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Volume 17, Number 24, Issue of December 15, 1997
Experience-Dependent Modifications in MAP2 Phosphorylation in Rat Olfactory Bulb
Benjamin D. Philpot1, Jae H. Lim1, Shelley Halpain2, and Peter C. Brunjes1 1 University of Virginia, Department of Psychology, Charlottesville, Virginia 22903, and 2 The Scripps Research Institute, Department of Cell Biology, La Jolla, California 92037
ABSTRACT
Microtubule-associated protein 2 (MAP2) is a neuron-specific cytoskeletal protein, enriched in dendrites and cell bodies, that helps determine dendritic shape. MAP2 regulates microtubule stability in a phosphorylation-dependent manner. The present study used immunocytochemistry with phosphoepitope-specific and phosphorylation state-independent antibodies to examine experience-dependent changes in MAP2 expression during postnatal development of the olfactory bulb. Our results demonstrate that immunoreactivity reflecting total MAP2 expression reaches a maximal level by postnatal day 20 (P20). The degree of staining for phosphoindependent forms of MAP2 is relatively unaffected by blocking odorant passage to one half the nasal epithelium via unilateral naris closure, a manipulation that attenuates physiological activity in the bulb. However, olfactory restriction from P1 dramatically reduces immunoreactivity for antibody AP18, which recognizes MAP2 only when phosphorylated on Ser136. Quantification of staining in the granule cell layer indicates that the greatest difference (64%) between control and experimental bulbs occurs after occlusion from P1 to P30 compared with animals deprived from P1 to P10 or P1 to P20. The shift in MAP2 phosphorylation occurs even when deprivation is delayed until P30, after the sensitive period for experience-dependent changes in bulb volume. Thus, the degree of the phosphorylation shift depends on the duration but not the time of onset of naris closure.
Because staining for phosphorylation-independent forms of MAP2 is unchanged by naris closure, the total amount of the protein per unit area is probably not significantly altered. However, the large reductions of AP18-immunoreactivity in the bulb after olfactory restriction suggest that there is an activity-dependent stimulation of MAP2 phosphorylation.
Key words: activity-dependent; AP18; calcineurin; dendrite; HM-2; microtubule; naris closure; sensory deprivation; synaptic plasticity
INTRODUCTION
Cellular morphology is determined by the structural stability of cytoskeletal proteins. One such neuronal component, microtubule-associated protein 2 (MAP2), is enriched in dendrites and cell bodies (Bernhardt and Matus, 1984
; Tucker et al., 1988
Microtubules exhibit the property of dynamic instability both in vitro and in vivo. This process is regulated by MAP2 and other MAPs in a phosphorylation state-dependent manner. MAP2 has multiple phosphorylation sites for a variety of serine- and threonine-directed protein kinases and phosphatases (Sloboda et al., 1975
Activity-dependent processes of dendritic organization may be regulated, in part, by MAP2 phosphorylation. For example, exposure to light after dark-rearing dephosphorylates MAP2 within kitten visual cortex (Aoki and Siekevitz, 1985
The olfactory bulb is a unique region for studying activity-dependent regulation of MAP2 phosphorylation. MAP2 expression increases substantially in the postnatal bulb (Crandall and Fischer, 1989
MATERIALS AND METHODS
Subjects. Offspring of Long-Evans-hooded rats purchased from the Charles River Laboratories (Wilmington, MA) was used. Rats were housed in polypropylene cages (40 × 25 × 16 cm) and given food and water ad libitum. The colony room was maintained on a 16/8 hr light/dark cycle. Litters were culled to 10 on postnatal day 1 (P1), the day after the day of birth. P1 subjects were anesthetized with hypothermia and underwent either unilateral occlusion of the right external naris via cautery or a sham manipulation consisting of cautery on the dorsal nose surface (Meisami, 1976
Immunoblot preparation. Frozen olfactory bulbs from P30 rats were rapidly solubilized in boiling hot 1% SDS by sonification; 45 µg aliquots were loaded onto 8% polyacrylamide gels, electrophoretically separated, and transferred to nitrocellulose. Membranes were incubated at room temperature for 60 min in Tris-buffered saline, pH 7.3, containing 0.1% Triton X-100 and 4% nonfat dry milk to block nonspecific binding. This buffer was used for all reagent dilutions and rinses between steps. Membranes were incubated for 2 hr with primary antibody using the following dilutions: polyclonal antiserum 266, 1:2000; monoclonal antibody AP18 hybridoma culture medium supernatant, 1:500; and monoclonal antibody HM-2 (Sigma, St. Louis, MO), 1:2000. For the two monoclonal antibodies, membranes were incubated 1 hr with rabbit anti-mouse IgG (Calbiochem, La Jolla, CA) as the secondary antibody. After a 2 hr incubation with 125I-Protein A (0.1 mCi/ml; Amersham, Arlington Heights, IL), membranes were dried and exposed to a PhophorImager screen to detect antibody binding.
Tissue preparation and immunostaining. Subjects were given an overdose of barbiturates and were perfused intracardially with 0.1 M PBS, pH 7.4, followed by Bouin's fixative. Brains were carefully dissected and post-fixed overnight in the Bouin's fixative. Brains were then dehydrated for 24 hr in 70% ethyl alcohol, run through an ascending alcohol series, cleared in toluene, and embedded in paraffin. Twelve-micrometer-thick sections were cut in the coronal plane and mounted onto gelatin-coated slides. Sections were deparaffinized for 5 min in xylenes, rehydrated through a descending alcohol series, rinsed three times with 0.1 M phosphate buffer (PB), and placed for 15 min in 3% H2O2 to quench endogenous peroxidases. After three washes in PB, sections were incubated for 1 hr in 10% normal goat serum (NGS) in PB to prevent nonspecific staining. Sections were then incubated with one of four antibodies: a rabbit anti-MAP2 polyclonal antibody that preferentially recognizes the high molecular weight MAP2 isoforms and has a binding affinity that is unaffected by phosphorylation (1:5000; antibody #266; Halpain and Greengard, 1990
Control experiments, consisting of the same protocol but omitting exposure to the primary antibody, consistently resulted in the absence of staining. The specificity and characterization of the antibodies used in this study have been examined previously (Huber and Matus, 1984 
Fig. 1. Immunoblot analysis of MAP2 isoforms present in adult rat olfactory bulb. Equal aliquots of total bulb homogenate were separated on 8% gels, transferred to nitrocellulose, and probed with the indicated antibodies against MAP2. Lane 1, Antibody HM-2, which recognizes all known isoforms of MAP2 independent of phosphorylation state; lane 2, antibody #266, which recognizes only high molecular weight isoforms of MAP2 independent of phosphorylation state; lane 3, antibody AP18, which recognizes all known isoforms of MAP2 only when phosphorylated on Ser136. Positions of high molecular weight MAP2 and low molecular weight MAP2c are indicated by arrows. The fainter bands running below MAP2 and MAP2c likely represent proteolytic breakdown products. Positions of molecular weight markers (in kilodaltons) are given on the right.
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Several precautions were taken to ensure that histological artifacts were minimized. For example, tissues from several groups were processed in parallel whenever possible. Furthermore, sections from each animal were subjected to several immunostaining techniques to determine which were consistent and maximal. For example, antibody dilutions and exposure durations were optimized for the most robust staining. Tissue samples from each subject were preincubated in various concentrations of Triton X-100 to increase antibody penetration, as well as in lower concentrations of NGS to prevent overblocking to demonstrate that antigenicity was maximal. Examinations of the effects of naris occlusion were facilitated by the fact that left to right comparisons could be made within single sections.
Quantification. Both right and left bulbs (i.e., the experimental bulb ipsilateral to the occluded naris and the contralateral control, respectively) were analyzed for the density of immunoreactivity. Quantification was performed in the granule cell layer because it was the region of lowest variability (e.g., see Fig. 2). Segments 600 µm in length and spanning the entire width of the layer were selected. A microcomputer-based image analysis system (MCID; Imaging Research) was used to calculate the proportion of the stained area to the total test area [area fraction, (AA)]. Images were consistently thresholded for each pair of bulbs such that all areas containing DAB reactions were black and the background was white, and visual inspection verified that all immunostaining was detected. The olfactory nerve layer, a region devoid of dendrites, was used to define background staining. Threshold levels were individually set for each pair of bulbs to ensure all immunoreactivity was identified, and thresholding and light levels were unchanged in pairs of left and right bulbs. The image analysis system was calibrated to ensure that all staining was included in area fraction determinations while background staining was excluded. The difference in the area fraction of staining between bulbs was calculated with the following formula: 100 × (AA right bulb AA left bulb)/AA left bulb. Values from each section were averaged for each animal, and a mean was determined across animals. ANOVA was performed to test whether the dependent variable (difference in area fraction) varied as a function of age group and experimental condition (naris-occluded or sham-operated). The data were analyzed for main effects and for interactions. A post hoc test, Tukey's honestly significant difference, was used to probe for univariate variations. The significance level was defined as p < 0.05. No statistical differences in staining were observed between left and right bulbs of nonoccluded subjects.
Fig. 2. Photomicrograph depicting immunoreactivity for a phosphorylation-independent MAP2 antibody, antibody 266, in a coronal section through the olfactory bulb of a P60 rat. MAP2-IR is absent in the olfactory nerve layer (ONL) and subependymal zone (SUB). MAP2-IR dendrites have extensive ramifications in neuropil of the glomerular layer (GLM). The external plexiform layer (EPL) is dense with MAP2-IR dendrites. Numerous MAP2-IR dendrites extend from the granule cell layer (GCL), through the mitral cell layer (MCL), and into the EPL. Scale bar, 300 µm.
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RESULTS
Figure 1 demonstrates that antibody HM-2 recognizes all known isoforms of MAP2, whereas antibody 266 recognizes only high molecular weight isoforms of MAP2. Both antibodies HM-2 and 266 recognize MAP2 independent of phosphorylation state. Antibody AP18 recognizes all known isoforms of MAP2 only when phosphorylated on Ser136. Because both the phosphorylation-independent and the phosphorylation-specific forms of MAP2 were examined, we have defined "MAP2-immunoreactivity" (IR) to refer to staining observed with the antisera directed against the phosphorylation-independent isoforms and "AP18-IR" to refer to staining observed with antiserum to the phosphorylation-specific AP18 epitope of the MAP2 isoform. Unless otherwise noted, characterization of phosphorylation-independent forms of MAP2 staining was made using antibody 266.
MAP2-IR was striking in the main olfactory bulb (Fig. 2). Staining was absent in the olfactory nerve layer and subependymal zones but present in all other layers. In general, MAP2-IR filled all glomeruli in the olfactory bulb (the site of synaptic contact between incoming olfactory nerve axons and central elements), was dense in the external plexiform layer, and was distributed evenly throughout the granule cell layer. Staining was restricted to dendrites and the perikaryal regions. There was no evidence of axonal or glial staining. Although no developmental changes in patterns of staining were observed, age-related increases in the density of staining did occur.
On P10, MAP2-IR dendrites had extensive arbors within glomerular neuropil (Fig. 3A). The dendritic arbors appeared to arise from mitral and juxtaglomerular cells and from cells in the external plexiform layer. Staining was most intense in the external plexiform layer. Laterally extending dendrites were more prevalent in the deeper half of the external plexiform layer. Although thick mitral cell dendrites were heavily labeled, only minimal staining was present within mitral cell somata. Deep to the mitral cell layer, MAP2-IR dendrites were observed extending from granule cells. The somata of most granule cells were labeled. 
Fig. 3. Photomicrographs depicting immunoreactivity for a phosphorylation-independent MAP2 antibody, antibody #266, in coronal sections of the developing bulb. A, At P10, MAP2-IR dendrites have extensive arborizations in glomeruli, and the external plexiform layer contains numerous MAP2-IR dendrites. Granule cells have distinct MAP2-IR along their somatic periphery, and their dendrites are lightly labeled. B, At P20, MAP2-IR is most intense at this age. The deep half of the external plexiform layer generally has more labeling than does the superficial half. Granule cell dendrites are darkly immunoreactive. C, At P30, MAP2-IR has a distribution similar to that seen in the P20 bulb. D, At P60, the intensity of MAP2-IR has decreased slightly from that observed in the P30 bulb. Arrows mark the mitral cell layer. For abbreviations, see Figure 2. Scale bar, 200 µm.
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There was a marked increase in staining intensity from P10 to P20 (Fig. 3B). The external plexiform layer was divided into two zones, with more dense MAP2-IR in the deeper half than in the superficial half. Granule cell apical dendrites had intense MAP2-IR. From P20 to P60, there was little change in MAP2-IR. Qualitatively there appeared to be a decrease in the intensity of MAP2-IR from P30 to P60 (Fig. 3C,D).
The pattern and amount of MAP2-IR were similar in right and left bulbs from both normal and naris-occluded rats in all age groups (Fig. 4). The percent difference in area fraction did not vary as a function of age [F(3,24) = 2.188; p > 0.05] or experimental treatment [F(1,24) = 2.8; p > 0.05]. 
Fig. 4. Graph depicting the mean percent difference (±SEM) between left and right bulbs in the area fraction of MAP2-IR (phosphorylation-independent antibody 266) within the granule cell layer. In sham-operated animals (SHAM), there is no difference between bulbs in MAP2-IR from P10, P20, P30, or P60 rats. In naris-occluded rats (NOSX), there is also a negligible difference in MAP2-IR between bulbs from animals occluded from P1 to P10, P1 to P20, P1 to P30, or P30 to P60.
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The pattern of AP18-IR was similar to that of MAP2-IR, although AP18 staining was consistently sparser and lighter (compare photomicrographs in Fig. 5). Within individual glomeruli, AP18-IR was present along fewer dendrites compared with MAP2-IR. Laterally extending AP18-IR processes were common along the deep border of glomeruli. The degree of dendritic labeling in the external plexiform layer was quite variable. Generally, AP18-IR dendrites were most intense in the deep half of the external plexiform layer and throughout the granule cell layer (Fig. 6). There was no evidence of laterality of AP18-IR between right and left bulbs of sham-operated rats at any age during development (Fig. 7). 
Fig. 5. Photomicrographs depicting immunoreactivity for a phosphorylation-independent antibody to MAP2 (A), antibody 266, and staining for the phosphoepitope-specific AP18 antiserum (B) in adjacent coronal sections of bulbs from a P30 rat. A, Numerous dendrites in the glomerular layer contain MAP2-IR. Labeling of dendrites is particularly dense along the deep border of the glomerular neuropil. The external plexiform layer has dark immunoreactivity, and stained dendrites course from the external plexiform layer through the mitral cell layer. B, AP18-IR is generally much sparser than is staining for the phosphorylation-independent MAP2 antibody. For example, relatively few dendrites are labeled in glomeruli. Labeling is less dense in the external plexiform and granule cell layers as well. The arrow marks the mitral cell layer. For abbreviations, see Figure 2. Scale bar, 100 µm.
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Fig. 6. Photomicrographs demonstrating AP18-IR in coronal sections from control (left) and experimental (right) bulbs after unilateral naris closure. Left, AP18-IR dendrites are apparent as they project into glomeruli or extend laterally in superficial aspects of the external plexiform layer. AP18-IR is relatively dense in the external plexiform layer, and many dendrites in the granule cell layer are labeled. Right, AP18-IR is less intense in experimental bulbs. Fewer dendrites are labeled in the glomerular layer, and there is substantially less immunoreactivity of granule cell dendrites. The arrow marks the mitral cell layer. For abbreviations, see Figure 2. Scale bar, 100 µm.
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Fig. 7. Graph of the mean percent difference (± SEM) between left and right bulbs in the area fraction of AP18-IR within the granule cell layer. In sham-operated rats (SHAM), there is a negligible difference between right and left bulbs in P10, P20, P30, and P60 rats. However, after naris closure (NOSX), the area fraction of the bulb containing AP18-IR in the granule cell layer is dramatically reduced in experimental bulbs after occlusion from P1 to P20, P1 to P30, or P30 to P60. Asterisks denote significant differences from zero (p < 0.05). Note the y-axis change from Figure 4.
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Although unilateral naris closure had no effect on MAP2-IR in the bulb, AP18-IR was dramatically affected by the manipulation (Fig. 6). Particularly, there was less AP18-IR in the granule cell layer of experimental bulbs compared with contralateral control bulbs. Staining in the granule cell layer was reduced in experimental bulbs in every animal measured, resulting in a significant effect of experimental condition [F(1,23) = 108.8; p < 0.0001; Figure 7]. Furthermore, the reduction varied as a function of age [F(3,23) = 4.1; p < 0.05], and there was a significant interaction between age and experimental condition [F(3,23) = 5.0; p < 0.01]. Post hoc analysis indicated a significant reduction in AP18-IR in deprived bulbs from animals occluded from P1 to P20, P1 to P30, and P30 to P60 (p < 0.05). The reduction in AP18-IR was related to the duration of occlusion: for example, rats occluded from P1 to P30 had a greater reduction in AP18 staining than did rats occluded from P1 to P10 (p < 0.05). Unlike many of the effects of naris closure in the olfactory bulb (Brunjes, 1994
In addition to the reductions in AP18-IR in the granule cell layer, there appeared to be fewer AP18-IR processes in the glomerular layer of experimental bulbs after naris closure, whereas AP18-IR in the external plexiform layer appeared unchanged by the manipulation (Fig. 6).
Because reductions in AP18-IR were observed with late- as well as early-onset occlusion, an additional set of experimental animals was examined to determine whether short periods of occlusion in older rats could alter the expression of AP18-IR. In rats occluded from P30 to P37, only small changes were observed; the mean percent difference in area fraction was
Although studies using antibody 266 demonstrated that the area fraction of staining for the high molecular weight forms of MAP2 was not altered after naris closure, the decrease in AP18-IR might be caused by a specific loss of the low molecular weight forms of MAP2 not detected by antibody 266. An antibody that recognizes all known forms of MAP2 and is phosphoindependent, the HM-2 antibody, was used to examine the possibility that reductions in AP18-IR were caused by a loss of low molecular weight forms of MAP2. HM-2 staining (Fig. 8) resembled staining using antibody 266. Moreover, the area fraction of staining using the HM-2 antibody was not altered in experimental bulbs in animals occluded from P1 to P30. The mean percent difference (±SEM) in area fraction of HM-2 staining between bulbs was 3 ± 5%. 
Fig. 8. Photomicrograph depicting HM-2 staining in a coronal section from a P30 bulb. The HM-2 antibody is phosphorylation-independent and recognizes all known forms of MAP2. Note the absence of staining in the nerve layer and the particularly dense immunoreactivity in the deeper portion of the external plexiform layer. Staining patterns are similar to those found using antibody 266. For abbreviations, see Figure 2. Scale bar, 150 µm.
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Because of the changes in AP18-IR that were observed after naris closure, the presence of calcineurin, an activity-dependent protein phosphatase that can dephosphorylate MAP2, was examined in the bulb. At all ages, calcineurin-IR was present in somatic profiles in the granule cell layer (Fig. 9), precisely the layer in which we observed reductions in AP18-IR. Faint labeling of granule cell dendrites was also observed. No quantitative changes in calcineurin-IR were observed in experimental bulbs after naris closure. 
Fig. 9. Photomicrograph depicting calcineurin-IR in a coronal section through the granule cell layer of a P20 bulb. Calcineurin-IR is located within somata but absent from the nucleus. There is some faint labeling of dendrites. For abbreviations, see Figure 2. Scale bar, 75 µm.
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DISCUSSION
The present study demonstrates that olfactory experience modifies the phosphorylation state of MAP2 in the developing and adult rat olfactory bulb. Thirty days of olfactory restriction significantly reduce immunostaining with the phosphorylation-dependent antibody against MAP2 (AP18) in the granule cell layer of the bulb, whereas immunoreactivity using phosphorylation-independent MAP2 antibodies is unaffected. The fact that staining with the phosphorylation-independent antibodies against MAP2 is unchanged by naris closure suggests that the density of dendrites does not change after the manipulation but that there is a net decrease in the proportion of phosphorylated MAP2. The reduction in AP18 levels might be because of (1) a general decrease in phosphorylated MAP2 within all dendrites and somata, (2) a decrease in the number of dendrites and somata expressing phosphorylated MAP2, or (3) discrete losses of phosphorylated MAP2 within the dendritic organization.
Several nonexclusive possibilities might account for the reduction in AP18-IR after naris closure. There may be a reduction in the activity of one or more of the kinases that phosphorylate MAP2. Phosphorylation at Ser136 is required for the AP18 antibody to recognize all MAP2 isoforms (Berling et al., 1994
Alternatively, the loss of AP18-IR could be caused by an increase in phosphatase activity after naris closure. The calcium- and calmodulin-dependent protein phosphatase calcineurin dephosphorylates MAP2 in vitro (Goto et al., 1985
Another possibility for the loss of AP18-IR may be that there is an increase in newly formed MAP2 that has yet to undergo phosphorylation. Enhanced MAP2 formation could occur if the rate of cell proliferation increases or if there is enhanced dendrogenesis. However, this possibility is less likely because dendritic morphology and the rate of cellular proliferation are apparently unchanged by naris closure (Frazier-Cierpial and Brunjes, 1989a
In the visual system, experience-dependent shifts in MAP2 regulation correspond to a critical period of anatomical development. Aoki and Siekevitz (1985)
Unlike the situation in the visual system, experience-dependent shifts in MAP2 phosphorylation in the olfactory bulb are not limited to early development. Our observations suggest naris closure induces a reduction in MAP2 phosphorylation that is dependent on the duration, but not the time of onset, of closure. Changes in AP18-IR are observed after 30 d of olfactory restriction, whether restriction begins on P1 or P30. There are many explanations for the differences observed between the two sensory modalities. For example, the continued expression of embryonic MAP2 may conserve activity-dependent shifts of MAP2 phosphorylation in the adult olfactory system. Viereck et al. (1989)
Because previous studies have demonstrated that in vitro phosphorylated MAP2 is impaired in its ability to stabilize microtubules (Jameson and Caplow, 1981
Physiological activity may be a critical regulator of MAP2 phosphorylation. In the hippocampus, depolarization can induce MAP2 phosphorylation (Fukunaga et al., 1992
In sum, our data suggest that experience-dependent patterns of neural activity support relatively high levels of MAP2 phosphorylation in the bulb, because olfactory restriction, starting either before or after the sensitive period for experience-induced anatomical changes, causes a dramatic downregulation of MAP2 phosphorylation at the AP18 epitope. Although the present study detected substantial changes in the phosphorylation of Ser136 on MAP2, it is quite possible that additional phosphorylation state changes occur at other residues as well.
FOOTNOTES
Received June 18, 1997; revised Sept. 18, 1997; accepted Sept. 25, 1997.
This work was supported by National Research Service Award MH11068 (B.D.P.), NIDCD Grant DC-00338 (P.C.B.), and National Institutes of Health Grant MH50861 (S.H.). We give special thanks to Amy Batinica for technical assistance.
Correspondence should be addressed to Dr. Peter C. Brunjes, 102 Gilmer Hall, Department of Psychology, University of Virginia, Charlottesville, VA 22903.
Dr. Philpot's present address: Department of Neuroscience and Howard Hughes Medical Institute, Brown University, Box 1953, Providence, RI 02912.
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