the context of a model for generating the MT array of dendrites that combines both MT transport and MT assembly.

Published
1996

17. Tau is enriched on dynamic microtubules in the distal region of growing axons.

Author

Black MM, Slaughter T, Moshiach S, Obrocka M, and Fischer I

Subjects
Adrenergic Fibers chemistry, Animals, Antibody Specificity, Axons ultrastructure, Base Sequence, Cells, Cultured chemistry, Cells, Cultured ultrastructure, Detergents, Fixatives, Fluorescent Antibody Technique, Microtubule-Associated Proteins analysis, Microtubules metabolism, Molecular Sequence Data, Neurites chemistry, Neurons chemistry, Neurons cytology, Neurons ultrastructure, Polymerase Chain Reaction, Polymers, Rats, Recombinant Proteins immunology, Superior Cervical Ganglion cytology, Tubulin analysis, tau Proteins immunology, tau Proteins metabolism, Axons chemistry, Microtubules chemistry, tau Proteins analysis
Abstract

It is widely held that tau determines the stability of microtubules in growing axons, although direct evidence supporting this hypothesis is lacking. Previous studies have shown that the microtubule polymer in the distal axon and growth cone is the most dynamic of growing axons; it turns over more rapidly and is more sensitive to microtubule depolymerizing drugs than the polymer situated proximally. We reasoned that if the stability of axonal microtubules is directly related to their content of tau, then the polymer in the distal axon should have less tau than the polymer in the proximal axon. We tested this proposition by measuring the relative tau content of microtubule along growing axons of cultured sympathetic neurons immunostained for tau and tubulin. Our results show that the tau content of microtubules varies along the axon, but in the opposite way predicted. Specifically, the relative tau content of microtubules increases progressively along the axon to reach a peak near the growth cone that is severalfold greater than that observed proximally. Thus, tau is most enriched on the most dynamic polymer of the axon. We also show that the gradient in tau content of microtubules does not generate corresponding gradients in the extent of tubulin assembly or in the sensitivity of axonal microtubules to nocodazole. On the basis of these findings, we propose that tau in growing axons has functions other than promoting microtubule assembly and stability and the key sites for these functions are the distal axon and growth cone.

Published
1996

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