Differential Display Reveals Transcriptional Up-regulation of the Motor Molecules for Both Anteroarade and Retrograde Axonal Transport During Nerve Regeneration

RNA fingerprinting using an arbitrary primed polymerase chain reaction was carried out to compare differences in expression of mRNAs between axotomized and normal hypoglossal motoneurons in the mouse. In this survey, the kinesin light chain (KLC) was identified as a nerve injury-associated molecule. This was also confirmed by in situ hybridization using hemihypoglossal nerve-transected brain sections. In order to identify the exact species of molecules belonging to the KLC family, in situ hybridization was carried out with oligonucleotide probes specific to rat KLC A, KLC B and KLC C, using the rat hypoglossal nerve injury model. In addition, expression of both ubiquitous and neuron-specific kinesin heavy chain and cytoplasmic dynein which is a retrograde motor, was also examined. Expression of all the members of the KLC (A-C) family and dynein was up-regulated during nerve regeneration, whereas the abundant expression of the neuron-specific KHC mRNA was not changed. The present results indicate that the molecules associated with both anterograde and retrograde axonal transport are up-regulated in their expression during efferent motor nerve regeneration, suggesting that the retrograde transport of growth factors and anterograde transport of vesicles, providing membrane material, could be increased during motor nerve regeneration.     

Delivery of Recombinant Tetanus–Superoxide Dismutase Proteins to Central Nervous System Neurons by Retrograde Axonal Transport

The nontoxic C fragment of tetanus toxin (TC) can transport other proteins from the circulation to central nervous system (CNS) motor neurons. Increased levels of CuZn superoxide dismutase (SOD) are protective in experimental models of stroke and Parkinson's disease, whereas mutations in SOD can cause motor neuron disease. We have linked TC to SOD and purified the active recombinant proteins in both the TC–SOD and SOD–TC orientations. Light microscopic immunohistochemistry and quantitative enzyme-linked immunosorbant assays (ELISA) of mouse brainstem, after intramuscular injection, demonstrate that the fusion proteins undergo retrograde axonal transport and transsynaptic transfer as efficiently as TC alone.     

Differential endocytic sorting of p75NTR and TrkA in response to NGF: a role for late endosomes in TrkA trafficking

NGF binds to two receptors, p75NTR and TrkA. The endosomal trafficking of receptors is of emerging importance for the understanding of their signaling. We compared the endocytic trafficking of the two NGF receptors in PC12 cells. Both p75NTR and TrkA were internalized in response to NGF and colocalized with early endosomes. However, surprisingly, the subsequent endosomal trafficking paths of both NGF receptors diverged: whereas p75NTR recycled back to the surface, TrkA moved to late endosomes and underwent lysosomal degradation. By performing subcellular fractionations of NGF stimulated PC12 cells, tyrosine-phosphorylated TrkA was recovered in fractions corresponding to late endosomes. This implicates these organelles as novel endosomal NGF signaling platforms. Furthermore, the trafficking of NGF receptors could be manipulated by pharmacological means. Disrupting p75NTR recycling diminished TrkA activation in response to low concentrations of NGF, demonstrating a functional role for the recycling of p75NTR.     

NGF Amplifies Expression of NGF Receptor Messenger RNA in Forebrain Cholinergic Neurons of Rats

In order to study the ligand-mediated regulation of NGF receptors in vivo, we assessed NGF receptor mRNA in the septal area of both neonatal and adult rats following intraventricular NGF administration. In neonatal rats NGF treatment, in comparison with cytochrome c, elicited a pronounced augmentation in the level of NGF receptor mRNA. A similar effect was also observed following continuous intraventricular NGF infusion in young adult rats. In addition, in this latter case, the increase in NGF receptor mRNA was associated with an increase in NGF receptor-related immunoreactivity, most likely associated with the cholinergic neurons, in the septal area. These results show that NGF itself may regulate expression of NGF receptor mRNA and corresponding protein levels in forebrain cholinergic neurons and suggest that NGF effects in the CNS may be mediated by an up-regulation of NGF receptors.     

Axonal Transport of Neprilysin in Rat Sciatic Nerves

Axonal transport of neprilysin, a putative neuropeptide degrading-enzyme, was examined in the proximal, middle, and distal segments of rat sciatic nerves using a double ligation technique. Neprilysin activity was significantly increased not only in the proximal segment but also in the distal segment 12–120 h after ligation, and the maximal neprilysin activity was found in the proximal and distal segments at 96 and 72 h, respectively. Western blot analysis of neprilysin showed that its immunoreactivities in the proximal and distal segments were 2.8- and 2.4-fold higher than that in the middle segment, indicating that neprilysin is transported by anterograde and retrograde axonal flow. These observations suggest that neprilysin may be involved in the metabolism of neuropeptides in nerve terminals or synaptic clefts.     

Persistence of Axonal Transport in Isolated Axons of the Mouse

We have examined the hypothesis, for the case of mouse axons, that isolating an axon from its cell body will lead to a rapid failure of fast axonal transport as anterogradely moving organelles vacate the axon in a proximo-distal direction, and retrogradely moving organelles vacate it in the opposite direction. We used CD1 and BALB/c mice and the Wallerian degeneration-resistant mutant C57BL/Ola. Sciatic nerves were cut high in the thigh; at various times up to 8 days later nerves were removed from the animal and individual myelinated axons from the segment distal to the cut were examined by video light microscopy to detect rapid organelle transport. Bidirectional fast organelle transport did decrease in amount with time but not nearly as rapidly as predicted, and anterograde and retrograde organelle velocities remained normal through time. In the C57BL/Ola mouse some structurally preserved axons contained organelles that transported at normal velocities in the anterograde and retrograde directions for as long as 8 days after axotomy. To test one of the possible origins of transported organelles in long-surviving axons we examined organelle transport very close to narrow lesions in axons bathed in a medium compatible with intracellular function. No organelles crossed the lesion but bidirectional organelle transport took place proximal and distal to the lesion; the amounts were compatible with the interpretation that ∼30% of organelles reversed transport direction on either side of the lesion. We propose that at least some of the organelles that undergo persistent transport in axons isolated from their cell bodies shuttle back and forth between the ends of the isolated segment.     

p75 and TrkA receptors are both required for uptake of NGF in adult sympathetic neurons: use of a novel fluorescent NGF conjugate

We have developed and tested the biological activity and specificity of a novel fluorescent dextran-Texas Red–nerve growth factor (DTR–NGF) conjugate. DTR–NGF was found to promote survival and neurite outgrowth in cultured dissociated sympathetic neurons similarly to native NGF. The conjugate was taken up and transported retrogradely by terminal sympathetic nerves innervating the iris to neurons in the ipsilateral superior cervical ganglion (SCG) of young adult rats. Uptake and transport was assessed by counting numbers of labelled neurons and by measuring intensity of neuronal labelling using confocal microscopy and image analysis. DTR–NGF labelling in SCG neurons was shown to be dose-dependent with an EC₅₀ of 75 ng. Similar concentrations of unconjugated DTR resulted in no neuronal labelling. DTR–NGF uptake was competed off using a 50-fold excess of native NGF, resulting in a 73% reduction in numbers of labelled neurons. Pretreatment of nerve terminals with function-blocking antibodies against the low (p75) and high (TrkA) affinity NGF receptors resulted in a large (85–93%) reduction in numbers of DTR–NGF labelled neurons. Anti-p75 and anti-TrkA antibodies had comparable effects which were concentration-dependent. These findings indicate that both receptors are required for uptake of NGF in adult rat sympathetic neurons. In particular, the results provide strong evidence that the p75 receptor plays a more active role in transducing the NGF signal than has been proposed.     

Loss of cell adhesion impairs the early response of TrkA to nerve growth factor (NGF)

Within the in vitro model of nerve growth factor (NGF)-dependent differentiation of PC12 cells, loss of adhesion is known to interfere with certain neurotrophic responses and not with others. The present analysis of early NGF signaling shows that the upstream activation of TrkA, as well as the recruitment of the adaptor protein Shc, are dramatically attenuated upon loss of cell adhesion, while the downstream activation of ERK1/2 is unaffected. That loss of cell adhesion interferes with the primary signaling response to NGF (i.e. autophosphorylation of TrkA) may explain why suspended PC12 cells fail to morphologically differentiate in response to NGF. The possibility that established adhesion-driven mechanisms underlie the full responsiveness of TrkA to NGF is discussed.     

Methylmercury inhibits TrkA signaling through the ERK1/2 cascade after NGF stimulation of PC12 cells

Using PC12 cells as a model of neuronal differentiation, we have shown that acute exposure to methylmercury (CH3Hg) inhibits nerve growth factor (NGF)-induced activation of TrkA. In the present study, we examined the effects of CH3Hg on pathways activated by NGF. NGF-induced phosphorylation of ERK1/2 in PC12 cells was time-dependent. Concurrent exposure to CH3Hg and NGF for 2.5 min resulted in a concentration-dependent inhibition of ERK1/2 phosphorylation (EC50 = 0.018 microM). However, NGF-stimulated ERK1/2 phosphorylation was not altered after 5 min of exposure to CH3Hg. In vitro studies revealed that CH3Hg did not directly inhibit the ERK kinase MEK. As reported in other neuronal tissue, CH3Hg can inhibit PKC activity in vitro. Incubation of PC12 cell lysates with CH3Hg produced a concentration-dependent inhibition of PKC activity that was significant at 0.3-10 microM. Further studies using recombinant enzymes examined the effect of CH3Hg on PKC isoforms expressed in PC12 cells. CH3Hg inhibited PKCdelta, and zeta activity in a concentration-dependent manner at higher concentrations (3-10 microM), while a significant increase in PKCalpha activity was observed at lower concentrations (0.1 microM). However, CH3Hg had no affect on NGF-induced PKC activity in intact cells. These results show that CH3Hg inhibition of NGF-stimulated TrkA activation in PC12 cells decreases downstream signaling through the Raf/MEK/ERK cascade. In intact cells PKC does not appear to be a primary target for CH3Hg.     

Transport and elimination of recombinant human NGF during long-term delivery to the brain

The gene for human nerve growth factor (NGF) has been cloned into a mammalian cell line and large quantities of recombinant human NGF (rhNGF) can now be produced for clinical use, but little is known about the fate of rhNGF following delivery to the brain. In this study, we implanted polymer matrices containing¹²⁵l-labeled rhNGF into the brains of adult rats and measured spatial distributions of the released protein for 8 weeks after implantation. NGF content in the tissue was determined by counting gamma radiation in thick (1 mm) sections and by autoradiography of thin (20 μm) sections. For the first several days, the rate of NGF release from the polymer matrix was high ( 100 ng/day); maximal NGF concentrations, measured at the polymer-tissue interface, were correspondingly high (> 20 μg/ml) through day 4. At later times, the release rate decreased (2–10 ng/day) and lower maximal concentrations were observed (1–10 μg/ml). NGF levels were always highest in the tissue sections closest to the polymer; during the 8 weeks of the experiment, NGF levels measured in thick sections decreased 100-fold, from 30 ng/section at day 2 to 0.3 ng/section at day 54. The first 10-fold decrease occurred during the first 10 days of the study; a further 6 weeks was required to achieve the second 10-fold decrease. Throughout the experiment, the majority of NGF remained within a restricted zone around the polymer at all times; the mass of NGF decreased to 10% of the maximal level within 2–3 mm of the polymer matrix. At early times (< 1 week), radiolabel corresponding to > 20 pg of NGF was also detected in regions of the brain further removed from the polymer. Comparison of local rhNGF concentration profiles with a simple mathematical model indicated that rhNGF diffuses through the brain interstitial space and is eliminated with a half-life of 45 min, although elimination appears to be substantially slower in white matter regions. This limited ability of NGF to penetrate and be retained within the brain tissue indicates that NGF will need to be delivered almost directly to the target tissue for efficacy.     

MR Imaging of Slow Axonal Transport in Vivo

Three magnetopharmaceuticals based on a monocrystalline iron oxide nanocompound (MION) are evaluated as potential contrast agents for demonstrating axonal transport in vivo by magnetic resonance (MR) imaging. One agent has a strong positive charge, one has a strong negative charge, and the third is covalently linked to wheat germ agglutinin, a plant lectin with a high affinity for axon terminals. All three agents were tagged with rhodamine, and fluorescence microscopy was used to determine their fate after administration and to validate the imaging results. Following injection into or near various neural structures in the motor and visual systems of rats, MR images were obtained at multiple times up to 11 days later, and the imaged tissues were processed for subsequent histological examination. Similar results were obtained with all three agents. Axonal transport was not seen by MR imaging or fluorescence microscopy when the agents were injected into the calf muscles, the vitreous of the eye, or the superior colliculus. However, bidirectional axonal transport was shown unequivocally by both methods after injection directly into the site of a focal crush injury to the sciatic nerve. The nerve, which otherwise is isointense with surrounding tissues on MR images, appeared as a uniformly hypointense structure having a length approximately in proportion to the time from injection to imaging. By 11 days, the course of the nerve was traceable from its component roots in the cauda equina to its bifurcation into the tibial and common peroneal nerves in the leg. A transport rate of about 5 mm/day was calculated, which is consistent with the mechanism of slow transport. MION-based magnetopharmaceuticals thus can be used to demonstrate slow axonal transport, and thereby visualize peripheral nerves, in vivo by MR imaging.     

Neurotoxicity of Human Immunodeficiency Virus-1: Viral Proteins and Axonal Transport

Human immunodeficiency virus-1 (HIV) infection of the central nervous system may cause a neurological syndrome termed HIV-associated neurocognitive disorder (HAND) which includes minor neurocognitive disorders or a more severe form of motor and cognitive impairments. Although treatment with highly active antiretroviral agents decreases the load of HIV in the brain, the prevalence of mild forms of HAND is actually increased due to longer life. Therefore, adjunctive and combined therapies must be developed to prevent and perhaps reverse the neurologic deficits observed in individuals with HAND. Key to developing effective therapies is a better understanding of the molecular and cellular mechanisms by which the virus causes this disorder. A number of HIV proteins has been shown to be released from HIV-infected cells. Moreover, these proteins have been shown to possess neurotoxic properties. This review describes new evidence of a direct interaction of the HIV protein gp120 with neurons, which might play a role in the etiopathology of HAND.     

Upregulation of Astrocytic Leptin Receptor in Mice with Experimental Autoimmune Encephalomyelitis

The detrimental role of leptin in experimental autoimmune encephalomyelitis (EAE) is opposite to its neuroprotective role in other neuropathologies. We hypothesize that a shifted cellular distribution of leptin receptors underlies the differential effects of leptin. A robust increase of ObR immunoreactivity was seen along glial fibrillary acidic protein (GFAP)(+) intermediate filaments in reactive astrocytes in the hippocampus and hypothalamus of mice with EAE. Although astrocyte-specific GFAP mRNA and protein were both increased, ObRa mRNA was elevated only after resolution of EAE symptoms, and ObRb mRNA was even decreased at the peak time of symptoms of EAE. A cell type-specific action of leptin may underlie its differential effects.     

Retrograde Axonal Transport of the α-Subunit of the GTP-binding Protein Gz in Mouse Sciatic Nerve: a Potential Pathway for Signal Transduction In Neurons

We have utilized antibodies against the α subunit of G_z in fluorescence immunohistochemistry to determine whether this GTP-binding protein can translocate along nerves by intra-axonal transport. After ligation of the mouse sciatic nerve we found an increase in G_z-like immunoreactivity on the proximal and distal side with time, suggesting that the α subunit undergoes orthograde axonal transport and also returns to the cell body by retrograde axonal transport in the sciatic nerve. Unlike the retrograde transport of G_iα, shown in a previous study to be present in most sciatic axons, G_zα only accumulated in a subpopulation of axons, suggesting that different G-proteins could convey information specific to neuronal subtypes. These results support our proposal that G_z may play a second messenger role in communicating information from the terminals back to cell bodies. G_iαand G_zα may be representative of relatively stable signalling molecules by which the signal from some neurotrophic molecules can be translocated from the neuronal periphery to the cell body without the need for the retrograde transport of the neurotrophic factor itself.     

Postnatal Changes in the Expression of the trkA High-affinity NGF Receptor in Primary Sensory Neurons

In development ∼70–80% of dorsal root ganglion (DRG) cells are dependent on nerve growth factor (NGF) for their survival, while in the adult only some 40% of DRG cells express the high-affinity NGF receptor, trkA. This discrepancy suggests that trkA expression, and therefore neurotrophin sensitivity, may alter as the animal matures. We have tested this possibility by counting the number of L4/5 DRG neurons showing immunoreactivity for trkA in rats from the day of birth to postnatal day 14. We also examined changes in p75 and IB4 labelling. On the day of birth, 71% of DRG cells were found to express trkA. However, this percentage gradually fell with age and reached adult levels at postnatal day 14. The expression of p75 did not parallel that of trkA, remaining relatively constant at between 45 and 50% of cells from birth to postnatal day 14. Over the same period there was a marked increase in the proportion of cells which bind the lectin IB4 from 9 (day of birth) to 40% (day 14). Since in the adult the 1B4 population consists of small cells which mostly do not express trkA, this finding suggests that the postnatal down-regulation of trkA occurs in this population. Consistent with this suggestion are the results of double labelling for trkA and IB4, which confirmed that at times intermediate between birth and postnatal day 14 there was a high degree of coexpression between these markers (which is absent in the adult). This result also suggests that the down-regulation of trkA is unlikely to be directly responsible for the emerging IB4 binding.     

Long-term microglial and astroglial activation in the hippocampus of trimethyltin-intoxicated rat: stimulation of NGF and TrkA immunoreactivities in astroglia but not in microglia

In the present study we investigated the microglial and astroglial response after trimethyltin (TMT) exposure over a prolonged period of time. Male Wistar rats were given a single dose of TMT (8 mg/kg, i.p.) and survived 4, 7, 21, 60 and 180 days after the administration of the toxin. Histochemistry (Griffonia simplicifolia lectin staining) and immunocytochemistry for GFAP were applied to identify micro- and astroglial cells, respectively. To assess the trophic response of glial cells (NGF and TrkA expression), single or double staining experiments were performed. In addition, the biochemical evaluation of GFAP and NGF were carried out at chosen timepoints using immunoblotting technique and ELISA, respectively. The main findings of our study were as follows. (1) A protracted activation of microglia (at least up to 2 months posttreatment). (2) A long-lasting expression of GFAP immunoreactivity (at least up to 6 months posttreatment) and a steady increase in GFAP content (at least up to 2 months posttreatment). (3) The appearance of enormously enlarged, round-shape astrocytes exclusively localized to CA1 and observed 2 months posttreatment. (4) The stimulation of NGF and TrkA expression in reactive astrocytes. (5) The strongest activation of micro- and astroglia coincided with the most prominent neurodegeneration in the hippocampus, i.e., in CA4/CA3c and CA1. It is tempting to assume that the activation of glial cells in the hippocampal areas particularly vulnerable to TMT may affect neuronal fate after neurotoxic insult.     

Transient Damage to the Axonal Transport System without Wallerian Degeneration by Acute Nerve Compression

The aim of this study was to examine whether acute nerve compression damages an axonal transport system based on microtubules and how the fibers recover after the compression. A 5-mm segment of the tibial nerve of male wistar rat was compressed with a specially designed clip. Functional recovery was assessed using Tibial Nerve Functional Index (TFI) (2). Rats were sacrificed each day from Day 0 to Day 2 and every 2 days between Day 4 and Day 10. For immunohistochemical analysis of the tibial nerve, the proximal uncompressed, the middle compressed, and the distal uncompressed segments of each section were assessed under immunofluoroscent microscopy for anti-dynein, anti-tubulin, and anti-neurofilament antibodies staining. In rats whose tibial nerve was compressed by 25 g/mm²of pressure for 5 min, staining of dynein and mirotubules in the compressed portion were obscure on Days 4–8, suggesting that the microtubules based axonal transport system was temporarily damaged, while neurofilaments were retained. In contrast, in the distal portion, anti-neurofilament staining showed no abnormality throughout the experimental period, indicating that Wallerian degeneration did not occur. We conclude that acute nerve compression can cause transient damage to the axonal transport system in nerve fibers without Wallerian degeneration.