Myosin-dependent transport in neurons

Axonal transport in neurons has been shown to be microtubule dependent, driven by the molecular motor proteins kinesin and dynein. However, organelles undergoing fast transport can often pause or rapidly change directions without apparent dissociation from their transport tracks. Cytoskeletal polymers such as neurofilaments and microtubules have also been shown to make infrequent but rapid movements in axons indicating that their transport is likely to involve molecular motors. In addition, neurons have multiple compartments that are devoid of microtubules where transport of organelles is still seen to occur. These areas are rich in other cytoskeletal polymers such as actin filaments. Transported organelles have been shown to associate with multiple motor proteins including myosins. This suggests that nonmicrotubule-based transport may be myosin driven. In this review we will focus our attention on myosin motors known to be present in neurons and evaluate the evidence that they contribute to transport or other functions in the different compartments of the neuron.     

Importin-mediated nuclear transport in neurons

The polarized morphology of neurons poses a particular challenge to intracellular signal transduction. Local signals generated at distal sites must be retrogradely transported to the nucleus to produce persistent changes in neuronal function. Such communication of signals between distal neuronal compartments and the nucleus occurs during axon guidance, synapse formation, synaptic plasticity and following neuronal injury. Recent studies have begun to delineate a role for the active nuclear import pathway in transporting signals from axons and dendrites to the nucleus. In this pathway, soluble cargo proteins are recognized by nuclear transport carriers, called importins, which mediate their translocation from the cytoplasm into the nucleus. In neurons, importins might serve an additional function by carrying signals from distal sites to the soma.     

Tubulin transport by IFT is upregulated during ciliary growth by a cilium-autonomous mechanism

The assembly of the axoneme, the structural scaffold of cilia and flagella, requires translocation of a vast quantity of tubulin into the growing cilium, but the mechanisms that regulate the targeting, quantity, and timing of tubulin transport are largely unknown. In Chlamydomonas, GFP-tagged α-tubulin enters cilia as an intraflagellar transport (IFT) cargo and by diffusion. IFT-based transport of GFP-tubulin is elevated in growing cilia and IFT trains carry more tubulin. Cells possessing both nongrowing and growing cilia selectively target GFP-tubulin into the latter. The preferential delivery of tubulin boosts the concentration of soluble tubulin in the matrix of growing versus steady-state cilia. Cilia length mutants show abnormal kinetics of tubulin transport. We propose that cells regulate the extent of occupancy of IFT trains by tubulin cargoes. During ciliary growth, IFT concentrates soluble tubulin in cilia and thereby promotes elongation of the axonemal microtubules.     

Axoplasmic transport of dopamine in nigro-striatal neurons

The possibility that dopamine is transported in the nigro-striatal system was investigated by the stereotaxic injection of labelled tyrosine or l -DOPA into the substantia nigra of tranylcypromine-pretreated rats. At various intervals thereafter (2-48 h), significant quantities of labelled material were recovered from the ipsilateral substantia nigra, globus pallidus and caudate-putamen, The activity in the substantia nigra consisted of DOPA, dopamine, methoxytyramine, acid metabolites and other unidentified metabolites. In the caudate-putamen, however, nearly all of the activity (85 per cent) was recovered in the dopamine fraction, the remainder being distributed among some of the metabolites. No DOPA was recovered from the caudate-putamen. On the basis of time-course studies after the injection of [¹⁴C]DOPA into the substantia nigra, we calculated the transport rate of dopamine in the nigro-striatal bundle to be 0.8 mm/h. Electrolytic lesions of the nigrostriatal bundle at the level of the lateral hypothalamus, pretreatment with 6-hydroxydopamine, or injections of [¹⁴C]DOPA dorsal to the substantia nigra each produced profound reductions in the amount of activity subsequently recovered from the caudate-putamen. These data suggest that the activity recovered from the caudate-putamen after injections of [¹⁴C]DOPA into the or substantia nigra reflected axonal transport rather than other processes such as diffusion or transport via the circulation. Pretreatment with the DOPA decarboxy-lase inhibitor, R_o 4-4602, significantly reduced the amount of activity recovered in the caudate-putamen, an indication that decarboxylation of DOPA to dopamine was a prerequisite for transport. Pretreatment with reserpine also severely reduced the transport of dopamine in the nigro-striatal bundle, an observation suggesting that dopamine was transported by binding to the amine storage granules. There was no evidence of retrograde transport of dopamine in the nigrostriatal bundle. Injections of larger than tracer quantities of labelled tyrosine into the substantia nigra did not produce the degree of transport of dopamine that was obtained after injections of DOPA, a result suggesting that the amine storage granules may not normally be filled during axonal transport.     

Alphaherpesvirus infection disrupts mitochondrial transport in neurons

Mitochondria are dynamic organelles that are essential for cellular metabolism but can be functionally disrupted during pathogen infection. In neurons, mitochondria are transported on microtubules via the molecular motors kinesin-1 and dynein and recruited to energy-requiring regions such as synapses. Previous studies showed that proteins from pseudorabies virus (PRV), an alphaherpesvirus, localize to mitochondria and affect mitochondrial function. We show that PRV and herpes simplex virus type 1 (HSV-1) infection of rodent superior cervical ganglion (SCG) neurons disrupts mitochondrial motility and morphology. During PRV infection, glycoprotein B (gB)-dependent fusion events result in electrical coupling of neurons and increased action potential firing rates. Consequently, intracellular [Ca(2+)] increases and alters mitochondrial dynamics through a mechanism involving the Ca(2+)-sensitive cellular protein Miro and reduced recruitment of kinesin-1 to mitochondria. This disruption in mitochondrial dynamics is required for efficient growth and spread of PRV, indicating that altered mitochondrial transport enhances alphaherpesvirus pathogenesis and infection.     

Tubulin immunohistochemistry

Summary We report here the results observed when tubulin fluorescence immunohistochemistry is performed upon dissociated cultures of nervous tissue, principally of chick embryo spinal cord. When fixation includes nonpolar solvents or detergents, a uniform fluorescence is seen in neuron perikarya (with the exception of their nuclei), and the processes to which they give rise. Fixation with formaldehyde or glutaraldehyde alone, however, results in a discontinuous staining of neurites, and a less regular staining of their perikarya. The former pattern of response can be elicited if aldehyde fixation is followed by exposure to non-polar solvents. Such results are obtained both in thinly spread regions of the cultures, where neurons and their processes can easily be seen, and in the cell aggregates that also characterise them. Possible interpretations of these results are discussed.     

Tubulin expression in trypanosomes

Microtubules in trypanosomes are the main component of the flagellar axoneme and of the subpellicular microtubule corset, whose relative positions determine the morphology of each cell stage of the life cycle of these parasites. Microtubules are polymers of tubulin, a protein dimer of two 55-kDa subunits, alpha- and beta-tubulin; in Trypanosoma brucei, the tubulin-coding sequences are clustered in a 40-kb fragment of tandemly repeated alpha- and beta-tubulin genes separated by a 170-bp intergenic zone. This cluster is transcribed in a unique RNA which is rapidly processed into mature mRNAs carrying the 5' 35-nucleotide leader sequence found in all trypanosome mRNAs. Although no heterogeneity has been found at the gene level, tubulin can be post-translationally modified in 2 ways: the C-terminal tyrosine of alpha-tubulin can be selectively cleaved and added again with 2 enzymes, tubulin carboxypeptidase and tubulin-tyrosine ligase; alpha-tubulin can also be acetylated on a lysine residue. Some molecular domains of tubulin are restricted to subpopulations of microtubules; for instance, the beta-tubulin form defined by the monoclonal antibody 1B41 is sequestered into a part of the subpellicular cytoskeleton limited to the flagellar adhesion zone, which might correspond to the group of 4 microtubules associated with a cisterna of the endoplasmic reticulum, forming the so-called "subpellicular microtubule quartet" (SFMQ). The early assembly of this zone in each daughter cell during the cell division of T. brucei, together with the alterations undergone by the domain defined by the monoclonal antitubulin 24E3 during the differentiation of Trypanosoma cruzi, suggest that specific tubulin forms are responsible for dynamic properties of SFMQ possibly involved in trypanosome morphogenesis.     

Calcium regulation in neurons: transport processes.

The ionic stoichiometry of the major Ca2+ transport mechanisms in neurons is still a matter for debate. The past year has seen some particularly interesting developments in this field, not least the finding that the neuronal Na(+)-Ca2+ exchange may be able to transport K+.     

Modelling active transport in Drosophila unipolar motor neurons

This paper develops a model for simulating organelle transport in Drosophila unipolar motor neurons. The paper is motivated by a recent experimental investigation by Stone et al. (Microtubules have opposite orientation in axons and dendrites of Drosophila neurons. Mol Biol Cell.19:4122-4129) who proposed a map of microtubule (MT) orientation in Drosophila neurons, and explained why dynein mutations selectively impede dendritic growth without having much effect on axonal growth. Two different approaches to modelling the effect of dynein mutations are utilised: one through assuming a reduced average velocity of a dynein mutant motor and the other through assuming its decreased processivity (an increased detachment rate from MTs). Modified Smith–Simmons equations are used for developing a continuum model of the process. Distributions of organelle concentrations as well as distributions of diffusion, motor-driven and total organelle fluxes are simulated.     

Modelling active transport in Drosophila unipolar motor neurons

This paper develops a model for simulating organelle transport in Drosophila unipolar motor neurons. The paper is motivated by a recent experimental investigation by Stone et al. (Microtubules have opposite orientation in axons and dendrites of Drosophila neurons. Mol Biol Cell.19:4122-4129) who proposed a map of microtubule (MT) orientation in Drosophila neurons, and explained why dynein mutations selectively impede dendritic growth without having much effect on axonal growth. Two different approaches to modelling the effect of dynein mutations are utilised: one through assuming a reduced average velocity of a dynein mutant motor and the other through assuming its decreased processivity (an increased detachment rate from MTs). Modified Smith-Simmons equations are used for developing a continuum model of the process. Distributions of organelle concentrations as well as distributions of diffusion, motor-driven and total organelle fluxes are simulated.     

The Tubulin Code

Microtubules create diverse arrays with specific cellular functions such as the mitotic spindle, cilia, and bundles inside neurons. How microtubules are regulated to enable specific functions is not well understood. Recent work has shown that posttranslational modifications of the tubulin building blocks mark subpopulations of microtubules and regulate downstream microtubule-based functions. In this way, the tubulin modifications generate a “code” that can be read by microtubule-associated proteins in a manner analogous to how the histone code directs diverse chromatin functions. Here we review recent progress in understanding how the tubulin code is generated, maintained, and read by microtubule effectors.     

Molecular motors and mechanisms of directional transport in neurons

Intracellular transport is fundamental for neuronal morphogenesis, function and survival. Many proteins are selectively transported to either axons or dendrites. In addition, some specific mRNAs are transported to dendrites for local translation. Proteins of the kinesin superfamily participate in selective transport by using adaptor or scaffolding proteins to recognize and bind cargoes. The molecular components of RNA-transporting granules have been identified, and it is becoming clear how cargoes are directed to axons and dendrites by kinesin superfamily proteins. Here we discuss the molecular mechanisms of directional axonal and dendritic transport with specific emphasis on the role of motor proteins and their mechanisms of cargo recognition.     

Regulation of PTEN in neurons by myosin-based transport mechanisms

Our understanding of the function and regulation of the PTEN phosphatase now extends far beyond its initial characterization as a tumor suppressor with an important role in nervous system development and function. A number of developmental neurological disorders, which harbor mutations in PTEN or the PI3K pathway, are associated with increases in neuronal cell size (i.e., specific forms of autism or tuberous sclerosis). In light of this, the discovery of a myosin-based transport mechanism offers a new outlook in exploring further the underlying mechanisms of cell size control and its consequences to nervous system function. Overall, dysregulation of the PTEN:MyosinV interaction may provide an additional signaling intersection which increases the growth potential of a number of cell types. Indeed, members of the MyosinV family are widely expressed in different combinations in tissues (Rodriguez and Cheney, 2002), and have been shown to be differentially regulated in various cancers.     

Tyrosination State of Tubulin and the Activity of Tubulin:Tyrosine Ligase and Tubulin Carboxypeptidase in the Developing Retina of the Chick

The tyrosination state of tubulin and the enzymes involved in the tubulin tyrosination/detyrosination cycle--tubulin:tyrosine ligase and tubulin carboxypeptidase--were determined in chick retina during development. The amount of tyrosinable (tyrosinated plus detyrosinated) tubulin increased approximately 110% from embryonic day 7 to 14. Then it decreased, and by day 19 it was similar to the value on day 7. This result did not change after hatching, at least up to day 20. The proportion of tyrosinated and detyrosinated tubulin significantly changed with the development of the animal. At embryonic day 7, these tubulin species were at a proportion of 70 and 30%, respectively, and after hatching, the values inverted, to 30 and 70%, respectively. This change did not correlate with the activity of the ligase relative to that of the carboxypeptidase, as measured in vitro. This observation suggested that a change in the turnover rate of microtubules, in the proportion of assembled and nonassembled tubulin pools, or in both had occurred. Coincident with the last possibility, the proportion of assembled tubulin was found to increase during the development of the animal. This finding suggests that the tyrosination state of tubulin may be determined, at least in part, by the assembly state.     

Glutamate slows axonal transport of neurofilaments in transfected neurons

Neurofilaments are transported through axons by slow axonal transport. Abnormal accumulations of neurofilaments are seen in several neurodegenerative diseases, and this suggests that neurofilament transport is defective. Excitotoxic mechanisms involving glutamate are believed to be part of the pathogenic process in some neurodegenerative diseases, but there is currently little evidence to link glutamate with neurofilament transport. We have used a novel technique involving transfection of the green fluorescent protein-tagged neurofilament middle chain to measure neurofilament transport in cultured neurons. Treatment of the cells with glutamate induces a slowing of neurofilament transport. Phosphorylation of the side-arm domains of neurofilaments has been associated with a slowing of neurofilament transport, and we show that glutamate causes increased phosphorylation of these domains in cell bodies. We also show that glutamate activates members of the mitogen-activated protein kinase family, and that these kinases will phosphorylate neurofilament side-arm domains. These results provide a molecular framework to link glutamate excitotoxicity with neurofilament accumulation seen in some neurodegenerative diseases.