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AnkyrinG is required for maintenance of the axon initial segment and neuronal polarity
Correspondence to Matthew N. Rasband: Rasband{at}bcm.edu
The axon initial segment (AIS) functions as both a physiological and physical bridge between somatodendritic and axonal domains. Given its unique molecular composition, location, and physiology, the AIS is thought to maintain neuronal polarity. To identify the molecular basis of this AIS property, we used adenovirus-mediated RNA interference to silence AIS protein expression in polarized neurons. Some AIS proteins are remarkably stable with half-lives of at least 2 wk. However, silencing the expression of the cytoskeletal scaffold ankyrinG (ankG) dismantles the AIS and causes axons to acquire the molecular characteristics of dendrites. Both cytoplasmic- and membrane-associated proteins, which are normally restricted to somatodendritic domains, redistribute into the former axon. Furthermore, spines and postsynaptic densities of excitatory synapses assemble on former axons. Our results demonstrate that the loss of ankG causes axons to acquire the molecular characteristics of dendrites; thus, ankG is required for the maintenance of neuronal polarity and molecular organization of the AIS.
Y. Ogawa's present address is Dept. of Pharmacology, Meiji Pharmaceutical University, Tokyo 204-8588, Japan.
Abbreviations used in this paper: AIS, axon initial segment; ankG, ankyrinG; CAM, cell adhesion molecule; DIV, day in vitro; DPI, day post infection; DPT, day post treatment; NF, neurofascin; NrCAM, neuronal CAM; shRNA, short hairpin RNA.
© 2008 Hedstrom et al. This article is distributed under the terms of an Attribution–Noncommercial–Share Alike–No Mirror Sites license for the first six months after the publication date (see http://www.jcb.org/misc/terms.shtml). After six months it is available under a Creative Commons License (Attribution–Noncommercial–Share Alike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).
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Introduction |
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Among the known AIS proteins, ankyrinG (ankG) is essential for AIS assembly (Jenkins and Bennett, 2001) and may be important for its long-term maintenance. Alternatively, neurofascin (NF)-186, an AIS CAM that binds ankG, could function independently of ankG to retain voltage-gated Na+ (Nav) channels at the AIS because it interacts with both the unique AIS extracellular matrix (Hedstrom et al., 2007) and Na+ channel β subunits (Ratcliffe et al., 2001). To test the hypothesis that the AIS contributes to the maintenance of neuronal polarity and to determine whether NF-186, ankG, or other AIS proteins mediate this function, we silenced AIS protein expression in fully polarized 10-d in vitro (DIV) neurons (Yang et al., 2007) using adenoviruses to transduce neurons with NF-186, Nav channel, βIV spectrin, or ankG short hairpin RNA (shRNA) expression constructs.
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Results and discussion |
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50% decrease in the targeted protein after 14 DPI (Fig. S1, D–G).
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After silencing ankG expression in some anti-GFP immunolabeled cells where the identity of the axon was clearly determined based on morphology of the distal processes (i.e., longest and thinnest process; Fig. 4 A, arrows), we also observed dendritic spines in the proximal region of the former axon (Fig. 4 B, inset). The presence or absence of spines correlated well with MAP2 immunoreactivity along the former axon: regions with high levels of MAP2 had spines, whereas distal segments with low levels of MAP2 did not (Fig. 4 C). To further confirm that loss of ankG from the AIS resulted in the development of excitatory synapses, we used antibodies against the postsynaptic scaffolding protein PSD-95. In neurons infected with adenovirus to deliver NF-186 shRNA, the AIS remained intact (Fig. 1, A–C; and Fig. 5 A), and PSD-95 immunoreactivity could only be detected on dendrites; the axon and AIS never had punctate PSD-95 immunoreactivity (Fig. 5, B and C, arrows). In contrast, the silencing of ankG and dismantling of the AIS (Fig. 5 D) resulted in all GFP+ neuronal processes having PSD-95+ postsynaptic densities (Fig. 5, E and F). Thus, loss of ankG permits the formation of spines and excitatory postsynaptic densities on the proximal region of the former axon.
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-PKC, can promote the differentiation of neurites that normally would become dendrites into axons (Inagaki et al., 2001; Zhang et al., 2007), our results demonstrate the first manipulation that causes an axon to acquire the molecular and structural properties of a dendrite (Jiang et al., 2005). Thus, besides the clustering of ion channels (Garrido et al., 2003; Pan et al., 2006; Dzhashiashvili et al., 2007), ankG is required for maintenance of the AIS and axon identity. The AIS has previously unappreciated degrees of plasticity in the kinds of ion channels expressed, their densities, and their position in the axon (Grieco et al., 2005; Kuba et al., 2006; Ogiwara et al., 2007). Because most AIS proteins are long lived, we speculate that modulation of the action potential threshold might be regulated at the level of ankG transcription or through increasing/decreasing ankG turnover rates rather than the expression of ion channels.
Previous studies showed that the lateral mobility of lipids and axonal CAMs in the AIS plasma membrane was limited (Winckler et al., 1999; Nakada et al., 2003), suggesting a diffusion barrier at the AIS. The treatment of cultured neurons with actin-destabilizing agents disrupts the diffusion barrier (Winckler et al., 1999; Kole et al., 2008), although the mechanisms underlying this phenomenon are not known. Our results indicate that this barrier role extends to somatodendritic membrane and cytoplasmic proteins and suggest that it is ankG based. Thus, the ankG-based AIS functions as a spatial barrier to maintain neuronal polarity by restricting the types of proteins that can enter the axon.
Axon injury has been associated with changes in neuronal polarity, conversion of dendrites to axons, and the development of supernumerary axons (Havton and Kellerth, 1987). One recent study showed that transection of the axon at sites distal to the soma did not affect polarity, but transection of the axon close to the cell body (35 µm from the soma and about the same location as the AIS) caused a fate switch and conversion of a dendrite into an axon (Gomis-Ruth et al., 2008). Although this was attributed to altered microtubule stability in the distal axon, an alternative explanation consistent with the results presented here is that the AIS maintains neuronal polarity. We propose that diseases or injuries that disrupt ankG at the AIS may contribute to nervous system dysfunction through loss of neuronal polarity, loss of clustered ion channels, and inappropriate synaptic innervation of proximal segments of axons.
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Materials and methods |
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Adenovirus
Sense sequences for ankG, PAN NF, Nav1.x, and βIV spectrin shRNA were as follows: ankG, 5'-GCCGTCAGTACCATCTTCT-3'; PAN NF, 5'-TGCCTTCGTCAGCGTATTA-3'; Nav1.x, 5'-GTTCGACCCTGACGCCACT-3'; and βIV spectrin, 5'-CACTGGATAGCCGAGAAGG-3'. Efficacy and specificity of these shRNA sequences were demonstrated previously (Hedstrom et al., 2007). For adenovirus, the H1 promoter driving shRNA expression and the shRNA sequence were inserted into pENTR 11 (Invitrogen) via the EcoRI and HindIII sites. A CAG promoter driving the expression of EGFP was also inserted using the HindIII and XhoI sites. Plasmids were recombined with pAd vector (Invitrogen) using the ViraPower Adenoviral Gateway Expression kit (Invitrogen).
Hippocampal neuron culture, infections, and immunostaining
Primary hippocampal neurons were prepared and immunostained as described previously (Ogawa et al., 2006). Neurons were infected using the adenovirus at 10 DIV. The virus was introduced for 3 h before the culture media was exchanged. For live labeling, neurons were treated for 30 min with A12/18.1 antibodies at 4°C. Cells were washed to remove unbound antibody, growth media were replaced in each culture well, and neurons were returned back to 37°C. Neurons were fixed and immunolabeled at the indicated time points.
Image acquisition and analysis
Fluorescence images were collected using an inverted microscope (Axiovert 200M; Carl Zeiss, Inc.) fitted with an apotome for optical sectioning. Images were collected using 20x, 40x, and 63x NA 1.4 Plan-Apochromat objectives, a camera (Axiocam; Carl Zeiss, Inc.), and Axiovision software (Carl Zeiss, Inc.). Montage images were assembled using Photoshop (Adobe Systems, Inc.). All experiments were performed in triplicate with independent dissections. Infected GFP+ cells with detectable AIS immunoreactivity were counted as AIS positive (AIS+). Infected GFP+ cells without detectable AIS immunoreactivity were counted as negatives. AIS fluorescence intensity measurements were made using ImageJ (National Institutes of Health). 10 images per experimental condition were analyzed in three separate experiments. The mean pixel intensity per unit area was measured for each AIS. We calculated the ratio of the mean infected neuron's AIS fluorescence to the mean fluorescence of noninfected neurons on the same coverslip. All camera exposure times were below saturation for noninfected neurons on the same coverslip. For antibody-labeled live neurons, measurements shown are the mean of the raw AIS fluorescence intensity over three experiments. All images were acquired using a subsaturating exposure time determined in 1 DPT neurons.
Online supplemental material
Fig. S1 shows that control GFP adenovirus–infected neurons have a normal AIS even at 10 DPI and that Na+ channels and βIV spectrin are very stable after adenoviral-delivered shRNA knockdown. Fig. S2 shows a GFP-labeled axon that has high levels of MAP2 immunoreactivity after the silencing of ankG expression. Fig. S3 shows another example of distal PAN NF immunoreactivity and the invasion of MAP2 into the axon. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200806112/DC1.
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Acknowledgments |
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This work was funded by National Institutes of Health grant NS044916, the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation, and Mission Connect. Y. Ogawa was supported by a National Multiple Sclerosis Society postdoctoral fellowship. M.N. Rasband is a Harry Weaver Neuroscience Scholar of the National Multiple Sclerosis Society.
Submitted: 18 June 2008
Accepted: 6 October 2008
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