Pgc-1α Overexpression Downregulates Pitx3 and Increases Susceptibility to MPTP Toxicity Associated with Decreased Bdnf

The full length murine Pgc-1α gene (∼2.4 kb) was amplified by PCR using the flag-HA Pgc-1α pCDNA construct as the DNA template (generously provided by the Carles Lerin [36]). A SalI restriction site, Kozak sequence, and ATG start codon were added to the 5′ end of the Pgc-1α full length coding region using the forward primer 5′-GTTCTGGTCGACGCCACCATGGACTACAAGGACGACGATGAC-3′. A stop codon and HindIII restriction site were amplified at the 3′ end of the coding region using primer 5′-GTTCTGAAGCTTTCATCTCTGAGCTTCCTTCAGTAA-3′. The Pgc-1α PCR product was digested sequentially with SalI and HindIII and ligated into the same sites of the pACP-BHI plasmid (gift from Caroline Bass). The pACP-BHI plasmid contains the CMV promoter, a multiple cloning site and intron/polyA sequences derived from SV40. These elements are flanked by AAV2 inverted terminal repeats. The ligation was transformed into Escherichia coli DH5α using low temperature (30°C) growth and recovery of the DH5a to propagate the FHA-Pgc-1α vector. The final maxi-prep of the AAV-expression construct was sequenced to ensure correct insertion and the fidelity of the nucleotide sequence. Constructs consisting of EGFP-pACP and mCherry-pACP were used as controls. Packaging of the AAV2/10-FHA-Pgc-1α, AAV2/10-mCherry and AAV2/10-EGFP was carried out according to the standard triple transfection protocol to create helper virus-free pseudotyped AAV2/10 virus [37]. An AAV2/10 rep/cap plasmid provided the AAV2 replicase and AAV10 capsid genes [38]–[39], while the pHelper plasmid (Stratagene, La Jolla, CA) provided the adenoviral helper functions. Briefly, to produce virus, AAV- 293 cells grown in a 10 cm tissue culture dish were transfected with 10 µg of pHelper, 1.15 pmol each of AAV2/10 and AAV expression plasmids (FHA-Pgc-1α-pACP, mCherry-pACP or EGFP-pACP) via calcium phosphate precipitation. The cells were harvested 72 hours later, the pellets resuspended in DMEM, freeze-thawed and centrifuged several times to produced a clarified viral lysate. The virus was quantified using real-time PCR to measure the number of viral genome copies (vgc) contained within the intact virions.

Adult (11–16 week) male C57BL/6 mice were obtained from Charles River Laboratories, Wilmington, MA. Mice were anesthetized with ketamine/xylazine and placed in a stereotaxic frame (myNeurolab, Leica Microsystems) with a mouse adapter. The tip of a pulled glass pipette (diameter) was inserted to stereotaxic coordinates AP:−2.9 mm; ML:−4.0 mm; DV:+1.2 mm, relative to bregma. Viral vector suspension in a volume of 1.5 µl was microinjected into the right hemisphere using 0.069 µl bursts from a Nanoliter 2000 injector (World Precision Instruments). This corresponded to 2×10¹⁰ viral genome copies (vgc) of AAV2/10-FHA-Pgc-α and 1×10¹⁰ vgc AAV2/10-mCherry.

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine hydrochloride (MPTP; Sigma Aldrich) was re-suspended in 0.9% sterile saline (Hospia) to a final concentration of 3.3 mg/ml MPTP (calculated as free base). MPTP was administered via subcutaneous injection at a dose of 20 mg/kg body weight three weeks post-stereotaxic surgery. Injections were performed every two days for a period of 9 days (5 injections in total).

Five days after the last MPTP or saline injection, mice were injected with 2 mg/kg body weight of amphetamine sulfate (Sigma Aldrich) in 0.9% sterile saline. After 15 minutes the mice were placed individually in a 28 (radius) × 37 (height) cm circular cylinder and behavior was recorded for 30 minutes after which time the mouse was returned to the home cage. The video recordings were scored by an individual blinded to treatment status, according to the number of ipsiversive or contraversive turns made, with one turn being defined as one full rotation of a point on the animal’s head past a marked point on the cylinder. Net scores were obtained by subtracting the number of contraversive turns from the number of ipsiversive turns.

All animal procedures, as described above, were approved by the Beth Israel Deaconess Medical Center Animal Care and Use Committee (Permit numbers: 035-2008 and 027-2011).

Two days after amphetamine-induced rotational behavior testing, mice were sacrificed via anesthetic overdose (ketamine/xylazine) and perfused with ice-cold 0.9% saline followed by 4% paraformaldehyde (PFA; Boston Bioproducts). Fixed brains were stored at 4°C in 4% PFA until cryopreservation for sectioning. Brains were cryoprotected by dehydration in 15% sucrose in PBS for 24 hours followed by 30% sucrose in PBS for 24 hours. Following cryoprotection, each brain was sectioned through the striatum, midbrain and SN at a thickness of 40 µm on a freezing microtome. Sections were permeabilized in TBS containing 0.25% Triton-X-100 for 30 minutes. The tissue sections were blocked in TBS +3% bovine serum albumin (BSA) for 1.5 hours at room temperature then incubated overnight at 4°C with the primary antibodies sheep anti-TH (AbCam) and rat anti-HA (Roche) each diluted 1∶1000 in TBS +1% BSA. The secondary antibodies Alexa Fluor donkey anti-sheep 594 and Alexa Fluor goat anti-rat 488 (Molecular Probes, Invitrogen) were diluted 1∶1000 in the same diluent and incubated with the tissue for 1.5 hours at room temperature. Sections were mounted with Vectashield mounting medium with DAPI (Vector Laboratories).

Immunohistochemical staining for tyrosine hydroxylase (Th) was performed using a mouse monoclonal anti-Th antibody (Sigma Aldrich 1∶1000) and a Mouse-on-mouse kit (Vector Laboratories, Burlingame, CA) according to the manufacturer’s instructions. Immunohistochemistry for the dopamine transporter (Dat) was performed using a rat anti-DAT (Millipore) primary and a goat anti-rat IgG biotin-conjugated secondary antibody and a standard immunostaining protocol. Briefly, free-floating brain sections were permeabilized with 0.25% Triton-X-100 in TBS for 10 minutes and blocked in 3% normal goat serum (NGS, Jackson Immunolabs) in TBS for 30 minutes. All antibody incubations were performed using 1% NGS as a diluent. The sections were incubated with a 1∶5000 dilution of primary antibody overnight at 4°C and with secondary antibody diluted at 1∶1000 for 45 minutes. The ABC kit (Vector Laboratories) was used for signal amplification and binding of the antibody was visualized using diaminobenzidine with nickel intensification (Vector Laboratories). The sections were mounted on Superfrost Plus slides (VWR) and dehydrated through an ethanol series before clarifying with xylene and cover-slipping with Permaslip (Alban Scientific). A subset of samples were counterstained by immersion in thionin solution (pH 4.2–4.4) for 5 minutes before subsequent dehydration, clarification and cover-slipping.

For striatal densitometry, the stained sections were imaged using a light microscope fitted with a camera (SPOT) and images were captured using a 10× objective and fixed exposure settings. Densitometry was performed to quantify the intensity of Th and DAT immunostaining in the striatum ipsilateral to the microinjected SN and in the contralateral striatum. Specifically, using Adobe Photoshop, a region of interest 200×200 pixels was delineated in the striatum. The integrated density of this region was calculated using the software. Next, a 200×200 pixel region of interest was delineated over the adjacent cortex of the same section and the integrated density of this area calculated by the software. To normalize for differences in background staining intensity the cortical integrated density measurement was subtracted from the striatal integrated density measurement for each section analyzed.

For stereology, the midbrain of each mouse was sectioned using a freezing microtome into four series of 40 µm coronal sections and one series was stained with an anti-Th antibody, as before, for stereological cell counts in the SN. Stereology was performed using the optical fractionator method by an investigator blinded to treatment status. After mounting, each section in the series was observed using a 2.5 × objective lens and an outline was drawn around each SN and overlaid with a 50×50 counting frame using Stereo Investigator software (MicroBrightField). The nuclei of each Th+ cell within the boundaries of the optical fractionator (X 120, Y 120, height 10 µm; with 2 µm guard zones) was counted. The total numbers of Th+ cells per SN were then calculated by the optical fractionator software. A subset of samples were analyzed for total SN neuronal counts. In this case, stereology was performed in the same manner with a second marker used for simultaneous counts of thionin+/Th- neurons with Th- neurons being defined as those cells morphologically resembling neurons and with a visible nucleolus but lacking Th immunoreactivity.

Mice were sacrificed by anesthetic overdose seven days after the final MPTP or saline injection. Animals used for these biochemical measurements had not undergone amphetamine-induced rotational behavior testing. The brains were rapidly removed, placed into a chilled brain matrix and sliced into 1 mm thick coronal sections on ice. The sections were then placed into ice-cold saline. The striatum was dissected from these 1 mm sections, snap-frozen and used for HPLC analysis of DA and DA metabolites, performed by the Neurochemistry Core, School of Medicine, Vanderbilt University. The levels of DA and DA metabolites were normalized to mg of protein input. Dopamine turnover was calculated as follows: DA turnover  =  (HVA + DOPAC)/DA.

Brain tissue samples were homogenized in ice-cold lysis buffer using the TissueLyser LT with 5 mm stainless steel beads (Qiagen). Tissue was homogenized in 50 mM Tris-HCl (pH 7.4), 150 mM NaCl and 1% Triton-X 100 supplemented with protease inhibitors to a final concentration of 1× (Sigma-Aldrich). Protein concentrations were determined by Bicinchoninic Acid (BCA) Assay (Thermo Scientific) according to the manufacturer's instructions. Proteins were separated by SDS-PAGE on an appropriate Tris-HCl gel according to standard protocols. The membranes were blocked with 5% non-fat milk in either 1× PBS-0.1%Tween or 1× TBS-0.1%Tween. Primary antibodies were diluted in blocking solution in the following manner: mouse anti-β-actin (C4) (sc-47778, Santa Cruz) 1∶1000; mouse anti-Th (T2928, Sigma Aldrich) 1∶1000; rabbit anti-cyrochrome c oxidase subunit 4 (CoxIV) 1∶1000 (4850, Cell Signaling Technologies); mouse anti-Pgc-1α 1∶1000 (ST1202, Calbiochem) and incubated on the membranes with rocking overnight at 4°C. HRP conjugated anti-mouse IgG-HRP or anti-rabbit IgG (Santa Cruz and Cell Signaling Technology) were diluted 1∶1000 in blocking buffer and incubated with the membranes at room temperature for 1 hour. The LumiGOLD ECL Western Blotting Detection Kit (SignaGen) was used according to manufacturer's instructions and the blots were imaged by exposure on Amersham Hyperfilm ECL (GE Healthcare). Band densities were quantified using Adobe Photoshop as before [40]. Briefly, the image was converted to grayscale and inverted with respect to black and white (so that positive values correspond to darker bands) and the freehand selection tool was used to outline each band. Photoshop automatically computed the integrated density (the product of area and mean gray value) of each band. The integrated density of each band of interest was normalized to the integrated density for the loading control of that band.

After dissection as before, RNA was extracted from the striata or SN using the RNeasy mini kit (Qiagen). After DNase treatment the RNA was purified using the RNeasy MinElute Clean-up kit (Qiagen) and used as a template for cDNA synthesis with High-Capacity cDNA Reverse Transcription Kit (Applied Biosystems). The final cDNA reaction was diluted seven-fold and 5 ul of the reaction was used in duplicate 15 ul SYBR-Green (Applied Biosystems) PCR reactions with primers specific to the target gene. Cycle numbers were normalized to the numbers obtained for a parallel 18S reaction, and fold-induction of the gene of interest was calculated in relation to the uninjected striatal or SN hemisphere of the same animal by the ΔΔCt method.

All statistical analyses were performed in Prism (Graphpad Software, La Jolla). For all comparisons of the microinjected hemisphere versus the contralateral hemisphere data were analyzed using a Student’s paired t-test. For comparisons between mCherry and Pgc-1α overexpressing SNs, the fold-changes relative to the contralateral sides were calculated and these values compared using Student’s t-test. Statistical comparisons of three groups or more were performed using a one-way ANOVA with post hoc Dunn’s Multiple Comparison Test. Numbers of mice indicated in the results section refer to numbers for each set of experimental conditions.

The AAV2/10-FHA-Pgc-1α vector was microinjected into the right-hemisphere SN of wild-type C57BL/6CR mice. The contralateral SN received no injection and served as control tissue. 1.5 µl of AAV2/10-FHA-Pgc-1α, corresponding to approximately 2×10¹⁰ vgc, or total intact virions injected, resulted in a mean 66.6-fold increase in Pgc-1α expression in the microinjected SN compared to the contralateral side (95% CI 15.73–117.6; p = 0.02) measured 5 weeks after injection (Figure 1A) by SYBR-green PCR using a primer set that does not discriminate between known Pgc-1α isoforms. This increase in Pgc-1α expression also induced target gene expression above baseline levels measured from the contralateral SN. Mean Prdx3 expression increased 2.3-fold (95% CI 1.24–3.3; p = 0.03). A 2.7-fold increase in expression was observed for both Prdx5 (95% CI 1.13–4.27; p = 0.04) and Cycs (95% CI 1.12–4.22; p = 0.04). There was a borderline significant 1.7-fold increase in mean Errα mRNA levels (95% CI 0.99 to 2.49; p = 0.05). AAV2/10-mCherry control injections did not significantly alter levels of expression of Pgc-1α or any of its target genes. In mice treated with 20 mg/kg MPTP (Figure 1B), the same titer of AAV2/10-FHA-Pgc-1α virus resulted in a 37.2-fold mean increase in Pgc-1α expression relative to the contralateral side (95% CI 11.03–63.45; p = 0.02). Again, Pgc-1α target genes were induced: Errα mRNA levels increased by a mean value of 2.15 (95% CI 1.09–3.12; p = 0.04), Prdx3 expression increased 1.6-fold (95% CI 1.07 to 2.21; p = 0.04), and Cycs increased 2.4-fold (95% CI 1.08–3.71; p = 0.04). A trend towards increased expression of Prdx5 after Pgc-1α overexpression and MPTP treatment did not reach statistical significance (95% CI 0.83 to 3.1; p = 0.08).

The 120 kD Pgc-1α protein was detected in the pooled samples from Pgc-1α-microinjected SNs (Figure 1C). We also detected a strong 35–38 kDa band that corresponded to the size of the published NT-Pgc-1α isoform [41] in the lysate from the Pgc-1α microinjected SN and in the contralateral SN of the same animals. This band was present only at a very low level in the ipsilateral and contralateral SNs of mCherry mice. This may indicate that some smaller Pgc-1α fragment may cross the midline into the contralateral hemisphere, or that unilateral Pgc-1α expression in one SN may have positive effects on Pgc-1α expression in the contralateral SN. However, analysis of Pgc-1α mRNA levels in the contralateral SN of Pgc-1α overexpressing animals compared to the contralateral SN of mCherry overexpressing animals, using the same cDNA samples as for Figure 1D, did not detect an increase in full-length Pgc-1α mRNA in the contralateral SN from ‘crossed over’ AAV2/10-FHA-Pgc-1α at time of sacrifice (data not shown).

The strong 35–38 kDa band seen on the western blot (Figure 1C) after Pgc-1α overexpression is unlikely to correspond to the published NT-Pgc-1α [41] isoform since the cDNA construct used lacks the intronic splice site required to generate this isoform. To investigate whether or not overexpressed full-length Pgc-1α could be inducing expression of an endogenous, shorter Pgc-1α transcript we measured Pgc-1α expression using primers specific for a shorter Pgc-1α isoform (a kind gift from Jorge Ruas, Figure 1D). Data were analyzed using a one-sample Student’s t-test with a theoretical mean of 1, corresponding to the baseline level of gene expression on the contralateral side, and we detected a 0.5-fold downregulation of this shorter transcript in the presence of AAV2/10-FHA-Pgc-1α compared to the contralateral side (95% CI 0.25 to 0.76; p = 0.004). Thus, the identity of the 35–38 kDa band seen on the western blot after Pgc-1α overexpression remains unknown. It is possible that this band represents misfolded protein, or a breakdown product of Pgc-1α that is not degraded as effectively as full-length Pgc-1α and retains the Pgc-1α epitope detected by the antibody. In addition, while this manuscript was in preparation several brain-specific Pgc-1α isoforms originating from an alternate promoter were identified [21]. Currently the expression-level of these novel isoforms in the SN remain undetermined.

A control AAV2/10-egfp virus spread well throughout the SN and was capable of transducing Th+ cells, as observed by viewing native fluorescence of EGFP (Figure 1E, green) on brain sections immunostained for Th (Figure 1E, red). Immunofluorescence staining for the HA-tag of the AAV2/10-FHA-Pgc-1α construct revealed expression of Pgc-1α in the SN (Figure 1F, green). However, surprisingly, the majority of HA-Pgc-1a was not co-localized with the expected pattern of Th immunofluorescence (Figure 1F, red). In addition, higher magnification (Figure 1F, right panel and figure 1G) revealed that the overexpressed Pgc-1α protein (green) was both nuclear (blue, DAPI fluorescence) and cytoplasmic.

To determine whether Pgc-1α overexpression in the SN affected mitochondrial load, western blot for CoxIV was performed on whole-cell SN lysates (Figure 2). It can be seen that overexpression of Pgc-1α did not significantly alter CoxIV levels in the SN of saline-treated mice compared to the contralateral side, although there was a trend towards an increase (mean increase of 1.6-fold; 95% CI 0.94 to 2.20 p = 0.07). However, there was a significant 1.4-fold increase in CoxIV protein in the Pgc-1α overexpressing SN of MPTP-treated mice, relative to the contralateral side, regardless of whether the CoxIV band densitometry data was normalized to b-actin (95% CI 1.26 to 1.57; p = 0.001) or Tubb3 (95% CI 1.08 to 1.71; p = 0.024; n = 6, data not shown). There was no significant difference (0.35±0.33) between CoxIV band densitometry data when Pgc-1α microinjected SN samples from saline-treated or MPTP-treated animals were compared (95% CI −1.078 to 0.377; p = 0.308). A similar immunoblot using striatal tissue from Pgc-1α-microinjected animals did not detect increased CoxIV protein in the striatum ipsilateral to Pgc-1α overexpression (Figure 2, right-side blot).

Mice were unilaterally microinjected in the (right) SN with AAV2/10-FHA-Pgc-1α or with AAV2/10-mCherry and 5 weeks later were exposed to MPTP or saline. Five days after the last saline or MPTP injection, the mice were assessed for rotational behavior induced by intraperitoneal administration of 2 mg/kg amphetamine (Figure 3A). Amphetamine tends to induce ipsiversive rotations in a mouse with a unilateral DA deficit. For this experiment, we predicted that unilateral overexpression of Pgc-1α would protect against MPTP toxicity ipsilateral to the injection, resulting in rotatations contraversive to the microinjected side. As expected, animals unilaterally overexpressing mCherry in the SN did not show a preferred direction of left-right rotation after amphetamine administration, as measured by net ipsilateral rotations/minute (Figure 3B), regardless of whether they were saline treated (0.32 net right rotations/minute; 95% CI −1.47 to 2.10; p = 0.70) or MPTP treated (−0.02 net right rotations/minute; 95% CI −2.15 to 2.11; p = 0.98). However, unexpectedly, mice that unilaterally overexpressed Pgc-1α in the SN exhibited a strong rotational preference toward the right-side, i.e. ipsiversive to Pgc-1α overexpression, regardless of whether the mice had received saline (mean 4.9 net right turns/minute; 95% CI 2.70 to 7.05; p = 0.0004) or MPTP treatment (mean 4.25 net right turns/minute; 95% CI −1.7 to 8.67; p = 0.06), although the p-value for the MPTP-treated mice was borderline. Also, the tendency to turn towards the right side in saline treated mice was significantly greater when the AAV2/10-FHA-Pgc-1α microinjected mice were compared to AAV2/10-mCherry microinjected mice (95% CI 1.91 to 7.21; p = 0.002). A similar tendency for mice microinjected with AAV2/10-FHA-Pgc-1α and treated with MPTP to turn towards the ipilateral side again did not quite reach statistical significance when analyzed by comparing AAV2/10-FHA-Pgc-1α to AAV2/10-mCherry microinjected mice (95% CI −9.0 to 0.46; p = 0.07), potentially due to statistical noise introduced by varying levels of MPTP toxicity between animals. These data indicate that unilateral overexpression of Pgc-1α leads to amphetamine-induced ipsilateral rotational behavior, suggesting that overexpression of Pgc-1α leads to DA depletion.

Stereotaxic injection of the AAV2/10-mCherry virus into the SN did not significantly alter levels of DA or DA metabolites (Figure 3C) as indicated by an absence of significant side-to-side differences in striata of these animals regardless of whether the animals were subsequently treated with saline (95% CI 0.85 to 1.01; p = 0.07) or MPTP (95% CI 0.84 to 1.03; p = 0.14).

In agreement with the ispiversive amphetamine-induced turning behavior, mice unilaterally overexpressing Pgc-1α in the SN have dramatically lower levels of DA and DA metabolites in the striatum ipislateral to Pgc-1α overexpression compared to the ipsilateral striatum of mCherry overexpressing mice. The mean DA level after Pgc-1α overexpression was 13.5 ng/mg protein, whereas in the mCherry animals this was 129.0 ng/mg protein, a difference of 115.4 ng/mg (95% CI 101.3 to 129.6; p = <0.0001). The mean level of DOPAC is reduced to 1.3 ng/mg protein after Pgc-1α overexpression compared to a mean level of 7.7 ng/mg protein after mCherry expression. For HVA the mean level is reduced to 3.3 ng/mg protein after Pgc-1α overexpression compared to 9.9 ng/mg protein after mCherry overexpression, and for 3-MT Pgc-1α overexpression yields a mean value of 2.8 ng/mg protein compared to 11.7 ng/mg protein for mCherry. Each of these comparisons is significant at the p = <0.0001 level. In addition, SN overexpression of Pgc-1α leads to significantly increased DA turnover from a mean ratio of 0.2 in the contralateral striatum to 0.58 in the ipsilateral striatum, an increase of 0.36 (Figure 3D; 95% CI 0.13 to 0.57; p = 0.004), representing a mean 2.9-fold increase. This effect is further pronounced after treatment with MPTP where DA turnover is increased by 1.0 (95% CI 0.660 to 1.356; p = <0.0001) from a mean ratio of 0.31 to 1.32 after Pgc-1α overexpression, representing a mean 4.3-fold increase.

Overexpression of Pgc-1α in the SN caused an average 69.4% reduction in Th immunoreactivity, a mean reduction of 9.9×10⁷ AU (95% CI 4.2×10⁷ to 16×10⁷; p = 0.004; Figure 4A), from a mean adjusted integrated density of 14×10⁷ AU in the contralateral striatum compared to 4.4×10⁷ AU in the striatum ipsilateral to microinjection. Overexpression of mCherry in the SN also significantly reduced Th immunoreactivity in the striatum from an average adjusted integrated density of 12×10⁷ AU to 10×10⁷ AU, a mean reduction of 1.9×10⁷ AU (95% CI 0.29×10⁷ to 3.5×10⁷; p = 0.03), a much lesser decrease than that seen following Pgc-1α overexpression. These data indicate that the injection procedure, the virus itself, or the mCherry protein had a mild impact on Th immunostaining in the striatum, but this impact accounts for less than 20% of the magnitude of effect seen following Pgc-1α overexpression. Evidence that Pgc-1α overexpression induces a reduction in levels of Th protein, beyond that seen with mCherry is further demonstrated by western blot data (Figure 4G) where there is no loss of Th protein in mCherry SN or striatal samples.

As expected, MPTP treatment largely ablated Th expression in the striatum (Figures 4A and 4D) and this loss of Th immunoreactivity was not exacerbated by overexpression of either mCherry (95% CI −2.1×10⁷ to 5.0×10⁷; p = 0.38) or Pgc-1α (95% CI −1.4×10⁷ to 3.4×10⁷; p = 0.38), potentially reflecting a floor effect.

Immunoreactivity for the DA transporter (Dat; Figure 4B) was not significantly altered by mCherry overexpression with a mean difference of 2.7×10⁷±9.3×10⁷ between striatal hemispheres (95% CI −2.3×10⁸ to 1.7×10⁸; p = 0.77) or Pgc-1α with a mean difference of 2.2×10⁷±7.0×10⁷ (95% CI −1.7×10⁸ to 1.2×10⁸; p = 0.75) prior to MPTP treatment, indicating no significant loss of dopaminergic terminals after overexpression of either gene.

Stereological cell counts of Th+ neurons in the SN (Figures 4C, 4E and 4F) revealed an increased average number of Th+ neurons counted on the AAV2/10-mCherry expressing SN compared to the contralateral SN in saline-treated animals (Figure 4E). From an average 4978 Th+ cells per SN to an average 6323 Th+ cells per SN, a mean difference of 1345 Th+ cells (95% CI 93.9 to 2595; p = 0.038). In contrast, Pgc-1α overexpression did not affect the number of Th+ cells in the SN of saline-treated animals. The mean number of Th+ cells was comparable between the contralateral side (4124 Th+ cells) and the Pgc-1α overexpressing side (4170 Th+ cells; 95% CI −1820 to 1795; p = 1.0). However, as ascertained from total cell counts, Pgc-1α overexpression caused a significant decrease in Th+ cell survival following MPTP treatment (Figure 4F), from a mean 3057 Th+ cells on the contralateral side to 1975 Th+ cells on the Pgc-1α overexpressing side, a mean difference of 1082 TH+ cells (95% CI 117 to 2047; p = 0.03). In addition, we found that Pgc-1α overexpression did not significantly alter the number of thionin+/Th- neurons (628 contralateral, 521 ipsilateral, mean difference 108; 95% CI −294.1 to 509.5; p = 0.56). Therefore, the significant difference in mean total cell counts between the contralateral SN (3686 neurons) and the Pgc-1α overexpressing SN (2496 neurons, mean difference 1190; 95% CI 232.8 to 2146; p = 0.02) after MPTP treatment was attributed predominantly to increased Th+ cell death in response to MPTP treatment. This increased loss of Th+ cells was not observed in mCherry microinjected SNs after MPTP.

Loss of Th at the protein level after Pgc-1α overexpression was confirmed by western blot using whole-cell lysates derived from gross dissected SN tissue samples (Figure 4G). By this measure mean Th levels were reduced by 57.5% following Pgc-1α overexpression in the SN ipsilateral to the injection compared to the contralateral side in the saline treated animals, a difference of 0.9054 AU (95% CI 0.487 to 1.324; p = 0.03) and by 76.8% in the MPTP treated mice, a difference of 0.935 AU (95% CI 0.432 to 1.44; p = 0.005; data not shown). In contrast, no reduction in Th protein levels was observed by western blot using whole-cell lysates derived from gross dissected ipsilateral SN tissue samples from mCherry overexpressors compared to the contralateral side. A similar pattern of results was also seen for striatal samples (Figure 4G). Quantitative SYBR-green PCR was performed using gene-specific primers and cDNA derived from gross dissected microinjected-SN and contralateral SN tissue (data not shown). Relative mean expression of Th was reduced to 0.125 (95% CI 0.124 to 0.238; p = <0.0001; n = 6), Dat was reduced to 0.08 (95% CI 0.02 to 0.142; p = <0.0001; n = 5) and Vmat was reduced to 0.146 (95% CI 0.056 to 0.237; p = <0.0001; n = 5) in Pgc-1a overexpressing SN tissue compared to a defined mean of 1 for the contralateral SN.

These markers of the dopaminergic phenotype were also reduced in the SN when the mean fold-change in gene expression (again, calculated for the side ipsilateral to microinjection relative to the contralateral) for Pgc-1α overexpressing mice was compared to that for mCherry overexpressing mice (Figure 5A). Again, the effects were striking; Th expression was reduced after Pgc-1α overexpression to a mean level of 0.125±0.004 compared to 0.76±0.113 after mCherry, a mean difference of 0.6±0.13 (95% CI 0.34 to 0.93; p = 0.0008). Dat expression was reduced to 0.08±0.02 after Pgc-1α overexpression compared to 0.94±0.22 after mCherry overexpression a difference of 0.86±0.24 (95% CI 0.31 to 1.413; p = 0.006). Vmat2 expression was also reduced from 0.92±0.2 after mCherry overexpression to 0.146±0.03 after Pgc-1α expression a difference of 0.775±0.25 (95% CI 0.21 to 1.3; p = 0.013).

To ascertain possible reasons for increased sensitivity to MPTP-induced reduction in Th+ cells in the Pgc-1α over-expressing SN of MPTP-treated mice, SYBR-green quantitative PCR was performed using the SNs of Pgc-1α-microinjected animals to determine the mRNA level of the growth factors Gdnf and Bdnf (Figure 5B). Although the level of Gdnf was unchanged between the contralateral and Pgc-1α-microinjected SN, Bdnf mRNA levels were significantly decreased in the Pgc-1α overexpressing SNs compared to the contralateral striatum in the saline-treated condition by a mean difference of 0.51 (95% CI 0.29 to 0.74; p = 0.002), and when comparing the mean side-to-side differences for the Pgc-1α versus mCherry groups where the mean of the differences was 0.77±0.24 (95% CI 0.24 to 1.3; p = 0.009). The Pgc-1α dependent decrease in Bdnf expression in the Pgc-1α overexpressing SN versus the contralateral SN is not apparent after MPTP treatment (data not shown), which may represent upregulation of Bdnf after MPTP treatment or, preferential loss of the cells with lower levels of Bdnf expression on the Pgc-1α overexpressing side.

Th, Dat, Vmat2 and Bdnf are all downstream of the transcription factor Pitx3, whereas GDNF is upstream [42]. Pitx3 can also work in concert with another transcription factor, Nurr1, to facilitate expression of the dopaminergic phenotype [43]. SYBR-green quantitative PCR revealed that over-expression of Pgc-1α resulted in a significant down-regulation of Pitx3 to 0.25±0.11 from a 0.79±0.08 level of expression after mCherry (Figure 5C, 95% CI 0.23 to 0.85; p = 0.003), a nonsignificant trend toward lower Nurr1 expression (0.47±0.14 from 0.93±0.18, a difference of 0.46±0.24; 95% CI −0.08 to 1.0; p = 0.08), and no loss of Lmx1b expression relative to mCherry microinjected SN (1.26±0.33 from 1.1±0.23, a difference of −0.17±0.39; 95% CI −1.07 to 0.73; p = 0.677). Other transcription factors and co-activators (Atf4, Mta-1 and Dj-1) were not affected (data not shown), indicating that the effect of Pgc-1α on Pitx3 does not reflect a nonspecific global suppression of transcription. We also confirmed a loss of Pitx3 at the protein level (Figure 5D). Consistent with some crossing over of Pgc-1α protein, and loss of Th, Vmat2 and Dat mRNA expression in the contralateral SN (Figure 1E), this loss of Pitx3 protein was observed to a lesser extent in the contralateral SN in addition to the Pgc-1α overexpressing SN. Given the large loss of Pitx3 at the protein level, it may be expected that we would see effects on Pitx3 target-gene expression in the contralateral SN. Post-hoc analysis of dopaminergic marker gene expression data from the contralateral (uninjected) SN, demonstrated that Pitx3 target genes (Th, Dat and Vmat2) were indeed downregulated at the mRNA level in the contralateral SN of Pgc-1α overexpressing animals compared to the contralateral SN of mCherry overexpressing animals (Figure 5E; p<0.0001 in all cases).

To determine whether the effects observed in the SN after Pgc-1α over-expression could be linked to the level of Pgc-1α over-expression, a lower titer of the Pgc-1α vector, 1×10⁹ vgc in a 1.5 µl volume, was microinjected into the right SN of wild-type C57BL/6CR mice (Figure 6A). This resulted in a mean 6.48-fold increase in Pgc-1α expression (95% CI 1.4 to 11.54; p = 0.02). With this lower titer injection, the impact of Pgc-1α on the expression of the subset of Pgc-1α-target genes examined was no longer detectible. This may reflect a low sensitivity for detecting small changes in gene expression levels since mRNA levels from tissue homogenate were examined, which likely includes RNA from many cells that were not transduced.

Although the effects were less pronounced, a significant 28.6% loss of Th immunoreactivity in the striatum was observed (Figure 6B) from 1.53×10⁶ AU on the contralateral side to 1.09×10⁶ on the ipsilateral side, a difference of 4.38×10⁵ AU (95% CI 2.0×10⁵ to 6.7×10⁵; p = 0.004), as was loss of DA, from an average of 162 ng/mg protein to 102 ng/mg protein a difference of 60.02 ng/mg protein (Figure 6C, 95% CI 6.034 to 114.0; p = 0.035). DA turnover in the striatum (Figure 6D) also increased from 0.18±0.01 to 0.258±0.002, an increase of 0.078 (95% CI −0.1378 to −0.018). Lesser in magnitude, but still significant effects also were seen for downregulation of Th (Figure 6E) to a mean expression level of 0.37 (95% CI 0.09 to 0.65; p = 0.003), Dat to a mean expression level of 0.51 (95% CI 0.28 to 0.71; p = 0.003), Vmat2 to a mean expression level of 0.64 (95% 0.11 to 0.62; p = 0.02) and Pitx3 to a mean expression level of 0.26 (95% CI 0.57 to 0.92; p = 0.0003) mRNA levels in the ipsilateral SN compared to the contralateral side. These data are consistent with suppression of the dopaminergic phenotype by Pgc-1α even with these lower titer injections.