The Role of the Axonal Cytoskeleton in Diabetic Neuropathy

The neuropathy associated with diabetes includes well documented impairment of axonal transport, a reduction in axon calibre and a reduced capacity for nerve regeneration. All of those aspects of nerve function rely on the integrity of the axonal cytoskeleton. Alterations in the axonal cytoskeleton in experimental diabetes include an insulin-dependent non-enzymatic glycation of actin that is reflected in increased glycation of platelet actin in the clinical situation. There is a reduced synthesis of mRNA for the isoforms of tubulin that are associated with nerve growth and regeneration and an elevated non-enzymatic glycation of peripheral nerve tubulin in both diabetic patients and diabetic animals. mRNAs for neurofilament proteins are selectively reduced in the diabetic rat and the post-translational modification of at least one of the neurofilament proteins is altered. There is some evidence that altered expression of isoforms of protein kinases may contribute to these changes.     

Altered Axonal Transport of Cytoskeletal Proteins in the Mutant Diabetic Mouse

Polypeptides in the motor axons of the sciatic nerve in 120-day-old normal and diabetic mice C57BL/Ks (db/db) were labeled by injection of [35S]methionine into the ventral horn of the spinal cord. At 8, 15, and 25 days after the injection, the distribution of radiolabeled polypeptides along the sciatic nerve was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Four major radiolabeled polypeptides, tentatively identified as actin, tubulin, and the two lightest subunits of the neurofilament triplet, were studied in both diabetic and control mice. In the diabetic animals, the two polypeptides identified as actin and tubulin showed a reduction of average velocity of migration along the sciatic nerve, resulting in a higher fraction of radioactivity in the proximal part of the sciatic nerve, whereas the front of radioactivity (advancing at maximal velocity) moved at a normal rate. In contrast, both the average and maximal velocities of the two neurofilament subunits were slower in the diabetic mice than in the control mice. These results indicate that the axonal transport of the cytoskeletal proteins is differentially affected in the course of diabetic neuropathy, and may suggest that the impairment concerns mainly the proteins carried by the slowest component of axonal transport.     

Glycation of Brain Actin in Experimental Diabetes

Abstract: Actin is a neuronal protein involved in axonal transport and nerve regeneration, both of which are known to be impaired in experimental diabetes. To determine if actin is subject to glycation, we rendered rats diabetic by injection of streptozotocin. Two or 6 weeks later brains were removed and a preparation of cytoskeletal proteins was analyzed by two-dimensional polyacrylamide gel electrophoresis. Brains from diabetic animals contained an extra polypeptide that migrated close to actin and reacted with monoclonal antibody C4 against actin. It was also found in a preparation of soluble synaptic proteins from diabetic rat brain, indicating that it was at least partly neuronal in origin. This polypeptide could be produced by incubation of cytoskeletal proteins from brains of nondiabetic rats with glucose-6-phosphate in vitro. The appearance of this glycated actin in diabetic animals was prevented by administration of insulin for a period of 6 weeks. We could not detect any effect of glycation in vitro on the ability of muscle G-actin to form F-actin filaments and its significance for the function of actin remains to be determined. The finding that glycation of platelet-derived actin from diabetic patients was significantly increased implies that the abnormality may also occur in clinical diabetes.     

Changes in Organization and Axonal Transport of Cytoskeletal Proteins During Regeneration

Changes in solubility and transport rate of cytoskeletal proteins during regeneration were studied in the motor fibers of the rat sciatic nerve. Nerves were injured by freezing at the midthigh level either 1-2 weeks before (experiment I) or 1 week after radioactive labeling of the spinal cord with L-[35S]methionine (experiment II). Labeled proteins in 6-mm consecutive segments of the nerve 2 weeks after labeling were analyzed following fractionation into soluble and insoluble populations with 1% Triton at 4 degrees C. When axonal transport of newly synthesized cytoskeleton was examined in the regenerating nerve in experiment I, a new faster component enriched in soluble tubulin and actin was observed that was not present in the control nerve. The rate of the slower main component containing most of the insoluble tubulin and actin together with neurofilament proteins was not affected. A smaller but significant peak of radioactivity enriched in soluble tubulin and actin was also detected ahead of the main peak when the response of the preexisting cytoskeleton was examined in experiment II. It is thus concluded that during regeneration changes in the organization take place in both the newly synthesized and the preexisting axonal cytoskeleton, resulting in a selective acceleration in rate of transport of soluble tubulin and actin.     

Tubulin and Neurofilament Proteins Are Transported Differently in Axons of Chicken Motoneurons

SUMMARY 1. We previously showed that actin is transported in an unassembled form with its associated proteins actin depolymerizing factor, cofilin, and profilin. Here we examine the specific activities of radioactively labeled tubulin and neurofilament proteins in subcellular fractions of the chicken sciatic nerve following injection of L-[³⁵S]methionine into the lumbar spinal cord.2. At intervals of 12 and 20 days after injection, nerves were cut into 1-cm segments and separated into Triton X-100-soluble and particulate fractions. Analysis of the fractions by high-resolution two-dimensional gel electrophoresis, immunoblotting, fluorography, and computer densitometry showed that tubulin was transported as a unimodal wave at a slower average rate (2–2.5 mm/day) than actin (4–5 mm/day). Moreover, the specific activity of soluble tubulin was five times that of its particulate form, indicating that tubulin is transported in a dimeric or small oligomeric form and is assembled into stationary microtubules.3. Neurofilament triplet proteins were detected only in the particulate fractions and transported at a slower average rate (1 mm/day) than either actin or tubulin.4. Our results indicate that the tubulin was transported in an unpolymerized form and that the neurofilament proteins were transported in an insoluble, presumably polymerized form.     

Early Effects of β,β'-Iminodipropionitrile on Tubulin Solubility and Neurofilament Phosphorylation in the Axon

Abstract: To elucidate the role of neurofilaments in microtubule stabilization in the axon, we studied the effects of β,β'-iminodipropionitrile (IDPN) on the solubility and transport of tubulin as well as neurofilament phosphorylation in the motor fibers of the rat sciatic nerve. IDPN is known to impair the axonal transport of neurofilaments, causing accumulation of neurofilaments in the proximal axon and segregation of neurofilaments to the peripheral axoplasm throughout the nerve. Administration of IDPN at various intervals after radioactive labeling of the spinal cord with l -[³⁵S]methionine revealed that transport inhibition occurred all along the nerve within 1–2 days. Transport of cold-insoluble tubulin, which accounts for 50% of axonal tubulin, was also affected. A significant increase in the proportion of cold-soluble tubulin was observed, reaching a maximum at 3 days after IDPN treatment and returning to the control level in the following weeks. Preceding this change in tubulin solubility, a transient decrease in the phosphorylation level of the 200-kDa neurofilament protein was detected in the ventral root using phosphorylation-dependent antibodies. These early changes agreed in timing with the onset of segregation and transport inhibition, suggesting that interaction between neurofilaments and microtubules possibly regulated by phosphorylation plays a significant role in microtubule stabilization.     

Binding of γ-Aminobutyric AcidA Receptors to Tubulin

Abstract: The rate of axonal transport of tubulin, actin, and the neurofilament proteins was measured in the peripheral and central projections of the rat L5 dorsal root ganglion (DRG). [³⁵S]Methionine was injected into the DRG, and the "front" of the radiolabeled protein was located 7, 14, and 20 days postinjection. Transport rates calculated for the neurofilament triplet proteins, tubulin, and actin in the peripheral nerve were ∼ 1.5-fold faster than those in the dorsal root. A progressive decrease in the rate of transport was observed from 7 to 20 days after radiolabeling in both the central and peripheral directions (neurofilaments, ∼ 1.7-fold; tubulin/actin, 2.1-fold). A surgical preparation, leaving the peripheral sciatic nerve with predominantly sensory fibers, was the basis for ELISAs for phosphorylation-dependent immunoreactivity of the high-molecular-weight neurofilament protein. In both dorsal roots and peripheral sensory axons the degree of phosphorylation was greater in nerve segments further away from the cell bodies. The degree of phosphorylation-related immunoreactivity correlates with the slowing of transport of radiolabeled cytoskeletal protein.     

In vitro binding of [14C]2,5-hexanedione to rat neuronal cytoskeletal proteins

2,5-Hexanedione (2,5-HD) induces central-peripheral axonpathy characterized by the accumulation of 10-nm neurofilaments proximal to the nodes of Ranvier and a Wallerian-type degeneration. It has been postulated that neurofilament crosslinking may be involved in the production of this axonopathy. A potential initiating event in this neurotoxic process may be the direct binding of 2,5-HD to neurofilament and microtubule proteins. In this study, the in vitro binding of [¹⁴C]2,5-HD to neurofilament and microtubule proteins was examined. Neurofilament proteins isolated from rat spinal cord or microtubule proteins isolated from rat brain were incubated in the presence of 2,5-HD at concentrations ranging 25 to 500 mM. Quantitative analysis of sodium dodecyl sulfate (SDS) polyacrylamide gels revealed a dose- and time-dependent binding of 2,5-HD to both neurofilament proteins and microtubule proteins. Expressed as pmol 2,5-HD bound per g protein, the observed relative binding was MAP2>NF160>NF200>NF68>tubulin. These data demonstrate the direct binding of 2,5-HD to cytoskeletal proteins including both neurofilaments and microtubules.     

Importance of Non-Selective Cation Channel TRPV4 Interaction with Cytoskeleton and Their Reciprocal Regulations in Cultured Cells

Background

TRPV4 and the cellular cytoskeleton have each been reported to influence cellular mechanosensitive processes as well as the development of mechanical hyperalgesia. If and how TRPV4 interacts with the microtubule and actin cytoskeleton at a molecular and functional level is not known.

Methodology and Principal Findings

We investigated the interaction of TRPV4 with cytoskeletal components biochemically, cell biologically by observing morphological changes of DRG-neurons and DRG-neuron-derived F-11 cells, as well as functionally with calcium imaging. We find that TRPV4 physically interacts with tubulin, actin and neurofilament proteins as well as the nociceptive molecules PKCε and CamKII. The C-terminus of TRPV4 is sufficient for the direct interaction with tubulin and actin, both with their soluble and their polymeric forms. Actin and tubulin compete for binding. The interaction with TRPV4 stabilizes microtubules even under depolymerizing conditions in vitro. Accordingly, in cellular systems TRPV4 colocalizes with actin and microtubules enriched structures at submembranous regions. Both expression and activation of TRPV4 induces striking morphological changes affecting lamellipodial, filopodial, growth cone, and neurite structures in non-neuronal cells, in DRG-neuron derived F11 cells, and also in IB4-positive DRG neurons. The functional interaction of TRPV4 and the cytoskeleton is mutual as Taxol, a microtubule stabilizer, reduces the Ca²⁺-influx via TRPV4.

Conclusions and Significance

TRPV4 acts as a regulator for both, the microtubule and the actin. In turn, we describe that microtubule dynamics are an important regulator of TRPV4 activity. TRPV4 forms a supra-molecular complex containing cytoskeletal proteins and regulatory kinases. Thereby it can integrate signaling of various intracellular second messengers and signaling cascades, as well as cytoskeletal dynamics. This study points out the existence of cross-talks between non-selective cation channels and cytoskeleton at multiple levels. These cross talks may help us to understand the molecular basis of the Taxol-induced neuropathic pain development commonly observed in cancer patients.     

The effect of ruthenium red on the assembly and disassembly of microtubules and on rapid axonal transport

The assembly of microtubules was found to decrease in proportion to the amount of added ruthenium red, indicating a high affinity of ruthenium red for the microtubule system. An equimolar amount of ruthenium red per tubulin dimer inhibited the microtubule assembly completely and disassembled existing microtubules. Binding of ruthenium red to tubulin is accompanied by a shift in the absorption maximum from 535 to 538 nm. The binding is very strong, as shown by the finding that ruthenium red could not be displaced from tubulin by gel chromatography on Sephadex, or by the addition of Ca²⁺ or Mg²⁺. The binding of ruthenium red to tubulin did not affect the single colchicine site, nor the Mg²⁺ site(s), as shown by use of Mn²⁺ as an EPR probe. Ruthenium red also interfered with microtubules in an intact cell system, as it inhibited rapid axonal transport in the frog sciatic nerve, measured by the accumulation of [³H]leucine-labelled proteins in front of a ligature.     

Quantitative Analysis of Axonal Transport of Cytoskeletal Proteins in Chicken Oculomotor Nerve

We studied the axonal transport characteristics of major cytoskeletal proteins: tubulin, the 69,000 molecular weight protein of chicken neurofilaments, and actin. After intracerebral injection of [35S]methionine, we monitored the specific radioactivity of these proteins as they passed through a very short nerve segment of the chicken oculomotor nerve. Specific radioactivities were assessed by quantitative sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. The transport patterns obtained for tubulin and the neurofilament protein were very similar, corresponding to transport rate ranges of 1-15 and 1-10 mm/day, respectively. A narrower velocity range of 3 to 4.3 mm/day was found for actin. Tubulin and the neurofilament protein appeared to be largely dispersed during the course of their transit along the nerve. The radioactivity associated with the proteins studied persisted in the nerve segment for a long time after the bulk of the labeled molecules had swept down. Finally, none of these proteins was observed to be transported with the fast axonal transport.     

Biochemical changes in sciatic nerve of hens treated with tri-o-cresyl phosphate: increased phosphorylation of cytoskeletal proteins.

Calcium- and calmodulin-regulated protein phosphorylation has been suggested to play a role in the pathogenesis of organophosphorus compound-induced delayed neurotoxicity (OPIDN). This condition is characterized by ataxia that progresses to paralysis concurrent with a central-peripheral distal axonopathy after a delay period of 1-2 weeks following exposure to an organophosphorus compound causing delayed neurotoxicity, such as tri-o-cresyl phosphate (TOCP). Calcium/calmodulin (CaM) kinase II is involved in the increased phosphorylation of brain microtubule and spinal cord neurofilament triplet proteins following treatment of animals with organophosphorus compounds that are capable of producing OPIDN. In this study, chickens were given a single oral neurotoxic dose of 750 mg TOCP/kg body weight and killed after 1, 6, 14 or 21 days following treatment. Protein kinase-mediated phosphorylation of cytoskeletal proteins was studied in proximal and distal parts of sciatic nerves of control and treated hens. Peripheral nerve proteins were phosphorylated in vitro using [gamma-32P]ATP as a phosphoryl group donor. Phosphorylated proteins were separated by one- and two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. Protein phosphorylation was detected by autoradiography and quantified by laser microdensitometry. The extent of Ca2+-calmodulin dependent phosphorylation of five cytoskeletal proteins was significantly increased in TOCP treated animals, particularly at 1 and 6 days after treatment, in both the proximal and distal portion of the nerve. The identity of these proteins was confirmed by 2-D PAGE as tubulin, the neurofilament triplet proteins and microtubule associated protein-2 (MAP-2). These results confirm earlier observation of the close temporal relationship between increased cytoskeletal protein phosphorylation and the development and OPIDN.     

Differential axonal transport of isotubulins in the motor axons of the rat sciatic nerve

The axonal transport of the diverse isotubulins in the motor axons of the rat sciatic nerve was studied by two-dimensional polyacrylamide gel electrophoresis after intraspinal injection of [35S]methionine. 3 wk after injection, the nerve segments carrying the labeled axonal proteins of the slow components a (SCa) and b (SCb) of axonal transport were homogenized in a cytoskeleton-stabilizing buffer and two distinct fractions, cytoskeletal (pellet, insoluble) and soluble (supernatant), were obtained by centrifugation. About two-thirds of the transported-labeled tubulin moved with SCa, the remainder with SCb. In both waves, tubulin was found to be associated mainly with the cytoskeletal fraction. The same isoforms of tubulin were transported with SCa and SCb; however, the level of a neuron-specific beta-tubulin subcomponent, termed beta', composed of two related isotubulins beta'1 and beta'2, was significantly greater in SCb than in SCa, relative to the other tubulin isoforms. In addition, certain specific isotubulins were unequally distributed between the cytoskeletal and the soluble fractions. In SCa as well as in SCb, alpha'-isotubulins were completely soluble in the motor axons. By contrast, alpha' and beta'2-isotubulins, both posttranslationally modified isoforms, were always recovered in the cytoskeletal fraction and thus may represent isotubulins restricted to microtubule polymers. The different distribution of isotubulins suggests that a recruitment of tubulin isoforms, including specific posttranslational modifications of defined isoforms (such as, at least, phosphorylation of beta' and acetylation of alpha'), might be involved in the assembly of distinct subsets of axonal microtubules displaying differential properties of stability, velocity and perhaps of function.     

Slow transport of the cytoskeleton after axonal injury

The delivery of cytoskeletal proteins to the axon occurs by slow axonal transport. We examined how the rate of slow transport was altered after axonal injury. When retinal ganglion cell (RGC) axons regenerated through peripheral nerve grafts, an increase in the rate of slow transport occurred during regrowth of the injured axons. We compared these results to axonal injury in the optic nerve where no substantial regrowth occurs and found a completely different response. Slow transport was decreased approximately tenfold in rate in the proximal segment of crushed optic nerves. This decreased rate of slow transport was not induced immediately, but occurred about 1 week after injury. To explore whether a decrease in the rate of slow transport was induced when the regeneration of peripheral nerves was physically blocked, we examined slow transport in motor neurons after the sciatic nerve was transected and ligated. In this case, no change in the rate of the comigrating tubulin and neurofilament (NF) radioactive peaks were observed. We discuss how the changes in the rate of slow transport may reflect different neuronal responses to injury and speculate about the possible molecular changes in the expression of tubulin which may contribute to the observed changes. © 1992 John Wiley & Sons, Inc.     

Slow transport of the cytoskeleton after axonal injury.

The delivery of cytoskeletal proteins to the axon occurs by slow axonal transport. We examined how the rate of slow transport was altered after axonal injury. When retinal ganglion cell (RGC) axons regenerated through peripheral nerve grafts, an increase in the rate of slow transport occurred during regrowth of the injured axons. We compared these results to axonal injury in the optic nerve where no substantial regrowth occurs and found a completely different response. Slow transport was decreased approximately tenfold in rate in the proximal segment of crushed optic nerves. This decreased rate of slow transport was not induced immediately, but occurred about 1 week after injury. To explore whether a decrease in the rate of slow transport was induced when the regeneration of peripheral nerves was physically blocked, we examined slow transport in motor neurons after the sciatic nerve was transected and ligated. In this case, no change in the rate of the comigrating tubulin and neurofilament (NF) radioactive peaks were observed. We discuss how the changes in the rate of slow transport may reflect different neuronal responses to injury and speculate about the possible molecular changes in the expression of tubulin which may contribute to the observed changes.     

Effects of taxol on slow and fast axonal transport

Axonal transport of tubulin in the rat sciatic nerve is almost completely inhibited by a single subepineural injection of taxol, without affecting that of neurofilament proteins. Actin and a large number of polypeptides cotransported with actin as minor components are also blocked by taxol, although to a lesser extent. Fast axonal transport is essentially free from the inhibitory effect of this drug. Although previous models have suggested that slow axonal transport involves the bulk movement of cytoskeletal structures, these results suggest that such transport may involve an equilibrium between polymerised and depolymerised forms of the axonal cytoskeleton.     

Increases in microtubule assembly and in tubulin content in mitogenically stimulated mouse splenic T lymphocytes

We have examined the changes in the microtubule and tubulin contents in populations of mouse splenic T lymphocytes stimulated by the mitogen concanavalin A. Indirect immunofluorescence staining with antiserum to tubulin indicated that a more extensive microtubule network was assembled from the centrosome in those cells which had increased in size in response to the mitogen. Direct counts of microtubules from electron micrographs of the centrosome regions of cells showed approximately a 2-fold increase in microtubule number in 48 h stimulated populations and up to a 5-fold increase in the large, fully stimulated, blast cells. Determinations of tubulin and actin contents were made by the measurement of peptides specific to those proteins. As a percentage of total cell protein both of these cytoskeletal proteins increased during the first 24 h of stimulation. Tubulin increased 50% by 24 h and remained high in populations stimulated for 48 h. The tubulin content per cell increased 2.5-fold, from 0.20 to 0.51 μg/10⁶ cells, in the 48 h stimulated population. An increase in tubulin content was also seen following the stimulation of nude mouse B lymphocyte populations and of total splenic lymphocyte populations. Our results show that during lymphocyte stimulation there is a large increase in the numbers of microtubules assembled which is correlated with, and appears dependent on, a similar large increase in the cellular tubulin content.     

Calcium activated proteolysis of fibrous proteins in central nervous system

A Ca²⁺ activated protease(s) capable of hydrolyzing several polypeptides at neutral pH including cytoskeletal proteins, actin, myosin, tubulin and neurofilament triplet was identified in calf brain cortex. The enzyme activity precipitates at 75 mM KCl, pH 6.5 – 7.0 and is inhibited by the sulfhydryl inhibitors, N-ethylmaleimide and para-chloromercuribenzoate and the protease inhibitors, antipain, pepstatin and leupeptin, leupeptin being the most effective.     

58,000 Dalton Intermediate Filament Proteins of Neuronal and Nonneuronal Origin in the Goldfish Visual Pathway

A group of proteins in the goldfish optic nerve with a molecular weight of 58K daltons was analyzed by two-dimensional gel electrophoresis. Results show that the proteins are differentially phosphorylated and found exclusively in a cytoskeletal-enriched fraction. The proteins from this fraction can be reconstituted into typical intermediate filament structures, as shown by electron microscopy. Two components which are of neuronal origin are transported within the slow phase of transport. The 58K proteins are the most abundant proteins in the optic nerve, and they are distinct from actin and tubulin. It was concluded that they are intermediate filament proteins. Cytoskeletal preparations of rat spinal cord, rat optic nerve, and goldfish optic nerve were compared by one-dimensional gel electrophoresis. The rat spinal cord contains glial fibrillary acidic protein (GFAP), and the rat optic nerve contains vimentin and GFAP, in addition to the neurofilament triplet. A typical mammalian neurofilament triplet is not detected in the goldfish optic nerve, while the major cytoskeletal constituent is a 58K band which coelectrophoreses with vimentin in the rat optic nerve by one-dimensional gel electrophoresis.     

PACSIN proteins bind tubulin and promote microtubule assembly

PACSINs are intracellular adapter proteins involved in vesicle transport, membrane dynamics and actin reorganisation. In this study, we report a novel role for PACSIN proteins as components of the centrosome involved in microtubule dynamics. Glutathione S-transferase (GST)-tagged PACSIN proteins interacted with protein complexes containing α- and γ-tubulin in brain homogenate. Analysis of cell lysates showed that all three endogenous PACSINs co-immunoprecipitated dynamin, α-tubulin and γ-tubulin. Furthermore, PACSINs bound only to unpolymerised tubulin, not to microtubules purified from brain. In agreement, the cellular localisation of endogenous PACSIN 2 was not affected by the microtubule depolymerising reagent nocodazole. By light microscopy, endogenous PACSIN 2 localised next to γ-tubulin at purified centrosomes from NIH 3T3 cells. Finally, reduction of PACSIN 2 protein levels with small-interfering RNA (siRNA) resulted in impaired microtubule nucleation from centrosomes, whereas microtubule centrosome splitting was not affected, suggesting a role for PACSIN 2 in the regulation of tubulin polymerisation. These findings suggest a novel function for PACSIN proteins in dynamic microtubuli nucleation.