Cytoplasmic Dynein Transports Axonal Microtubules in a Polarity-Sorting Manner.

Axonal microtubules are predominantly organized into a plus-end-out pattern. Here, we tested both experimentally and with computational modeling whether a motor-based polarity-sorting mechanism can explain this microtubule pattern. The posited mechanism centers on cytoplasmic dynein transporting plus-end-out and minus-end-out microtubules into and out of the axon, respectively.

Pharmacologically increasing microtubule acetylation corrects stress-exacerbated effects of organophosphates on neurons.

Many veterans of the 1990-1991 Gulf War contracted Gulf War Illness (GWI), a multisymptom disease that primarily affects the nervous system. Here, we treated cultures of human or rat neurons with diisopropyl fluorophosphate (DFP), an analog of sarin, one of the organophosphate (OP) toxicants to which the military veterans were exposed. All observed cellular defects produced by DFP were exacerbated by pretreatment with corticosterone or cortisol, which, in rat and human neurons, respectively, serves in our experiments to mimic the physical stress endured by soldiers during the war.

Axonal transport: The orderly motion of axonal structures.

Axonal transport is a constitutive process that supplies the axon and axon terminal with materials required to maintain their structure and function. Most materials are supplied via three rate components termed the fast component, slow component a, and slow component b. Each of these delivers a distinct set of materials with distinct transport kinetics.

A novel role for doublecortin and doublecortin-like kinase in regulating growth cone microtubules.

Doublecortin (DCX) and doublecortin-like kinase (DCLK), closely related family members, are microtubule-associated proteins with overlapping functions in both neuronal migration and axonal outgrowth. In growing axons, these proteins appear to have their primary functions in the growth cone. Here, we used siRNA to deplete these proteins from cultured rat sympathetic neurons.

The cytoskeleton of the neuron--an essay in celebration of Paul Letourneau's career.

The neuronal cytoskeleton consists of microtubules, actin filaments, neurofilaments, and an array of accessory proteins that regulate and modify these three main filament systems. This essay celebrates the career of Paul Letourneau, a pioneer of the neuronal cytoskeleton, to whom the community owes a debt of gratitude.

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

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.

Cytoskeletal requirements in axonal transport of slow component-b.

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.

Rapid and intermittent cotransport of slow component-b proteins.

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.

Antagonistic forces generated by cytoplasmic dynein and myosin-II during growth cone turning and axonal retraction.

Cytoplasmic dynein transports short microtubules down the axon in part by pushing against the actin cytoskeleton. Recent studies have suggested that comparable dynein-driven forces may impinge upon the longer microtubules within the axon. Here, we examined a potential role for these forces on axonal retraction and growth cone turning in neurons partially depleted of dynein heavy chain (DHC) by small interfering RNA.

Effects of dynactin disruption and dynein depletion on axonal microtubules.

We investigated potential roles of cytoplasmic dynein in organizing axonal microtubules either by depleting dynein heavy chain from cultured neurons or by experimentally disrupting dynactin. The former was accomplished by siRNA while the latter was accomplished by overexpressing P50-dynamitin. Both methods resulted in a persistent reduction in the frequency of transport of short microtubules.

Role of cytoplasmic dynein in the axonal transport of microtubules and neurofilaments.

Recent studies have shown that the transport of microtubules (MTs) and neurofilaments (NFs) within the axon is rapid, infrequent, asynchronous, and bidirectional. Here, we used RNA interference to investigate the role of cytoplasmic dynein in powering these transport events. To reveal transport of MTs and NFs, we expressed EGFP-tagged tubulin or NF proteins in cultured rat sympathetic neurons and performed live-cell imaging of the fluorescent cytoskeletal elements in photobleached regions of the axon.

Transport of neurofilaments in growing axons requires microtubules but not actin filaments.

Neurofilament (NF) polymers are conveyed from cell body to axon tip by slow axonal transport, and disruption of this process is implicated in several neuronal pathologies. This movement occurs in both anterograde and retrograde directions and is characterized by relatively rapid but brief movements of neurofilaments, interrupted by prolonged pauses. The present studies combine pharmacologic treatments that target actin filaments or microtubules with imaging of NF polymer transport in living axons to examine the dependence of neurofilament transport on these cytoskeletal systems.

STOP (stable-tubule-only-polypeptide) is preferentially associated with the stable domain of axonal microtubules.

Axonal microtubules consist of two distinct domains that differ in tyrosinated-tubulin staining. One domain stains weakly for tyrosinated-tubulin, while the other stains strongly, and the transition between these domains is abrupt; the tyrosinated-tubulin-poor domain is at the minus end of the microtubule, and the tyrosinated-tubulin-rich domain extends from the plus end of the tyrosinated-tubulin-poor domain to the end of the microtubule. The tyrosinated-tubulin-poor domain is drug- and cold-stable, whereas the tyrosinated-tubulin-rich domain is drug-labile, but largely cold-stable.