Department of Neurobiology & Anatomy, Drexel University College of Medicine, 2900 Queen Lane, Philadelphia, PA 19129, USA
Address correspondence to S.-P. Onn, Department of Neurobiology & Anatomy, Drexel University College of Medicine, 2900 Queen Lane, Philadelphia, PA, 19129. Email: Shao-Pii.Onn{at}drexel.edu.
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Abstract |
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Key Words: calbindin calcium-binding proteins confocal microscopy glutamate immunohistochemistry psychostimulant withdrawal
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Introduction |
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In this study, we used immunohistochemistry to evaluate the effects of chronic AMPH exposure in adult rats on prefrontal cortical GABA interneurons identified by the calcium-binding proteins PV, CB and CR. We compared density of cells expressing PV, CB or CR in vehicle- versus AMPH-treated animals. Two time points were chosen for examining cortical intrinsic circuits to better associate alterations with drug-induced actions (i.e. 1 day withdrawal with the presence of AMPH in the brain system) versus alterations with the withdrawal process (i.e. 7 day withdrawal) (Onn and Grace, 2000). To further evaluate the contribution of DA receptors to the cellular changes induced by AMPH, we compared changes in rats treated repeatedly with the DA D1/D2 agonist apomorphine, and with the DA D1 agonist SKF-38393. Given the high levels of corticotropin-releasing factor (CRF) present in withdrawn animals (Richter et al., 1995
; Erb et al., 1998
; Richter and Weiss, 1999
; Zorrilla et al., 2001
), we characterized changes in terms of CRF-immunoreactive (ir) puncta in the ACC of AMPH-treated rats, at 1 day or 7 day withdrawal. In addition, using double immunofluorescence and confocal microscopy, we examined CRF-ir puncta in relation to PV-, CB- or CR-ir GABA interneurons as well as glutamate (Glu)-ir pyramidal neurons. Portions of these data were presented in abstract form (Mohila and Onn, 2001
, 2002
).
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Materials and Methods |
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Male SpragueDawley rats (n = 56) weighing 150 g at the beginning of treatment were used in this study. Animals were housed two per cage on a 12 h lightdark cycle in a climate-controlled colony with free access to food and water. Rats arriving at the colony were divided into three groups. Rats in the first group of animals (n = 20) were given escalating i.p. doses of AMPH (1.07.0 mg/kg) or an equal volume of vehicle (0.85% saline) in their home cages for 1014 consecutive days to simulate the abuse pattern of drug addicts (Robinson and Becker, 1986; Onn and Grace, 2000
). The initial dose of 1.0 mg/kg of AMPH was increased each day by 0.5 mg/kg until a final dose of 7.0 mg/kg was reached. Rats in the second group (n = 16) were given one daily i.p. injection of apomorphine (0.5 mg/kg; 0.02% ascorbic acid) or an equal volume of vehicle solution (0.02% ascorbic acid in 0.85% saline) in their home cages for 1014 consecutive days. Rats in the third group (n = 20) were given one daily i.p.injection of SKF-38393 (10 mg/kg in 0.85% saline) or an equal volume of vehicle solution (0.85% saline) in their home cage for 10 consecutive days. The injection sites alternated between left and right sides of the abdomen to minimize pain and inflammation. Animals were observed behaviorally after each injection to verify drug effects in which locomotion and stereotypy were observed in rats injected with AMPH, apomorphine or SKF-38393, but not in rats injected with vehicle. All experimental procedures were approved by Drexel University's institutional animal welfare committee in accordance with the NIH Guide for the Care and Use of Laboratory Animals.
Immunoperoxidase and Double Immunofluorescence Staining
At two time points, 1 day withdrawal from the termination of drug treatment and 7 day withdrawal from treatment, a group of 46 rats consisting of drug-treated and vehicle-treated controls were deeply anesthetized with 8% chloral hydrate (400 mg/kg, i.p.) and transcardially perfused with ice-cold saline, followed by 4% buffered paraformaldehyde. The brains were removed, postfixed in the same solution for 4 h, and then cryoprotected in 25% sucrose overnight. Tissue sections obtained from control and treatment groups were processed simultaneously for all immunocytochemical staining. Serial coronal sections (60 µm thick) were cut on a freezing microtome and collected in 0.1 M phosphate buffer (PB) solution, pH 7.4. Free-floating sections were washed with PB (3 x 10 min), pretreated with 0.5% H2O2 for 10 min, and then blocked with 5% normal serum diluted in PB containing 0.3% Triton X-100 for 1 h at room temperature. Every sixth section was incubated at 4°C overnight with mouse anti-PV (1:1000; Sigma, St Louis, MO), mouse anti-CB (1:5000; Sigma), rabbit anti-CR (1:2000; Sigma) or goat anti-CRF (1:100; Santa Cruz Biotechnology, Santa Cruz, CA) antibody diluted accordingly in PB and 5% normal serum. After several rinses in cold PB, sections were incubated for 2 h at room temperature with biotinylated secondary antibodies diluted 1:200 in PB and 2% normal serum. Sections were then rinsed three times in cold PB and incubated for 1 h at room temperature in avidinbiotin complex (Vector Laboratories, Burlingame, CA). The immunoreaction product was visualized using 0.005% H2O2 and 0.05% diaminobenzidine (DAB) (Vector Laboratories) as a chromogen. Sections were mounted on gelatin-coated slides, air dried, dehydrated with ethanol, cleared in xylenes and coverslipped using Pro-Texx (Lerner Laboratories, Pittsburgh, PA).
Using double immunofluorescence, we examined CRF immunoreactivity in combination with PV, CB or Glu immunoreactivity. Free-floating sections were incubated at 4°C overnight with goat anti-CRF antibody diluted 1:100 in PB and 5% normal donkey serum. Following several rinses with PB, sections were incubated for 4 h at room temperature with biotinylated donkey anti-goat antibody diluted 1:200 in PB and 2% normal donkey serum. After several rinses with PB, sections were subsequently incubated at 4°C overnight with avidin-Texas Red (Vector Laboratories) diluted 1:100 in PB. Sections were then incubated at 4°C overnight with mouse anti-PV (1:1000), mouse anti-CB (1:5000), rabbit anti-CR (1:2000) or mouse anti-Glu (1:500; Sigma) antibody in PB and 5% normal horse serum. Sections were subsequently incubated for 4 h at room temperature with biotinylated horse anti-mouse antibody diluted 1:200 with PB and 2% normal horse serum. After several rinses with PB, sections were incubated at 4°C overnight with avidinfluorescein (FITC) (Vector Laboratories) diluted 1:100 in PB. Although two ABC protocols for two distinct primary antibodies were mostly used in this study, an indirect immunofluorescence method was also used to process double labeling for the two individual primary antibodies and yielded similar results. For double-labeling experiments using the two ABC protocols, sections were treated with the avidinbiotin blocking kit (Vector Laboratories) between two individual primary antibodies. To assess nonspecific staining, sections were processed with omission of primary antibody or the secondary bridging serum and showed an absence of immunoreactivity. For double-immunofluorescent labeling experiments, we also verified the absence of any cross-reactivity of the secondary antibodies in control sections by incubating with a single primary antibody and then with the secondary antibody appropriate to the other primary, which yielded no specific staining. Such use of a system for detection of false positives was routinely performed to reliably exclude any potential overlap in detection of the individual fluorophores. Sections were mounted on gelatinized slides and coverslipped with Vectashield (Vector Laboratories). All other chemicals and reagents, unless otherwise indicated, were purchased from Sigma.
Quantitative Data Analysis
Quantitative analyses on the ACC and the parietal cortex were performed by an investigator who was blind to the treatment of the animal from which the particular brain tissue was taken. Immunoperoxidase-stained sections were examined/identified using a Leitz Laborlux S microscope. Digital images of the ACC were captured using a Polaroid DCM camera (Polaroid) and processed using Polaraoid DCM2 and Adobe Photoshop software packages. Images spanning cortical layers IIVI for PV-ir and CR-ir neurons and layers IIIVI for CB-ir neurons in the ACC were taken bilaterally using a 10x objective on three corresponding anatomical levels as depicted in Figure 1. The genu of corpus callosum was used as an initial reference point for aligning the counting frame (2.0 mm x 1.5 mm at the 10x objective lens). The frame was then adjusted medially to span layers IIVI of the ACC. Similarly, images of parietal cortices on three anatomical levels were taken bilaterally (using a 4x objective lens) to span layers IIVI within the counting frame (5.0 mm x 3.75 mm at 4x objective lens). Manual counting of immunoreactive neurons was done bilaterally at a final magnification of 350x in digitized color images projected on a high-resolution color monitor. PV-ir, CB-ir and CR-ir neurons were identified if they displayed clear, intense immunoreactivity in the cytoplasm and possessed a distinct nucleus. In CB-immunoreacted sections, layer II, the outer granular cell layer, had both intensely and weakly stained cell bodies that are heterogeneous in two apparent cell types, with weakly-stained cell bodies possibly co-localized with PV (Kawaguchi and Kubota, 1997). Thus, CB-ir perikarya in layer II were excluded from CB cell counts. The density of immunoreactive cells for an area (2.0 mm x 1.5 mm) was then scored. In addition, a second method of cell counting as commonly employed by Chapman and Zahm (1996)
was applied to compare with the method indicated above. Each neuron was first identified under a microscope and then traced onto a clear acetate sheet with the aid of a drawing tube attached to the microscope. The border of the ACC, an agranular cortex, can be defined accurately by referring to adjacent Nissl-stained sections. Neurons drawn on acetate sheets, which was later superimposed upon diagrams traced from serial adjacent Nissl-stained sections, were then counted with a grid of same size of counting frame as shown in Figure 1. Both counting methods revealed nearly identical numbers of neurons scored from the same area (i.e. ±1.4 cells; NS).
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Confocal Laser Microscopy
Dual immunofluorescent sections were also examined on a confocal laser scanning microscope (Leica TSC SP2) equipped with a Leica DMR microscope to reveal the relationship of CRF-ir puncta to PV-ir perikarya. Using lasers that excite at wavelengths of 488 and 543 nm respectively, FITC (green) and Texas Red (red) fluorophores were visualized. The pinhole apertures were set constant (1 airy unit) for all scans. For each section, the gain and black parameters of the confocal microscope were corrected to ensure that the entire dynamic range of each sample was captured and were kept approximately the same across samples. Z-series were scanned at 0.2 µm increments using a 40x oil immersion lens to examine the relationship between CRF-ir puncta and PV-ir perikarya. Thus, the images shown were the results of optical sections taken at 2 µm intervals and processed using Leica Confocal and Adobe Photoshop software programs.
Quantification of Tissue Area and Volume
To estimate tissue volume in the ACC of vehicle-treated controls (n = 4) and AMPH-treated rats (n = 4), measurements of tissue area (mm2) were performed on Nissl-stained sections of three corresponding anatomical levels (Fig. 1) for each brain. Measurements were taken from the midline to the genu of the corpus callosum (the mediallateral axis; M-L) and from the genu of the corpus callosum to the pial surface (the dorsalventral axis; D-V). M-L and D-V axes at 90° were averaged for each group respectively, to indirectly reflect cross-sectional areas. StereoInvestigator software (MicroBrightField Inc., Williston, VT) was employed to estimate tissue area (mm2) and volume (mm3) on these Nissl-stained sections of vehicle- and AMPH-treated rats (see Notes). Tissue thickness was measured at 48 random points within the ACC and then averaged to obtain a mean of tissue thickness for the ACC in each section. The ACC was then outlined and the area and thickness measurements were used to calculate tissue volume, using a modified Cavalieri method (Bothwell et al., 2001).
Statistical Analysis
For all drug treatments, sections at three corresponding anatomical levels (Fig/ 1) of the ACC were analyzed bilaterally; thus six data points were sampled for each rat. The density of cells was expressed as the number of immunoreactive somata per mm2. Data are presented as mean ± standard error of the mean (SEM). Data on tissue volume were tested for normality using a KolmogorovSmirnov (KS) test and results that met the criterion of a normal distribution were compared using a Student's t-test as done by Bothwell et al. (2001). Unpaired Student's t-test was used for between-subject comparisons (i.e. between the means of drug- and vehicle-treated groups). Two-way (3 experimental vehicle groups x 2 post-treatment time points) analysis of variance (ANOVA) was used to compare the baseline density of PV-ir cells among different vehicle-treated control groups and post hoc comparisons were used to further identify the source of possible interactions. Differences were considered to be statistically significant at P < 0.05.
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Results |
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Parvalbumin Immunoreactivity
In vehicle-treated adult rats, multipolar-shaped PV-ir cell bodies were scattered throughout cortical layers IIVI (Fig. 2AD). There were no apparent differences in the morphology of PV-ir neurons between vehicle- and AMPH-treated rats. Quantitative analysis revealed an average of 19.79 ± 1.08 (mean ± SE) PV-ir somata/mm2 in the ACC of vehicle-treated control rats at 1 day withdrawal (Fig. 2A; Table 1). Significantly higher densities of PV-positive neurons (24.97 ± 1.47 somata/mm2; P = 0.0061; df = 58) were found in AMPH-treated rats at 1 day withdrawal (Fig. 2C) than in vehicle-treated controls (Fig. 2A). In addition, the density of PV-ir neurons in AMPH-treated rats (25.62 ± 1.25 somata/mm2) remained significantly elevated (P < 0.0001; df = 58) at 7 day withdrawal (Fig. 2D) when compared with the density of PV-ir neurons in vehicle-treated rats (19.63 ± 0.61 somata/mm2) (Fig. 2B). Therefore, significantly higher numbers of PV-positive ACC neurons were present in AMPH-treated rats at both 1 day and 7 day withdrawal than were present in vehicle-treated rats at either of these time points (Fig. 2E; Table 1). When densities of PV-ir neurons were compared in the parietal cortex (a non-limbic cortex), similar numbers were observed between vehicle- and AMPH-treated rats, both at 1 day withdrawal (AMPH: 6.03 ± 0.77 somata/mm2 versus vehicle: 7.95 ± 0.57 somata/mm2; P = 0.055; df = 22; NS) and at 7 day withdrawal (AMPH: 9.97 ± 0.77 somata/mm2 versus vehicle: 9.28 ± 0.66 somata/mm2; P = 0.50; df = 22; NS). Therefore, compared to respective vehicle-treated controls, a significant increase in the number of PV-ir neurons was observed in limbic ACC, but not in the parietal cortex, of AMPH-treated rats at both time points examined.
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To determine whether or not the increased density of ACC neurons expressing PV in AMPH-treated rats is a result of drug-specific actions on this PV-containing subclass of GABA interneurons, we immunostained adjacent brain sections with antibodies specific for two other calcium-binding proteins, CB or CR, which co-localize in two other GABA interneuron classes (DeFelipe, 1997) and have little overlap with PV-ir neurons in deep layers (IIIVI) (Kawaguchi and Kubota, 1997
). CB-positive non-pyramidal neurons were intensely labeled in both vehicle- and AMPH-treated rats and were mostly bipolar- or multipolar-shaped somata that were easily distinguished from occasional lightly labeled pyramidal-shaped cell bodies (Fig. 3A,C). Quantitative analysis (Fig. 3E) on the density of CB-ir non-pyramidal-shaped cell bodies in the ACC revealed similar densities of CB-ir cells in AMPH-treated versus vehicle-treated control rats at 1 day withdrawal (AMPH: 7.78 ± 0.40 somata/mm2 versus vehicle: 7.67 ± 0.31 somata/mm2; P = 0.828; df = 58; NS) and at 7 day withdrawal (AMPH: 7.07 ± 0.26 somata/mm2 versus vehicle: 7.59 ± 0.24 somata/mm2; P = 0.143; df = 58; NS). CR-positive ACC neurons in both vehicle- and AMPH-treated rats were mostly bipolar-shaped somata and were intensely labeled across most cortical layers IIVI (Fig. 3B, D), with a few cells scattered in layer I. Quantitative analysis (Fig. 3F) also revealed similar densities of CR-ir neurons in the ACC of AMPH-treated versus of vehicle-treated rats, at 1 day withdrawal (AMPH: 10.42 ± 0.44 somata/mm2 versus vehicle: 9.50 ± 0.42 somata/mm2; P = 0.161; df = 46) and at 7 day withdrawal (AMPH: 10.90 ± 0.35 somata/mm2 versus 11.29 ± 0.40 somata/mm2; P = 0.466; df = 46). Therefore, in contrast to the up-regulation in the density of PV cells in the ACC of AMPH-treated rats, the density of CB- or CR-ir GABA interneurons in the ACC was not altered by repeated exposure to AMPH (Table 1).
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To determine whether the increased density of PV-containing neurons in AMPH rats was a result of drug-induced tissue shrinkage, M-L versus D-V measurements were taken at comparable anatomical sections from AMPH-treated rats. There was no statistically significant difference between groups in area measurements. This was further confirmed by area and volume calculations (StereoInvestigator). When ACC tissue area was compared between AMPH-treated and vehicle-treated control rats, similar values were revealed at both 1 day withdrawal (AMPH: 2.93 ± 0.15 mm2 versus vehicle: 2.62 ± 0.22 mm2; P = 0.27; df = 10; NS) and 7 day withdrawal (AMPH: 3.04 ± 0.09 mm2 versus vehicle: 2.77 ± 0.13 mm2; P = 0.13; df = 10; NS) (Fig. 4A). Similar volumes of the ACC were also derived in AMPH-treated and vehicle-treated control rats at 1 day withdrawal (AMPH: 0.046 ± 0.003 mm3 versus vehicle: 0.044 ± 0.002 mm3; P = 0.53; df = 10; NS) and 7 day withdrawal (AMPH: 0.052 ± 0.003 mm3 versus vehicle: 0.052 ± 0.001 mm3; P = 0.92; df = 10; NS) (Fig. 4B).
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PV- and CB-ir GABA interneurons express both DA D1 and D2 receptor subtypes, with a higher density on PV- than on CB-ir cell bodies (Gaspar et al., 1995; Vincent et al., 1995
; Meador-Woodruff et al., 1997
; Le Moine and Gaspar, 1998
). We therefore examined the effects of repeated exposure to apomorphine (a D1/D2 mixed agonist) or to SKF-38393 (a D1 agonist) on PV expression in ACC neurons. Quantitative analysis revealed a significantly higher density of PV-ir neurons at 1 day withdrawal in rats treated with apomorphine (40.79 ± 1.36 somata/mm2 versus vehicle: 18.48 ± 0.83 somata/mm2; P < 0.0001, df = 40) or in rats treated with SKF-38393 (28.89 ± 0.63 somata/mm2 versus vehicle: 21.30 ± 0.75 somata/mm2; P < 0.0001, df = 70). However, unlike in AMPH-treated rats, the increase in PV-ir neuron density at 1 day withdrawal in rats treated with apomorphine or SKF-38393 disappeared as withdrawal continued into day 7 (Table 1). Thus, at 7 day withdrawal in apomorphine-treated rats the average density of PV-ir neurons was 20.31 ± 0.75 somata/mm2, that was similar to that in vehicle-treated rats (18.63 ± 0.82 somata/mm2; P = 0.136; df = 52; NS). Similarly, in SKF-38393-treated rats at 7 day withdrawal, the average density of PV-ir neurons was 22.60 ± 0.55 somata/mm2, that was of no difference from 21.27 ± 0.48 somata/mm2 (P = 0.058; df = 46; NS) in vehicle-treated rats. Thus, unlike in AMPH-treated rats, repeated administration with either DA agonist did not produce lasting effects on PV expression (Table 1).
Two-way (3 experimental vehicle groups x 2 post-treatment time points) ANOVA revealed no effect of post-treatment time or interaction between factors on the density of PV-ir neurons; however, the effect of vehicle treatments reached statistical significance [F(2,156) = 5.51, P = 0.005]. Post hoc analyses further revealed differences in vehicle-treated rats between SKF-38393 group and apomorphine-group, at both 1 day [F(1,52) = 6.89, P = 0.0113] and 7 day withdrawal [F(1,46) = 7.36, P = 0.0094] (Table 1); this may be attributed to the ascorbic acid (an antioxidant) contained in the vehicle for apomorphine treatment. There were no significant differences among other comparisons. Thus, the density of PV-ir somata in vehicle-treated rats of AMPH- versus apomorphine-group was of no difference, either at 1-day [F(1,46) = 0.72, P = 0.399; NS] or at 7 day [F(1,52) = 1.01, P = 0.319; NS] withdrawal. No differences were revealed in vehicle-treated rats between the AMPH and SKF-38393 groups, either at 1 day [F(1,64) = 1.56, P = 0.216, NS] or at 7 day withdrawal [F(1,52) = 3.73, P = 0.059; NS].
Corticotropin-releasing Factor Immunoreactivity
Neurochemical studies have shown elevated concentrations of CRF in rats during psychostimulant withdrawal (Richter et al., 1995; Nemeroff, 1998
; Richter and Weiss, 1999
). In this study, we compared CRF immunoreactivity in ACC neurons of vehicle- and AMPH-treated rats. CRF-ir cell bodies were faintly labeled in adult ACC (Yan et al., 1998
) and cytoplasmic CRF staining appeared homogeneously light brown right up to the rim of nucleus. However, intensely labeled CRF-ir terminal-like puncta were frequently found in the neuropil of the ACC, surrounding somatic profiles in both vehicle- (Fig. 5A) and AMPH-treated rats (Fig. 5B). Occasionally, CRF-ir puncta, in particular in AMPH-treated rat ACC (Fig. 5B3), were observed to cover significant outer portions of cytoplasm, but never abut the rim of nucleus (see Fig. 6), suggesting they derive from nerve endings making possible contacts with the cell body (Lowry et al., 2000
). The estimated density of CRF-ir puncta was 4.50 ± 0.24 somata/mm2 in the ACC of AMPH-treated rats at 1 day withdrawal, by counting the number of somata that were apposed by CRF-ir puncta (Fig. 5C). This was not significantly different from the average 4.97 ± 0.29 somata/mm2 in the ACC of vehicle-treated control rats (P = 0.3173; df = 82; NS). However, at 7 day withdrawal of AMPH-treated rats, a significantly higher density of somata was apposed by CRF-ir puncta (9.02 ± 0.33 somata/mm2) relative to the average of 5.44 ± 0.30 cells/mm2 in vehicle-treated controls (P < 0.0001; df = 82; Fig. 5C).
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Discussion |
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PV calcium-binding protein evolved as a functionally distinct, physiologically relevant modulator of intracellular calcium transients that is critical for synaptic plasticity, as PV-knockout mice fail to maintain synaptic transmission during high-frequency firing (Caillard et al., 2000). Cortical GABA neurons co-localized with PV, often termed fast-spiking (FS) neurons, are known to fire at an extremely high frequency (Baimbridge et al., 1992
; Kawaguchi and Kubota, 1993
). The increase in PV after AMPH treatment may be protective against prolonged bursting activity in this subclass of GABA interneurons, as an increase in the level of PV in GABA neurons can be induced by bursting activity (Chard et al., 1993
). Furthermore, GAD activity in GABA neurons is regulated by levels of internal calcium and is increased after tetanic stimulation (Erecinska et al., 1996
). Thus, increased PV expression in this study is believed to reflect increased GABA neuron activity. A corresponding increase in both PV and GABA immunoreactivities was reported in the ACC of rabbits subjected to prenatal (intrauterine) cocaine exposure (Wang et al., 1995
). The PV-containing GABA interneurons, corresponding morphologically to wide arbor (basket) and chandelier cells, have their axonal arbors elaborating mostly horizontally/vertically to make chemical synapses on somata/axon initial segments of pyramidal neurons (DeFelipe et al., 1989
; DeFelipe, 1997
; Lewis and Lund, 1990
; Cruz et al., 2003
) and strongly regulate cortical output activity. However, PV is only present in a subpopulation of chandelier axon cartridges (Lewis and Lund, 1990
; Del Rio and DeFelipe, 1997
; Cruz et al., 2003
), thus heterogeneity is present among basket and chandelier neurons. CB and somatostatin were recently identified in axo-axonic terminals in making synapses on many axon initial segments of pyramidal neurons in human temporal cortex (DeFelipe, 1997
) and rat visual cortex (Gonchar et al., 2002
), respectively. Based on our present findings, it is justified to assume that increased PV neuron density in AMPH rats is a result of drug-induced increases in its cellular expression and consequent detectability in previously undetected PV-neurons, and probably not due to emergence of a new set of neurons. PV-containing FS GABA interneurons can contact tens of PV-containing GABA neurons (Galarreta and Hestrin, 1999
; Gibson et al., 1999
; Gonchar and Burkhalter, 1999
; Amitai et al., 2002
) that could lead to disinhibition of pyramidal neurons. These complex inhibitory/disinhibitory processes within GABA interneuronal networks can induce cortical oscillatory activities (Cobb et al., 1995
) and synchronize gamma oscillations (Traub et al., 2001
). A differentiated pattern of changes in different calcium binding proteins (i.e. PV as opposed to no changes in calbindin and calretinin) and its functional significance in altering dendritic branching pattern and spine density (Robinson and Kolb, 1997
) and neuronal synchronization in pyramidal neurons of AMPH-withdrawn rats (Onn and Grace, 2000
) should encourage further studies into detailing cortical microcircuits in amphetamine addicts.
Two time points were chosen in the present study to associate cellular changes in PV either with drug treatment (i.e. at 1 day withdrawal) or with the withdrawal process (i.e. at 7 day withdrawal). Repeated exposure to apomorphine (a DA D1/D2 agonist) or to SKF-38393 (a D1 agonist) can also induce PV up-regulation during the treatment period (i.e. at 1 day withdrawal), suggesting that the PV increases at 1 day withdrawal of AMPH-treated rats may result from repeated stimulation of DA receptors. A larger increase in the density of PV-ir neurons was noted in rats repeatedly exposed to apomorphine than in rats exposed to SKF-38393. The increase in the former group is reminiscent of what was observed in AMPH rats. This may be explained by the fact that D1 and D2 receptors are preferentially co-localized to PV-containing GABA interneurons (see Introduction). The involvement of amines other than DA cannot be excluded, as AMPH releases DA and other amines (e.g. norepinephrine and serotonin). However, the lack of PV changes in the parietal cortex of AMPH-treated rats (present study) speaks for the critical involvement of the mesolimbic/mesocortical DA system in PV changes, because parietal cortex, a non-limbic cortex, contains low levels of DA fibers (but high levels of noradrenergic fibers: Stanwood et al., 2001). Similarly, psychostimulants (AMPH and cocaine) increase c-fos activity, i.e. increased neuronal activity (Sharp et al., 1993
; Chapman and Zahm, 1996
), only in cortical structures (e.g. the prefrontal cortex) that tie closely to the mesolimbic/mesocortical DA system) and thereby the ventral basal ganglia loop linked to drug-seeking behavior (McFarland and Kalivas, 2001
).
Compelling evidence exists for a regulatory role of DA receptors on GABA activity within the prefrontal cortex (PFC). Neurochemically, activation of DA D2 receptors within the PFC by D2 agonists increases spontaneous GABA release (Retaux et al., 1991; Grobin and Deutch, 1998
) and blockade of these D2 receptors decreases GABA levels (Bourdelais and Deutch, 1994
). Physiologically, DA excites cortical GABA interneurons (Penit-Soria et al., 1987
; Zhou and Hablitz, 1999
), probably via D1 receptors (Seamans et al., 2001
). Thus, activation of DA D1 receptors within the PFC can increase membrane excitability of GABA interneurons, thereby enhancing GABA release (Seamans et al., 2001
). On the other hand, Gao et al. (2003)
have recently shown that DA via presynaptic D1 receptors reduced inhibitory postsynaptic currents arising only from axons of FS interneurons (PV-containing), but not from axons of non-FS interneurons (e.g. CB- and CR-containing). This non-uniform DA action, preferentially targeting axons of FS-GABA interneurons in the ACC, is consistent with our postmortem observations that showed the preferential up-regulation of PV expression in the ACC of AMPH-treated rats.
DA receptor activation however did not appear to account for the up-regulation of PV observed in AMPH-treated rats at 7 day drug withdrawal: different cellular mechanisms may account for this persistent PV up-regulation. Our present study showed increases in densities of both CRF-ir puncta and PV-ir cell bodies in AMPH-treated rats at 7 day withdrawal. Interestingly, we observed no cases of CB-, CR- or Glu-containing neurons that were apposed by CRF-ir puncta. The crisp appearance of CRF-varicosities could only be obtained by incubating CRF-primary alone (followed later by PV-primary), not by the cocktail method (incubating both CRF-primary and PV-primary together). This may be caused by the fact that CRF peptides are delicate and in low concentrations in axons compared to the level and resilience of calcium-binding proteins in cell bodies. Nevertheless, sequential incubations of CRF-ir puncta with PV (or CB, CR, Glu) antibodies in double-labeling experiments revealed similar increases in CRF-ir puncta by single immunoperoxidase stains on brain sections reacted only for CRF (Fig. 5). As CRF and PV coexist in some basket/chandelier cells (Lewis and Lund, 1990; DeFelipe, 1997
), we observed a few cases of cytoplasmic co-localization of CRF and PV (Fig. 6B). In those cases, cytoplasmic CRF-ir staining appeared yellow in the merged images (of two individual fluorophores red and green; Fig. 7) and can be differentiated from CRF-varicosities in red (rarely co-localized with PV). These interrelated pre-/postsynaptic structures between CRF-varicosities and PV-ir cell bodies can be easily discerned in three-dimensional views by rotating these structures every 20°, as exemplified in Figure 7. Increased CRF-ir puncta and their exclusive association with PV-ir neurons in the ACC suggest a causal relationship between increased CRF release (Richter et al., 1995
; Erb et al., 1998
; Richter and Weiss, 1999
; Zorrilla et al., 2001
) and sustained PV expression during AMPH withdrawal (present study).
CRF-ir puncta within neocortex could arise from CRF-containing local circuit neurons (see Fig. 6B2) that overlap to some extent with PV-ir neurons (Sakanaka et al., 1987; Lewis et al., 1989
; Yan et al., 1998
). CRF-ir GABA interneurons (Lewis et al., 1989
), were mostly lightly stained in the adult ACC (Yan et al., 1998
). This was attributed to low levels of CRF peptides in cell bodies in the mature neocortex, as CRF-ir neurons in adult rat neocortex are often undetected, and thereby appear less numerous than those stained in immature rat cortex (Yan et al., 1998
). Colchicine pretreatment is commonly used to block axonal transport to increase detectability of CRF-ir cell bodies in adult neocortex (Sakanaka et al., 1987
; Yan et al., 1998
). This technical difficulty has prevented us from evaluating changes in CRF-ir local circuit neurons to further associate them with the increased CRF-ir puncta during withdrawal. However, an extrinsic source for CRF-ir puncta in the ACC could arise from the amygdala or hypothalamus (Bloom et al., 1982
; Swanson et al., 1983
; Daikoku et al., 1985
; Richter et al., 1995
) that uses Glu as the neurotransmitter. Our occasional observation (Fig. 6G) of the coexistence between CRF-ir and Glu-ir puncta in AMPH-withdrawn rats favors such a possibility. CRF from an extrinsic source (i.e. from amydgala and hypothalamus) has been shown to change firing activity in both serotonergic and noradrenergic neurons by making possible pericellular contacts with their cell bodies (Siggins et al., 1985
; Valentino and Foote, 1988
; Lowry et al., 2000
). It is highly possible that the increase in CRF-ir puncta in the ACC during withdrawal may exert significant influence over cortical inhibitory tone by directly modulating PV expression. CRF peptides, present at extremely low levels in axon terminals, may go undetected in normal (vehicle-treated) animals. Increased levels of CRF in axon terminals during withdrawal are presumably due to axonal transport from the somata, where CRF is synthesized, and may act to cope with the increased demand of terminal release during psychostimulant withdrawal. Increased CRF release in limbic cortices of AMPH-withdrawn rats may be a mechanism whereby altered GABA inhibitory tone during withdrawal leads to relapse to drug seeking (Richter et al., 1995
; Erb et al., 1998
; Richter and Weiss, 1999
; Zorrilla et al., 2001
).
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