Developmental regulation of sensory axon regeneration in the absence of growth cones

The actin filament (F-actin) cytoskeleton is thought to be required for normal axon extension during embryonic development. Whether this is true of axon regeneration in the mature nervous system is not known, but a progressive simplification of growth cones during development has been described and where specifically investigated, mature spinal cord axons appear to regenerate without growth cones. We have studied the cytoskeletal mechanisms of axon regeneration in developmentally early and late chicken sensory neurons, at embryonic day (E) 7 and 14 respectively. Depletion of F-actin blocked the regeneration of E7 but not E14 sensory axons in vitro. The differential sensitivity of axon regeneration to the loss of F-actin and growth cones correlated with endogenous levels of F-actin and growth cone morphology. The growth cones of E7 axons contained more F-actin and were more elaborate than those of E14 axons. The ability of E14 axons to regenerate in the absence of F-actin and growth cones was dependent on microtubule tip polymerization. Importantly, while the regeneration of E7 axons was strictly dependent on F-actin, regeneration of E14 axons was more dependent on microtubule tip polymerization. Furthermore, E14 axons exhibited altered microtubule polymerization relative to E7, as determined by imaging of microtubule tip polymerization in living neurons. These data indicate that the mechanism of axon regeneration undergoes a developmental switch between E7 and E14 from strict dependence on F-actin to a greater dependence on microtubule polymerization. Collectively, these experiments indicate that microtubule polymerization may be a therapeutic target for promoting regeneration of mature neurons.     

Control of growth cone motility and neurite outgrowth by SPIN90

SPIN90 is an F-actin binding protein thought to play important roles in regulating cytoskeletal dynamics. It is known that SPIN90 is expressed during the early stages of neuronal development, but details of its localization and function in growth cones have not been fully investigated. Our immunocytochemical data show that SPIN90 is enriched throughout growth cones and neuronal shafts in young hippocampal neurons. We also found that its localization correlates with and depends upon the presence of F-actin. Detailed observation of primary cultures of hippocampal neurons revealed that SPIN90 knockout reduces both growth cone areas and in the numbers of filopodia, as compared to wild-type neurons. In addition, total neurite length, the combined lengths of the longest (axonal) and shorter (dendritic) neurites, was smaller in SPIN90 knockout neurons than wild-type neurons. Finally, Cdc42 activity was down-regulated in SPIN90 knockout neurons. Taken together, our findings suggest that SPIN90 plays critical roles in controlling growth cone dynamics and neurite outgrowth.     

Ezrin functionality and hypothermic preservation injury in LLC-PK1 cells

Renal epithelial cells from donor kidneys are susceptible to hypothermic preservation injury, which is attenuated when they over express the cytoskeletal linker protein ezrin. This study was designed to characterize the mechanisms of this protection. Renal epithelial cell lines were created from LLC-PK1 cells, which expressed mutant forms of ezrin with site directed alterations in membrane binding functionality. The study used cells expressing wild type ezrin, T567A, and T567D ezrin point mutants. The A and D mutants have constitutively inactive and active membrane binding conformations, respectively. Cells were cold stored (4 °C) for 6-24 h and reperfused for 1h to simulate transplant preservation injury. Preservation injury was assessed by mitochondrial activity (WST-1) and LDH release. Cells expressing the active ezrin mutant (T567D) showed significantly less preservation injury compared to wild type or the inactive mutant (T567A), while ezrin-specific siRNA knockdown and the inactive mutant potentiated preservation injury. Ezrin was extracted and identified from purified mitochondria. Furthermore, isolated mitochondria specifically bound anti-ezrin antibodies, which were reversed with the addition of exogenous recombinant ezrin. Recombinant wild type ezrin significantly reduced the sensitivity of the mitochondrial permeability transition pore (mPTP) to calcium, suggesting ezrin may modify mitochondrial function. In conclusion, the cytoskeletal linker protein ezrin plays a significant role in hypothermic preservation injury in renal epithelia. The mechanisms appear dependent on the molecule's open configuration (traditional linker functionality) and possibly a novel mitochondrial specific role, which may include modulation of mPTP function or calcium sensitivity.     

Manifold reduction of moesin in fetal Down syndrome brain

Moesin is a member of the ERM family and is involved in plasma membrane-actin cytoskeleton cross-linking, resulting cell adhesion, shape, and motility. Because moesin was shown to be highly expressed in growth cones and moesin/radixin suppression led to impaired structure and function of this key element in brain development, we tested the ERM family, ezrin, radixin, and moesin, in fetal Down syndrome (DS) cortex at the early second trimester. We applied two-dimensional gel electrophoresis with subsequent MALDI detection and identification of protein spots followed by quantification with specific software. Moesin was shown to be significantly and manifold reduced in fetal DS brain, whereas reduction of ezrin and radixin did not reach statistical significance. We therefore propose the involvement of moesin in developmental impairment of DS brain, including deteriorated arborisation, neuritic outgrowth, and neuronal migration. Furthermore, decreased moesin is the second F-actin bundling protein, besides drebrin, that is manifold reduced in fetal DS brain.     

Role of spectrin in Amoeba proteus, as studied by microinjection of anti-spectrin monoclonal antibodies.

Spectrin is a major protein accounting for about 5% of whole-cell proteins in Amoeba proteus, and the precipitation of spectrin by intracellular injection of purified anti-spectrin monoclonal antibodies has a profound effect on cell morphology, motility, and movement-related cell activities in amoebae. Thus, amoebae injected with anti-spectrin antibodies show drastic changes in their shape and movement, suggesting that amoeba spectrin plays an important structural role, unlike nonerythroid spectrins in other cells. However, precipitation of spectrin does not affect the distribution of F-actin in amoebae.     

Cdc42 and actin control polarized expression of TI-VAMP vesicles to neuronal growth cones and their fusion with the plasma membrane

Tetanus neurotoxin-insensitive vesicle-associated membrane protein (TI-VAMP)-mediated fusion of intracellular vesicles with the plasma membrane is crucial for neurite outgrowth, a pathway not requiring synaptobrevin-dependent exocytosis. Yet, it is not known how the TI-VAMP membrane trafficking pathway is regulated or how it is coordinated with cytoskeletal dynamics within the growth cone that guide neurite outgrowth. Here, we demonstrate that TI-VAMP, but not synaptobrevin 2, concentrates in the peripheral, F-actin-rich region of the growth cones of hippocampal neurons in primary culture. Its accumulation correlates with and depends upon the presence of F-actin. Moreover, acute stimulation of actin remodeling by homophilic activation of the adhesion molecule L1 induces a site-directed, actin-dependent recruitment of the TI-VAMP compartment. Expression of a dominant-positive mutant of Cdc42, a key regulator of cell polarity, stimulates formation of F-actin- and TI-VAMP-rich filopodia outside the growth cone. Furthermore, we report that Cdc42 activates exocytosis of pHLuorin tagged TI-VAMP in an actin-dependent manner. Collectively, our data suggest that Cdc42 and regulated assembly of the F-actin network control the accumulation and exocytosis of TI-VAMP-containing membrane vesicles in growth cones to coordinate membrane trafficking and actin remodeling during neurite outgrowth.     

Long-range signaling in growing neurons after local elevation of cyclic AMP-dependent activity

Cyclic AMP-dependent activity at the growth cone or the soma of cultured Xenopus spinal neurons was elevated by local extracellular perfusion of the neuron with culture medium containing 8-bromoadenosine 3',5'-cyclic monophosphate (8-br-cAMP) or forskolin. During local perfusion of one of the growth cones of multipolar neurons with these drugs, the perfused growth cone showed further extension, while the distant, unperfused growth cones were inhibited in their growth. Local perfusion of the growth cone with culture medium or local perfusion with 8-br-cAMP at a cell-free region 100 microns away from the growth cone did not produce any effect on the extension of the growth cone. Reduced extension of all growth cones was observed when the perfusion with 8-br-cAMP was restricted to the soma. The distant inhibitory effect does not depend on the growth of the perfused growth cone since local coperfusion of the growth cone with 8-br-cAMP and colchicine inhibited growth on both perfused and unperfused growth cones, while local perfusion with colchicine alone inhibited only the perfused growth cone. The distant inhibitory effect was abolished when the perfusion of 8-br-cAMP was carried out together with kinase inhibitor H- 8, suggesting the involvement of cAMP-dependent protein kinase and/or its downstream factors in the long-range inhibitory signaling. Uniform exposure of the entire neuron to bath-applied 8-br-cAMP, however, led to enhanced growth activity at all growth cones. Thus, local elevation of cAMP-dependent activity produces long-range and opposite effects on distant parts of the neuron, and a cytosolic gradient of second messengers may produce effects distinctly different from those following uniform global elevation of the messenger, leading to differential growth regulation at different regions of the same neuron.     

Cytoskeletal remodeling during growth cone-target interactions

Reorganization of the cytoskeleton of neuronal growth cones in response to environmental cues underlies the process of axonal guidance. Most previous studies addressing cytoskeletal changes during growth cone pathfinding have focused on the dynamics of a single cytoskeletal component. We report here an investigation of homophilic growth cone- target interactions between Aplysia bag cell neurons using digitally enhanced video microscopy, which addresses dynamic interactions between actin filaments and microtubules. After physical contact of a growth cone with a physiological target, mechanical coupling occurred after a delay; and then the growth cone exerted forces on and displaced the target object. Subsequent to coupling, F-actin accumulation was observed at the target contact zone, followed by preferential microtubule extension to the same site. After successful target interactions, growth cones typically moved off highly adhesive poly-L- lysine substrates into native target cell surfaces. These events were associated with modulation of both the direction and rate of neurite outgrowth: growth cone migration was typically reoriented to a trajectory along the target interaction axis and rates of advance increased by about one order of magnitude. Directed microtubule movements toward the contact site appeared to be F-actin dependent as target site-specific microtubule extension and bundling could be reversibly randomized by micromolar levels of cytochalasin B in a characteristic manner. Our results suggest that target contacts can induce focal F-actin assembly and reorganization which, in turn, guides target site-directed microtubule redistribution.     

Ezrin Mediates Neuritogenesis via Down-Regulation of RhoA Activity in Cultured Cortical Neurons

Neuronal morphogenesis is implicated in neuronal function and development with rearrangement of cytoskeletal organization. Ezrin, a member of Ezrin/Radixin/Moesin (ERM) proteins links between membrane proteins and actin cytoskeleton, and contributes to maintenance of cellular function and morphology. In cultured hippocampal neurons, suppression of both radixin and moesin showed deficits in growth cone morphology and neurite extensions. Down-regulation of ezrin using siRNA caused impairment of netrin-1-induced axon outgrowth in cultured cortical neurons. However, roles of ezrin in the neuronal morphogenesis of the cultured neurons have been poorly understood. In this report, we performed detailed studies on the roles of ezrin in the cultured cortical neurons prepared from the ezrin knockdown (Vil2^kd/kd) mice embryo that showed a very small amount of ezrin expression compared with the wild-type (Vil2^+/+) neurons. Ezrin was mainly expressed in cell body in the cultured cortical neurons. We demonstrated that the cultured cortical neurons prepared from the Vil2^kd/kd mice embryo exhibited impairment of neuritogenesis. Moreover, we observed increased RhoA activity and phosphorylation of myosin light chain 2 (MLC2), as a downstream effector of RhoA in the Vil2^kd/kd neurons. In addition, inhibition of Rho kinase and myosin II rescued the impairment of neuritogenesis in the Vil2^kd/kd neurons. These data altogether suggest a novel role of ezrin in the neuritogenesis of the cultured cortical neurons through down-regulation of RhoA activity.     

Immunodetection of the microvillous cytoskeleton molecules villin and ezrin in the parasitophorous vacuole wall of Cryptosporidium parvum (Protozoa: Apicomplexa)

Microvilli - actin - villin - ezrin - Cryptosporidium parvum The sporozoites and merozoites of the Apicomplexan protozoan Cryptosporidium parvum (C. parvum) invade the apical side of enterocytes and induce the formation of a parasitophorous vacuole which stays in the brush border area and disturbs the distribution of microvilli. The vacuole is separated from the apical cytoplasm of the cell by an electron-dense layer of undetermined composition. In order to characterize the enterocyte cytoskeleton changes that occur during C. parvum invasion and development, we used both confocal immunofluorescence and immunoelectron microscopy to examine at the C.parvum-enterocyte interface the distribution of three components of the microvillous skeleton, actin, villin and ezrin. In infected cells, rhodamine-phalloidin and anti-villin and anti-ezrin antibodies recognized ring-like structures surrounding the developing parasites. By immunoelectron microscopy, both villin and ezrin were detected in the parasitophorous vacuole wall surrounding the luminal and lateral sides of the intracellular parasite. In contrast, anti-beta and anti-gamma actin antibodies showed no significant labelling of the vacuolar wall. These observations indicate that the parasitophorous vacuole wall contains at least two microvillus-derived components, villin and ezrin, as well as a low amount of F-actin. These data suggest that C.parvum infection induces a rearrangement of cytoskeleton molecules at the apical pole of the host cell that are used to build the parasitophorous vacuole.     

Axon initiation and growth cone regeneration in cultured motor neurons

Axon initiation in cultured neurons from embryonic ciliary ganglia involves a process in which cell surface motile activity gradually becomes restricted to sites of growth cone formation. Once frank growth cones have commenced to move outward, away from the soma, the broad connecting isthmus of cytoplasm connecting the growth cone to the soma rounds up to form the base of the definitive axon. Motile activity usually does not occur along the sides of axons or of somas. When axons are cut using sharp blades, ruffling and microspike activity are seen on both proximal and distal stumps within times as short as 3–10 min. On rare occasions, portions of the somal surface may also display ruffling and motile activity. It is concluded that the capacity to generate new growth cones and cell surface movements characteristic of locomotion is widely distributed through axoplasm and the neuron.     

Neurotrophin regulation of beta-actin mRNA and protein localization within growth cones.

Neurotrophins play an essential role in the regulation of actin-dependent changes in growth cone shape and motility. We have studied whether neurotrophin signaling can promote the localization of beta-actin mRNA and protein within growth cones. The regulated localization of specific mRNAs within neuronal processes and growth cones could provide a mechanism to modulate cytoskeletal composition and growth cone dynamics during neuronal development. We have previously shown that beta-actin mRNA is localized in granules that were distributed throughout processes and growth cones of cultured neurons. In this study, we demonstrate that the localization of beta-actin mRNA and protein to growth cones of forebrain neurons is stimulated by neurotrophin-3 (NT-3). A similar response was observed when neurons were exposed to forskolin or db-cAMP, suggesting an involvement of a cAMP signaling pathway. NT-3 treatment resulted in a rapid and transient stimulation of PKA activity that preceded the localization of beta-actin mRNA. Localization of beta-actin mRNA was blocked by prior treatment of cells with Rp-cAMP, an inhibitor of cAMP-dependent protein kinase A. Depolymerization of microtubules, but not microfilaments, inhibited the NT-3-induced localization of beta-actin mRNA. These results suggest that NT-3 activates a cAMP-dependent signaling mechanism to promote the microtubule-dependent localization of beta-actin mRNA within growth cones.     

GDAF对原代培养脊髓神经元的影响

The effect of GDNF on long-term cultured spinal cord neurons was studied. GDNF could promote spinal cord neurons survival after 7 d or 14 d culture by MTT assay. The effect of GDNF on growth cones, neuron soma magnitude, neurite length and spines formulation of spinal cord neurons in cell culture was observed by phase microscopy, Nissl stain and NSE immunocytochemistry stain. The results indicated that GDNF had significant trophic effects on long-term cultured spinal cord neurons.     

GDNF对原代培养脊髓神经元的影响

本文研究了GDNF对体外培养各个时期的脊髓神经元的作用。通过MTT法检测GDNF对脊髓神经元存活率的影响,发现GDNF能促进培养7天及14天的神经元存活。 通过活体观察、尼氏染色、NSE免疫细胞化学染色观察GDNF对脊髓神经元生长锥数目、胞体大小、突起长度及分枝、侧棘形成的影响,发现GDNF对体外培养1—3周的脊髓神经元有明显的营养作用。     

Neuronal expression of the ERM-like protein MIR in rat brain and its localization to human chromosome 6

The ERM proteins, ezrin, radixin, and moesin, regulate cell motility by linking cortical F-actin to the plasma membrane in different cell types. Myosin regulatory light chain interacting protein (MIR) is a recently cloned ERM-like protein which was shown to be involved in neurite outgrowth. Here we have studied the occurrence and expression of MIR in rats during brain development. As shown using Western blotting, MIR is present in different regions both in developing and adult brain. Immunohistochemistry and double labelling studies showed that MIR is localized especially to neurons in hippocampus and cerebellum. A search using the gene bank showed that the MIR gene localised to human chromosome 6 in the interval 6p22.3-23, the loss of which is characterized by mental retardation and different malformations in man. The presence of MIR in brain neurons during development together with its known effects on neurite outgrowth suggest an important function of the protein in the regulation of nerve cell motility and cytoskeletal interactions.     

Distribution of GAP-43, β-III tubulin and F-actin in developing and regenerating axons and their growth cones in vitro, following neurotrophin treatment

Brain derived neurotrophic factor (BDNF) when added to explant cultures of both embryonic and adult retinal ganglion cell (RGC) axons exerted a marked effect on their growth cone size and complexity and also on the intensity of GAP-43, ß-III tubulin and F-actin immunoreaction product in their axons. GAP-43 was distributed in axons, lamellipodia, and filopodia whereas ß-III tubulin was distributed along the length of developing and adult regenerating axons and also in the C-domain of their growth cones. BDNF-treated developing RGC growth cones were larger and displayed increased numbers of GAP-43 and microtubule-containing branches. Although filopodia and lamellipodia were lost from both developing and adult RGC growth cones following trkB-IgG treatment, the intensity of the immunoreaction product of all these molecules was reduced and trkB-IgGs had no effect on the axonal distribution of ß-III tubulin and GAP-43. BDNF-treated growth cones also displayed increased numbers of F-actin containing filopodia and axonal protrusions. This study demonstrates, for the first time, that trkB-IgG treatment causes the loss of F-actin in the P-domain of growth cone tips in developing and regenerating RGC axons. Although microtubules and F-actin domains normally remained distinct in cultured growth cones, ß-III tubulin and F-actin overlapped within the growth cone C-domain, and within axonal protrusions of adult RGC axons, under higher concentrations of BDNF. The collapse of RGC growth cones appeared to correlate with the loss of F-actin. In vitro, trkB signalling may therefore be involved in the maintenance and stabilisation of RGC axons, by influencing F-actin polymerisation, stabilisation and distribution.     

The secretion-stimulated 80K phosphoprotein of parietal cells is ezrin, and has properties of a membrane cytoskeletal linker in the induced apical microvilli.

Stimulation of gastric acid secretion in parietal cells involves the translocation of the proton pump (H,K-ATPase) from cytoplasmic tubulovesicles to the apical membrane to form long, F-actin-containing, microvilli. Following secretion, the pump is endocytosed back into tubulovesicles. The parietal cell therefore offers a system for the study of regulated membrane recycling, with temporally separated endocytic and exocytic steps. During cAMP-mediated stimulation, an 80 kDa peripheral membrane protein becomes phosphorylated on serine residues. This protein is a major component, together with actin and the pump, of the isolated apical membrane from stimulated cells, but not the resting tubulovesicular membrane. Here we show that the gastric 80 kDa phosphoprotein is closely related or identical to ezrin, a protein whose phosphorylation on serine and tyrosine residues was recently implicated in the induction by growth factors of cell surface structures on cultured cells [Bretscher, A. (1989) J. Cell Biol., 108, 921-930]. Light and electron microscopy reveal that ezrin is associated with the actin filaments of the microvilli of stimulated cells, but not with the filaments in the terminal web. In addition, a significant amount of ezrin is present in the basolateral membrane infoldings of both resting and stimulated cells. Extraction studies show that ezrin is a cytoskeletal protein in unstimulated and stimulated cells, and its association with the cytoskeleton is more stable in stimulated cells. These studies indicate that ezrin is a membrane cytoskeletal linker that may play a key role in the control of the assembly of secretory apical microvilli in parietal cells and ultimately in the regulation of acid secretion. Taken together with the earlier studies, we suggest that ezrin might be a general substrate for kinases involved in the regulation of actin-containing cell surface structures.     

Actions of cytochalasins on the organization of actin filaments and microtubules in a neuronal growth cone

Actions of cytochalasin B (CB) on cytoskeletons and motility of growth cones from cultured Aplysia neurons were studied using a rapid flow perfusion chamber and digital video light microscopy. Living growth cones were observed using differential interference contrast optics and were also fixed at various time points to assay actin filament (F-actin) and microtubule distributions. Treatment with CB reversibly blocked motility and eliminated most of the phalloidin-stainable F-actin from the leading lamella. The loss of F-actin was nearly complete within 2-3 min of CB application and was largely reversed within 5-6 min of CB removal. The loss and recovery of F-actin were found to occur with a very distinctive spatial organization. Within 20-30 s of CB application, F-actin networks receded from the entire peripheral margin of the lamella forming a band devoid of F-actin. This band widened as F-actin receded at rates of 3-6 microns/min. Upon removal of CB, F-actin began to reappear within 20-30 s. The initial reappearance of F-actin took two forms: a coarse isotropic matrix of F-actin bundles throughout the lamella, and a denser matrix along the peripheral margin. The denser peripheral matrix then expanded in width, extending centrally to replace the coarse matrix at rates again between 3-6 microns/min. These results suggest that actin normally polymerizes at the leading edge and then flows rearward at a rate between 3-6 microns/min. CB treatment was also observed to alter the distribution of microtubules, assayed by antitubulin antibody staining. Normally, microtubules are restricted to the neurite shaft and a central growth cone domain. Within approximately 5 min after CB application, however, microtubules began extending into the lamellar region, often reaching the peripheral margin. Upon removal of CB, the microtubules were restored to their former central localization. The timing of these microtubule redistributions is consistent with their being secondary to effects of CB on lamellar F-actin.