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Volume 16, Number 18, Issue of September 15, 1996 pp. 5583-5592
Copyright ©1996 Society for NeuroscienceTau Binds to the Distal Axon Early in Development of Polarity in a Microtubule- and Microfilament-Dependent Manner
Martina Kempf1, Albrecht Clement1, Andreas Faissner1, Gloria Lee2, and Roland Brandt1 1 Institute of Neurobiology, University of Heidelberg, 69120 Heidelberg, Germany, and 2 Center for Neurological Diseases, Harvard Medical School, Brigham and Women's Hospital, Boston, Massachusetts 02115
ABSTRACT
Microtubule-associated protein tau is localized to the axon in situ and has been implicated in the development of neuronal polarity. Here we report that tau is extracted differentially in cultured hippocampal neurons yielding an axon-specific localization under conditions that keep the integrity of the plasma membrane. The amount of bound tau increases toward the distal axon and is highest at the transition from the axonal shaft to the growth cone. This distribution is significantly different from the distribution of axonal microtubules that are most concentrated at the proximal axon. Distal binding of tau to one process appears early in development of polarity in culture and correlates with the onset of axon formation (day 2 in culture). Binding to the distal axon requires intact microtubules and microfilaments. Distal tau binding does not stabilize microtubules selectively against drug-induced disassembly, because colchicine-induced microtubule depolymerization is highest distally. We conclude that binding of tau to the distal axon follows a complex mechanism, is an early event in the development of polarity, and reproduces the axon-specific localization of tau in situ.
Key words: tau; microtubule-associated protein; hippocampal neuron; polarity; axon; plasma membrane
INTRODUCTION
A characteristic morphological feature of neurons is their polarized structure with an axonal and a somatodendritic compartment. Microtubule-associated proteins (MAPs) are thought to be involved critically in the development of this polarity. In situ, they are characteristically distributed with tau being confined to the axon and MAP2 localized to the soma and dendrites (Bernhardt and Matus, 1984; DeCamilli et al., 1984
The understanding of the properties of developing neurons mostly derives from studies of cells in vitro, in which the cellular environment can be controlled most easily and in which cells are most accessible for microscopic analysis. Of the several neuronal culture systems that have been developed, hippocampal neurons have been characterized most extensively (for review, see Banker and Waxman, 1988
In cultured neurons and neural cell lines, neurite outgrowth correlates with the induction of tau (Drubin et al., 1985
To understand the role of tau during development, we have analyzed its cellular interactions during axon formation in cultured hippocampal neurons. Our previous work has indicated that differential detergent extraction allows the immunocytochemical analysis of various tau interactions. Here we analyzed the distribution of bound tau, MAP2, and microtubules in neurons at different stages of development in culture by confocal image analysis. Drug treatments were used to characterize the involvement of different cytoskeletal elements. The results are in agreement with a model in which microtubule-bound tau interacts with a plasma membrane component that is localized specifically at the distal axon and that requires actin filaments for its subcellular localization.
MATERIALS AND METHODS
Materials. Chemicals were purchased from Sigma (St. Louis, MO), and products for cell culture were obtained from Life Technologies (Gaithersburg, MD), unless otherwise stated.Cell culture. Rat hippocampal neurons were prepared and grown in low-density culture according to standard procedures (Goslin and Banker, 1991
supplemented with 0.6% (w/v) glucose and 7 m HEPES, pH 7.4, treated with 0.25% trypsin for 15 min at 37°C, washed three times with HBSS
Drug treatments were done as follows. To disrupt actin filaments, 0.1-0.6 µ cytochalasin B was added to hippocampal cultures 2 d after plating, and the incubation was continued for an additional 20 hr. To disrupt microtubules, 0.1-1.0 µ colchicine was added 3 d after plating, and cultures were incubated for an additional 3 hr. In all experiments, drugs were added from a 1000× stock in ethanol, and controls were performed with the same added volume of carrier only (ethanol).
Immunofluorescence microscopy. For fixation without detergent extraction, cells were incubated with 4% (w/v) paraformaldehyde in PBS (10 m phosphate buffer, pH 7.4, 2.7 m KCl, and 137 m NaCl) containing 4% (w/v) sucrose for 20 min at room temperature (RT). After washing with PBS, cells were incubated with 0.1 glycine for 20 min and permeabilized for 5 min in 0.2% (v/v) Triton X-100 in PBS.
For saponin extractions of neurons, cells were washed with extraction buffer [80 m PIPES/KOH, pH 6.8, 1 m MgCl2, 1 m EGTA, 30% (v/v) glycerol, and 1 m GTP], extracted for 30 sec with extraction buffer containing 0.02% (w/v) saponin, and then washed again with extraction buffer, with all steps on a heating platform set at 37°C. Fixation was performed for 1 hr at RT with 2% (w/v) paraformaldehyde and 0.1% (v/v) glutaraldehyde in extraction buffer. Cells were permeabilized with 0.1% (v/v) Triton X-100 in PBS for 30 min, incubated for 7 min with 10 mg/ml NaBH4 in PBS and for 20 min with 0.1 glycine in PBS, and subsequently blocked for 1 hr with PBS containing 1% (w/v) BSA. Increasing the saponin concentration to 0.2% (w/v) resulted in a decrease of staining but left the overall pattern of tau immunoreactivity unchanged. Similar staining patterns also were observed by using a previously described combined NP-40 permeabilization-fixation procedure (Lee and Rook, 1992
Staining was essentially as described earlier (Lee and Rook, 1992
-tubulin (DM1A), and anti-acetylated tubulin antibody (6-11B-1), rhodamine-coupled donkey anti-mouse, FITC-coupled donkey anti-rabbit, and Texas Red-coupled goat anti-mouse antibody (all secondary antibodies from Jackson ImmunoResearch, West Grove, PA). Staining with primary antibodies was for 1 hr at RT and with secondary antibodies for 30 min. For staining of actin filaments, rhodamine-coupled phalloidin was included in the secondary antibody incubation. Coverslips were mounted in 1 mg/ml p-phenylenediamine in 90% (v/v) glycerol and 10% (v/v) PBS. Cells were photographed with Neofluar lenses on a Zeiss Axioskop.
Confocal image analysis. Confocal image analysis used a Leica TCS 4D True confocal scanner equipped with an argon/krypton laser. Cells were imaged with a 40×/1.00 PL FLUOTAR or a 63×/1.4 PL APO oil-immersion objective and were recorded at 512 × 512 pixels per image. Scanning was in the standard mode (450 lines/sec). Laser scan images were optimized to achieve a linear increase in pixel intensity with increasing fluorescence. Noise suppression was achieved via accumulation in the line-averaging mode (8 counts/average). Tau and tubulin distributions from the same neurons were recorded by two-channel simultaneous scannings from double-stained cells. From each cell ~10 optical sections with a thickness of ~200 nm were recorded. Summation of pixel intensities in the direction of projection was achieved by using the ``extended focus'' option in the three-dimensional image-processing mode. To evaluate the distribution of tau and tubulin in cellular processes, consecutive 5-µm-long (2-6 d cultures) or 10-µm-long (8 d cultures) segments with a diameter slightly larger than the process were defined as random windows in the data analysis mode. To correct for background fluorescence, an average background pixel intensity was calculated for each process from three random windows close to the process and then substracted from the pixels within the segments. The total fluorescence intensity for the segments was calculated by summing the corrected intensities of the pixels comprising each segment. Process diameters were measured from the projected fluorescence images at the beginning and end of each segment, and the mean was determined. Because of the heterogeneity of axonal growth cones with respect to their size, they were not included in the quantification. To compare processes with different lengths, we calculated fluorescence intensities relative to the total process length (excluding the growth cone) in 10% steps and normalized to a maximum total fluorescence intensity of 1.0 of the respective label. For each experimental condition, three representative processes were evaluated as described above, and mean and SE were calculated.
To analyze the fluorescence distribution, we performed linear regression analysis. Normalized fluorescence distributions were plotted against the segment number (i.e., 1-10 according to the fractionation in 10% steps) and slope, and 95% confidence intervals were calculated.
RESULTS
Distribution of total tau and bound tau in cultured hippocampal neurons
To determine the distribution of tau in polarized neurons, low-density cultures of rat hippocampal neurons were analyzed. After 3 d in culture, hippocampal neurons contain a fast-growing axon in addition to shorter neurites, which later develop into dendrites (stage 3 neurons; Dotti et al., 1988To analyze the binding of tau in the neurons, a mild extraction protocol with saponin was used. This protocol selectively removes unbound cytosolic proteins but retains cytoskeletal membrane associations (Nakata and Hirokawa, 1987
Fig. 1. Tau distribution in saponin-extracted cultured hippocampal neurons. A, Double staining for tau (left) and MAP2 (right) of saponin-extracted neurons. Whereas MAP2 is present in all neurites, including the growth cones and the cellular soma, anti-tau staining is concentrated in the distal portion of the axonal shaft (arrowheads). B, Double staining for tau (left) and actin filaments (right) in saponin-extracted neurons. Note that anti-tau staining is restricted to the distal axonal shaft and the proximal growth cone (arrowheads), whereas actin filaments are prominent in the distal growth cones, including filopodia. For all experiments, cells were grown for 3 d in serum-free medium. Cells were extracted and fixed as described under Materials and Methods. Tau-specific staining was obtained by affinity-purified tau polyclonal and MAP2 staining by monoclonal anti-MAP2 antibody (AP20). Double staining in A used FITC-coupled donkey anti-rabbit and Texas Red-coupled goat anti-mouse antibody. Actin filaments were visualized with rhodamine-coupled phalloidin in the secondary antibody reaction. Scale bar, 20 µm.
[View Larger Version of this Image (108K GIF file)]
In contrast to the distribution of tau, MAP2 was present uniformly in the axon, the cell body, and minor neurites after saponin extraction (Fig. 1A, right), which was similar to its distribution in unextracted cells (data not shown). Interestingly, at early stages of development in culture (6 d or fewer) when MAP2 was still present in most of the axons, MAP2 staining extended far into the axonal growth cones, whereas tau was concentrated at the distal axonal shaft and the growth cone neck (arrowheads, Fig. 1A). Tau was absent from the F-actin-rich distal growth cone and from growth cone filopodia (Fig. 1B) and colocalized with microtubules as reported previously (Brandt et al., 1995
To quantify the effect of saponin extraction on subcellular tau distribution, cells with tau-positive neurites after 3 d in culture were evaluated by visual inspection for axon-specific and distally enriched tau localization. In all, 93% (±5%, n = 2) and 90% (±2%, n = 2) of extracted cells exhibited axon-specific and distally enriched tau staining, respectively, with 85% of the cells showing both. In contrast, only 5% (±5%, n = 2) of unextracted cells exhibited axon-specific staining, and in 1% (±0%, n = 2) tau staining was distally enriched.
Binding of tau to the distal axon takes place early in the development of polarity in culture
To determine the time course of the localization of tau, cultured hippocampal neurons were analyzed at different times after plating. Cultured hippocampal neurons develop by a stereotyped sequence of events, characterized by the formation of lamellipodia (stage 1), the formation of minor neurites (stage 2), and axonal outgrowth (stage 3) as early events within the first days in culture (Dotti et al., 1988
Fig. 2. MAP2 and tau binding in hippocampal neurons during development in culture. A, Distribution of tau (left) and MAP2 (right) in unextracted hippocampal neurons after 2 d in culture. B, Double staining for tau (left) and MAP2 (right) of saponin-extracted cells after 2 d in culture. Note the intense MAP2 staining at the periphery of the cell in actin-rich regions (compare with Fig. 1A). In contrast, tau staining is enriched in the distal axonal shaft (arrowhead). C, Quantification of tau expression during development in culture. At times indicated, cells were fixed and stained. One hundred cells were scored for each experiment, and the proportion of cells with tau-positive neurites was determined. Mean and range from two independent experiments are shown. D, Quantification of cells with axon-specific and distally enriched tau staining during development in culture. At times indicated, cells were extracted, fixed, and stained. Cells with tau-positive neurites were evaluated. For 2 and 3 d cultures, between 61 and 100 cells were scored. For 6 and 8 d cultures, between 8 and 40 cells were scored; only a small portion of processes could be followed unequivocally because of the formation of an extensive neuritic meshwork. Mean and range from two independent experiments are shown. For all experiments, cells were grown for the time indicated in serum-free medium. Cells were fixed and permeabilized or extracted and fixed as described under Materials and Methods. Tau-specific staining was obtained by monoclonal antibody Tau-1 (C) or affinity-purified tau polyclonal (A, B, D). MAP2 staining was obtained with monoclonal anti-MAP2 antibody (AP20). Double stainings used FITC-coupled donkey anti-rabbit and rhodamine-coupled donkey anti-mouse antibody. Quantifications were performed by visual inspection of cells stained for tau and MAP2. The longest process was considered as being an ``axon.''
[View Larger Version of this Image (76K GIF file)]
In saponin-extracted neurons, tau was enriched in the distal region of one of the neurites as soon as tau was detectable [Fig. 2B (left), D], indicating that binding of tau to the distal axon is an early event in the development of polarity. In the vast majority of tau-positive cells, tau was restricted to one process and distally enriched starting from day 2 in culture; the distribution of tau was very similar during development in culture (Fig. 2D). In contrast to the localization of tau to the axon early in development, the exclusion of MAP2 from the axon took place much later, with approximately one-third of the cells still having a MAP2-positive axon after 8 d in culture (Fig. 2D). Interestingly, during early development (at days 1 and 2 in culture), MAP2 showed an intense binding at the cellular periphery at lamellipodial and filopodial regions (Fig. 2B, right), where it colocalized with actin filaments (data not shown). Between days 2 and 3 a switch to a microtubular staining pattern took place (compare Fig. 2B, right, with 1A, right).
The results indicate that binding of tau to one neurite at its distal end takes place early in the development of polarity in culture when axons start to emerge (day 2). Tau and MAP2 binding are not correlated temporally and spatially because the spatial specificity of MAP2, i.e., its exclusion from the axon, takes place much later in development.
Binding of tau in the axon shows a proximal-to-distal increase
To quantify the distribution of bound tau, microtubules, and MAP2 in axons, confocal image analysis was used. Saponin-extracted neurons were prepared for immunofluorescence microscopy, and the distribution of label was quantified in consecutive segments along the neurites. Figure 3A shows the distribution of tau and tubulin as the mean of three representative axons. The amount of bound tau in the distal axon was higher than in the proximal region, whereas the amount of tubulin showed an opposite distribution. Regression analysis confirmed that tau and tubulin distributions were significantly different, distributed with a slope of 0.068 (± 0.026) and0.051(± 0.022), respectively (95% confidence intervals are given). The axonal diameter remained almost constant, suggesting that the gradient in bound tau is not caused by the distribution of microtubules or an increase of axonal volume. Although tau is enriched in the distal third of the axonal shaft ~3:1 relative to the proximal third, no specific enrichment as indicated by a high tau/tubulin ratio was found in the growth cone (Fig. 3B). It should, however, be noted that the growth cone sizes as reflected by the area they covered were very heterogeneous in the individual neurons. Because this heterogeneity complicated a systematic quantitative analysis of the growth cone regions, we decided to restrict our analysis to the axonal shafts. In contrast to tau, the amount of bound MAP2 decreased from the proximal-to-distal axon (Fig. 3C). The decrease (
Fig. 3. Distribution of bound tau, MAP2, and tubulin in processes of cultured hippocampal neurons. Distribution of tau and tubulin in axons (A, B), MAP2 in axons and minor neurites (C), and tau and acetylated tubulin in axons (D) of cultured hippocampal neurons. Note that tau is enriched in the distal axon, which is not paralleled by a similar distribution of MAP2, tubulin, acetylated tubulin, or an increase in process diameter. For all experiments, cells were grown for 3 d in serum-free medium. Cells were extracted and fixed as described in Materials and Methods. Tau-specific staining was obtained by affinity-purified tau polyclonal, MAP2 staining by monoclonal anti-MAP2 (AP20), tubulin staining by monoclonal anti-
[View Larger Version of this Image (63K GIF file)]
To analyze the binding of tau during differentiation, the distribution of bound tau was quantified from cells at different times after plating (Fig. 4). The mean lengths of the axons increased approximately threefold from 2 to 8 d in culture. At all time points tau was enriched in the distal axon. Regression analysis revealed an ~40% increase in the slope from 2 to 6 d of development. This increase, however, was not significant.
Fig. 4. Time course of tau distribution in axons of cultured hippocampal neurons. Note the enrichment of tau in the distal axon at all times in culture. Cells were grown for the times indicated in serum-free medium. Cells were extracted and fixed as described in Materials and Methods. Tau-specific staining was obtained by affinity-purified tau polyclonal antibody and Texas Red-coupled goat anti-mouse secondary antibody. Mean and SE of the relative fluorescence intensity of three different processes are shown. Mean and SD of process lengths are indicated.
[View Larger Version of this Image (57K GIF file)]
The results suggest that the mechanisms by which tau and MAP2 are bound in their respective compartment are different. Whereas MAP2 binding parallels the distribution of microtubules once polarity has been established, tau binding shows a proximal-to-distal increase that is not reflected by a similar distribution of microtubules, acetylated microtubules, or MAP2.
Distal tau binding depends on intact microtubules and microfilaments
To test for the role of microtubules in the binding of tau to the distal axon, neurons were cultivated for 3 d, followed by an incubation with the microtubule-disrupting drug colchicine (Wilson and Bryan, 1974
Fig. 5. Effect of colchicine on tau binding in hippocampal neurons. A, Distribution of microtubules in hippocampal neurons, which have been treated with carrier (0.1% ethanol) only. Note that the microtubules seem to be distributed uniformly in the axonal shaft and that they extend far into the axonal growth cone. B, Distribution of microtubules in colchicine-treated (0.5 µ, 3 hr) hippocampal neurons. Note the decrease of the microtubule concentration toward the distal axon and the complete loss of growth cone microtubules. C-E, Distribution of tau in control cells (C) and cells treated with 0.5 (D) and 1 µ (E) colchicine. Note the redistribution of tau after colchicine treatment, resulting in a loss of the proximal-to-distal tau gradient. After 3 d in culture, colchicine at the indicated concentrations or, as a control, carrier only (0.1% final ethanol concentration) was added to the cultures. Cells were incubated for an additional 3 hr and then extracted and fixed as described in Materials and Methods. Tau-specific staining was obtained by monoclonal anti-tau antibody (Tau-1), and microtubules were stained with monoclonal anti-
[View Larger Version of this Image (109K GIF file)]
To analyze a possible involvement of actin filaments in the localization of bound tau, neurons were kept for 2 d in culture to allow binding of tau to the distal axon, followed by incubation with the actin filament-disrupting drug cytochalasin B (Cooper, 1987
Fig. 6. Effect of cytochalasin on tau binding in hippocampal neurons. A, Distribution of actin filaments in control cells (left) and cytochalasin-treated neurons (right). Whereas in control cells actin filaments are prominent at the periphery of the cells and in the tips of the growth cones, actin filaments seem disrupted in cytochalasin-treated cells, and knob-like structures are present in the growth cones (arrowheads). B, Distribution of tau (left) and MAP2 (right) in cytochalasin-treated neurons. Note that tau is distributed evenly within the axon in cytochalasin-treated cells. C, Quantification of tau distribution in cytochalasin-treated and control cells. Mean and range from two independent experiments are shown. Between 25 and 58 tau-positive cells were scored for each experiment. After 2 d in culture, 0.6 µ cytochalasin or, as a control, carrier only (0.1% ethanol) was added to the cultures; the cells were incubated for an additional 20 hr and then extracted and fixed as described in Materials and Methods. Tau-specific staining was obtained by affinity-purified tau polyclonal, MAP2 staining used monoclonal anti-MAP2 antibody (AP20), and actin filaments were stained with rhodamine-coupled phalloidin.
[View Larger Version of this Image (83K GIF file)]
DISCUSSION
Using a differential extraction protocol designed to retain cytoskeleton plasma membrane interactions, we show in this paper that tau binds to the distal axon early in the development of neuronal polarity and remains concentrated in this region throughout maturation. This distribution contrasts with the localization of total tau, which is present ubiquitously in hippocampal neurons (our data; Dotti et al., 1987Various mechanisms have been proposed for the segregation of tau into axons and MAP2 into dendrites. It has been proposed that their localization is determined by mRNA localization (Garner et al., 1988
The function of tau in the development of neuronal polarity is a matter of debate. From studies in which tau was overexpressed in non-neural or neural cells, it has been concluded that tau confers stability onto microtubules (Knops et al., 1991
As a next step in the understanding of the molecular mechanisms involved in the development of neuronal polarity, it will be important to identify the component(s) with which tau interacts at the distal axon and to analyze their function.
FOOTNOTES
Received March 12, 1996; revised May 28, 1996; accepted June 19, 1996.
This work was supported by an habilitation fellowship and ``Sachbeihilfe'' of the Deutsche Forschungsgemeinschaft (M.K., R.B.), DFG Grant Fa 159/5-2, 3(A.C., A.F.), and National Institutes of Health Grant NS32100 (G.L.). Andreas Faissner is the recipient of a Schilling Professorship for Neuroscience. We thank Drs. Lester I. Binder and Virginia M.-Y. Lee for providing anti-tau antibody (Tau-1 and 46.1, respectively) and Alan Summerfield for excellent photographic service.
Correspondence should be addressed to Dr. Roland Brandt, Institute of Neurobiology, University of Heidelberg, Im Neuenheimer Field 364, 69120 Heidelberg, Germany.
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