Polarity orientations of microtubules in squid and lobster axons

Hooks and comets: The story of microtubule polarity orientation in the neuron

It is widely believed that signature patterns of microtubule polarity orientation within axons and dendrites underlie compositional and morphological differences that distinguish these neuronal processes from one another. Axons of vertebrate neurons display uniformly plus-end-distal microtubules, whereas their dendrites display non-uniformly oriented microtubules. Recent studies on insect neurons suggest that it is the minus-end-distal microtubules that are the critical feature of the dendritic microtubule array, whether or not they are accompanied by plus-end-distal microtubules. Discussed in this article are the history of these findings, their implications for the regulation of neuronal polarity across the animal kingdom, and potential mechanisms by which neurons establish the distinct microtubule polarity patterns that define axons and dendrites.

The role of the cytoskeleton in the life cycle of viruses and intracellular bacteria: tracks, motors, and polymerization machines

Recent advances in microbiology implicate the cytoskeleton in the life cycle of some pathogens, such as intracellular bacteria, Rickettsia and viruses. The cellular cytoskeleton provides the basis for intracellular movements such as those that transport the pathogen to and from the cell surface to the nuclear region, or those that produce cortical protrusions that project the pathogen outwards from the cell surface towards an adjacent cell. Transport in both directions within the neuron is required for pathogens such as the herpesviruses to travel to and from the nucleus and perinuclear region where replication takes place. This trafficking is likely to depend on cellular motors moving on a combination of microtubule and actin filament tracks. Recently, Bearer et al. reconstituted retrograde transport of herpes simplex virus (HSV) in the giant axon of the squid. These studies identified the tegument proteins as the viral proteins most likely to recruit retrograde motors for the transport of HSV to the neuronal nucleus. Similar microtubule-based intracellular movements are part of the biological behavior of vaccinia, a poxvirus, and of adenovirus. Pathogen-induced surface projections and motility within the cortical cytoplasm also play a role in the life cycle of intracellular pathogens. Such motility is driven by pathogen-mediated actin polymerization. Virulence depends on this actin-based motility, since virulence is reduced in Listeria ActA mutants that lack the ability to recruit Arp2/3 and polymerize actin and in vaccinia virus mutants that cannot stimulate actin polymerization. Inhibition of intracellular movements provides a potential strategy to limit pathogenicity. The host cell motors and tracks, as well as the pathogen factors that interact with them, are potential targets for novel antimicrobial therapy.

Microtubules in Xenopus oocytes are oriented with their minus-ends towards the cortex

Despite lacking centrosomes, stage VI Xenopus oocytes contain extensive networks of cytoplasmic microtubules (MTs). To gain additional insight into the factors regulating MT organization during oogenesis, we have used electron microscopy and "hook decoration" to examine the distribution and orientation of MTs in Xenopus oocytes. A limited survey of two "undecorated" stage VI oocytes revealed 218 MTs in images covering approximately 2,500 microm(2), and indicated that the MT number density of the animal cytoplasm was greater than that of the vegetal cytoplasm. Examination of five "decorated" stage VI oocytes (three animal and five vegetal hemispheres) revealed 653 MTs. Of these, 76% could be scored as having exclusively counterclockwise (CCW) or clockwise (CW) hooks. In the animal hemispheres, 93% of the scored MTs exhibited CCW hooks when viewed from the direction of the cortex, indicating that most MTs were oriented with their minus-ends out. MT orientation appeared relatively uniform throughout the animal cytoplasm: more than 90% of the scored MTs in the cortical (90%), subcortical (96%), or perinuclear (98%) cytoplasm were oriented with their minus-ends out. In the vegetal hemispheres, approximately 80% of the scored MTs exhibited CCW hooks, and thus were oriented with their minus-ends out; 96% of the scored MTs in stage III oocytes were oriented minus-end out. These observations support a model in which the cortex plays a significant role in MT nucleation and organization in Xenopus oocytes, and have significant implications for the MT-dependent transport and localization of cytoplasmic organelles and RNAs during oogenesis.

Plus-end motors override minus-end motors during transport of squid axon vesicles on microtubules

Plus- and minus-end vesicle populations from squid axoplasm were isolated from each other by selective extraction of the minus-end vesicle motor followed by 5'-adenylyl imidodiphosphate (AMP-PNP)-induced microtubule affinity purification of the plus-end vesicles. In the presence of cytosol containing both plus- and minus-end motors, the isolated populations moved strictly in opposite directions along microtubules in vitro. Remarkably, when treated with trypsin before incubation with cytosol, purified plus-end vesicles moved exclusively to microtubule minus ends instead of moving in the normal plus-end direction. This reversal in the direction of movement of trypsinized plus-end vesicles, in light of further observation that cytosol promotes primarily minus-end movement of liposomes, suggests that the machinery for cytoplasmic dynein-driven, minus-end vesicle movement can establish a functional interaction with the lipid bilayers of both vesicle populations. The additional finding that kinesin overrides cytoplasmic dynein when both are bound to bead surfaces indicates that the direction of vesicle movement could be regulated simply by the presence or absence of a tightly bound, plus-end kinesin motor; being processive and tightly bound, the kinesin motor would override the activity of cytoplasmic dynein because the latter is weakly bound to vesicles and less processive. In support of this model, it was found that (a) only plus-end vesicles copurified with tightly bound kinesin motors; and (b) both plus- and minus-end vesicles bound cytoplasmic dynein from cytosol.

Organization of microtubules in myelinating Schwann cells

Myelinating Schwann cells polarize their surface membrane into several ultrastructurally and biochemically distinct domains that constitute the myelin internode. Formation of these membrane domains depends on contact with appropriate axons and requires microtubule-based transport systems for site-specific targeting of membrane components. Because little is known about microtubules in myelinating Schwann cells, this study used confocal microscopy and the microtubule hook-labelling method to characterize microtubule distribution, the location of microtubule nucleation sites, and the polarity and composition of Schwann cell microtubules. In myelinating Schwann cells, microtubules were abundant within the Golgi-rich perinuclear cytoplasm; they were not attached to the centrosome. Three-fourths of the microtubules in the cytoplasmic channels located along the outer perimeter of the myelin internode had their (+) ends oriented away from the perinuclear region, whereas the remaining 25% had the opposite polarity. Depolymerization/repolymerization experiments detected microtubule nucleating sites in perinuclear cytoplasm but not along the myelin internode. Taken together, these results indicate that microtubule-mediated transport of myelin components along the internode could utilize both (+)- and (-)-end motors. Specialized microtubule tracks that target myelin proteins to specific sites were not identified on the basis of tubulin polarity or posttranslational modifications.

GTP gamma S inhibits organelle transport along axonal microtubules

Movements of membrane-bounded organelles through cytoplasm frequently occur along microtubules, as in the neuron-specific case of fast axonal transport. To shed light on how microtubule-based organelle motility is regulated, pharmacological probes for GTP-binding proteins, or protein kinases or phosphatases were perfused into axoplasm extruded from squid (Loligo pealei) giant axons, and effects on fast axonal transport were monitored by quantitative video-enhanced light microscopy. GTP gamma S caused concentration-dependent and time-dependent declines in organelle transport velocities. GDP beta S was a less potent inhibitor. Excess GTP, but not GDP, masked the effects of coperfused GTP gamma S. The effects of GTP gamma S on transport were not mimicked by broad spectrum inhibitors of protein kinases (K-252a) or phosphatases (microcystin LR and okadaic acid), or as shown earlier, by ATP gamma S. Therefore, suppression of organelle motility by GTP gamma S was guanine nucleotide-specific and evidently did not involve irreversible transfer of thiophosphate groups to protein. Instead, the data imply that organelle transport in the axon is modulated by cycles of GTP hydrolysis and nucleotide exchange by one or more GTP-binding proteins. Fast axonal transport was not perturbed by AlF4-, indicating that the GTP gamma S-sensitive factors do not include heterotrimeric G-proteins. Potential axoplasmic targets of GTP gamma S include dynamin and multiple small GTP-binding proteins, which were shown to be present in squid axoplasm. These collective findings suggest a novel strategy for regulating microtubule-based organelle transport and a new role for GTP-binding proteins.

Organelle flux in intact and transected crayfish giant axons

The flux of organelles moving by fast axonal transport in distal segments of severed crayfish medial giant axons (MGAs) and lateral giant axons (LGAs) was measured for survival times of up to 35 days (MGAs) or 60 days (LGAs). The response to transection occurred in 4 phases: (1) Organelle fluxes remained nearly normal for the first 24 h. (2) Fluxes then declined continuously until day 6 or 7. (3) A rebound toward normal levels lasted until day 21 (MGAs) or longer (LGAs). (4) During the final phase, fluxes declined either to zero (MGAs) or plateaued at a level which was a significant percentage of normal flux (LGAs). Changes in anterograde and retrograde flux were identical. The distribution of various size classes of translocating vesicles in distal segments of these axons was normal until day 4, with small and medium size, rapidly moving vesicles predominating. Afterwards, larger, slower vesicles predominated. During long-term survival, the axons remained physiologically intact, and cytoskeletons appeared to be normal, retaining intact microtubules which remained normally oriented with positive ends pointing distally. The evidence suggests that the two initial phases of the response to transection represent clearance from distal segments of organelle traffic which normally moves between axon and cell body. The rebound phase may be trauma induced, possibly a transient phase of cytoplasmic degeneration resulting from the loss of trophic support from the cell body. Differences between LGAs and MGAs with respect to organelle flux during prolonged survival, i.e. during the 4th phase of the response to transection, are consistent with different mechanisms of long-term survival which have been proposed for these axons.

Changes in microtubule polarity orientation during the development of hippocampal neurons in culture

Microtubules in the dendrites of cultured hippocampal neurons are of nonuniform polarity orientation. About half of the microtubules have their plus ends oriented distal to the cell body, and the other half have their minus ends distal; in contrast, microtubules in the axon are of uniform polarity orientation, all having their plus ends distal (Baas, P.W., J.S. Deitch, M. M. Black, and G. A. Banker. 1988. Proc. Natl. Acad. Sci. USA. 85:8335-8339). Here we describe the developmental changes that give rise to the distinct microtubule patterns of axons and dendrites. Cultured hippocampal neurons initially extend several short processes, any one of which can apparently become the axon (Dotti, C. G., and G. A. Banker. 1987. Nature [Lond.]. 330:477-479). A few days after the axon has begun its rapid growth, the remaining processes differentiate into dendrites (Dotti, C. G., C. A. Sullivan, and G. A. Banker. 1988. J. Neurosci. 8:1454-1468). The polarity orientation of the microtubules in all of the initial processes is uniform, with plus ends distal to the cell body, even through most of these processes will become dendrites. This uniform microtubule polarity orientation is maintained in the axon at all stages of its growth. The polarity orientation of the microtubules in the other processes remains uniform until they begin to grow and acquire the morphological characteristics of dendrites. It is during this period that microtubules with minus ends distal to the cell body first appear in these processes. The proportion of minus end-distal microtubules gradually increases until, by 7 d in culture, about equal numbers of dendritic microtubules are oriented in each direction. Thus, the establishment of regional differences in microtubule polarity orientation occurs after the initial polarization of the neuron and is temporally correlated with the differentiation of the dendrites.

Dendrites of mitral cell neurons contain microtubules of opposite polarity

Axonal extensions of neurons show microtubules (MTs) with a uniform polarity indicating that they originate at or near the perikaryon. To obtain information on the polarity of dendritic MTs, a polarity assay was used to examine MTs in dendrites of interneurons (mitral cells) of the olfactory pathway of the bullfrog. The assay involved incubating pieces of olfactory lobe in a tubulin-containing detergent medium which stabilized pre-existing MTs and provided for assembly of exogenous tubulin onto their surfaces as ribbon structures, which appear as 'hooks' on the MTs when seen in cross-section. The orientation of the ribbons in a clockwise or anticlockwise direction reflects the polarity of the wall lattice of the MT with which they are associated. Mitral cell dendrites show MTs with ribbons oriented in both directions, indicating two populations of MTs with opposite polarity. The two populations are seen in both the proximal and distal regions of dendrites, and the perikaryon, as expected, shows a mixed population of MTs as regards polarity. It is hypothesized that this is true for most neurons, and that dendritic MTs arise from organizing centers in the dendritic process. If this hypothesis is correct, the polarity of dendritic MTs would depend on the orientation of these centers, which remain to be identified.

Microtubule stability in severed axons

We examined severed axons of cat sympathetic nerves and severed neurites of cultured chick sensory neurons for evidence of extensive microtubule depolymerization. Cat sympathetic fibres fixed at various times after severing were cross-sectioned for electron microscopy from both cut ends. The number density of microtubules was determined at various times after severing for matched proximal and distal regions equidistant from cut ends. These data show that the number density of microtubules was nearly identical in proximal and distal fragments at 10, 20 and 60 min and at distances between 10 and 50 micron from the cut ends. In chick sensory neurites the microtubule array was examined in longitudinal sections. In order to define objectively a normal microtubule array, the distance between 100 microtubule pairs was measured in seven control neurites, giving a mean distance (+/- S.D.) of 33 nm +/- 19 nm. A normal array of microtubules was defined as having microtubules within 52 nm of their nearest lateral neighbour. Among 11 neurites at times from 1 to 15 min after transection, the mean distance from the cut tip to the first microtubule was 1.3 micron in proximal fragments and 0.5 micron in distal fragments. The mean distance to the normal microtubule array was 2.8 micron in proximal fragments and 2.1 micron in distal fragments. There was no trend or pattern with respect to the times after severing that the neurite was fixed and the amount of microtubule depolymerization. Our results show no evidence for stabilization of axonal/neurite microtubules by capping structures at their ends. We conclude that microtubule instability is unlikely to play a role in the response of axons to axotomy.