Introduction
The pedunculopontine nucleus (PPN) is situated in the brainstem and was originally proposed to be an interface between the basal ganglia and the spinal cord (Garcia-Rill
1986). Considered as a part of the mesencephalic locomotor region (MLR), early experiments in decorticated rats showed that electrical stimulation of this region and its surroundings induced a motor response (Skinner et al.
1990), thus providing evidence of its descending control of locomotion. Tracer studies have shown that the PPN has descending projections that mainly innervate targets in the lower brainstem and medulla, including the nucleus reticularis pontis oralis, the gigantocellular nucleus (GiN) and the medioventral medulla, and then innervate some regions of the spinal cord (Mitani et al.
1988; Semba et al.
1990; Rye et al.
1988; Grofova and Keane
1991; Nakamura et al.
1989; Scarnati et al.
2011). These projections have been implicated in the control of gait and posture.
In addition to the descending projections, neurons of the PPN provide an extensive ascending axonal innervation of several neuronal systems across the midbrain and forebrain, including the basal ganglia. Among these, the relationship between the subthalamic nucleus and the PPN (Nomura et al.
1980; Edley and Graybiel
1983; Hammond et al.
1983) has recently attracted the attention in clinical neuroscience given the proposed roles of both structures in the pathophysiology of Parkinson’s disease (PD) and their current use as therapeutic targets for deep brain stimulation (DBS). The use of DBS in the PPN has suggested its involvement in the control of gait (Kringelbach et al.
2007; Thevathasan et al.
2012; Wilcox et al.
2011; Moro et al.
2010), even though this therapy has yielded ambiguous results (Hamani et al.
2011).
The PPN is composed of three main phenotypes of neurons, cholinergic, GABAergic and glutamatergic (Mena-Segovia et al.
2009; Wang and Morales
2009), but further subgroups have been defined on the basis of the expression of neurochemical markers (Martinez-Gonzalez et al.
2012) and electrophysiological properties (Ros et al.
2010). Along with the neuronal heterogeneity, important topographical differences define the connectivity of PPN neurons and their functionality (Martinez-Gonzalez et al.
2011). Neurons innervating motor structures are predominantly situated in the caudal part of the PPN, which raises the possibility that basal ganglia and medulla receive the same signal from PPN neurons. Alternatively, ascending and descending motor projections may be segregated, arising from different populations of PPN neurons. These possibilities entail two different scenarios, the first one consisting of a coordinated activation of upstream and downstream targets, and the second supports the idea of a differential motor output where PPN afferents, as well as local circuitry, play an important part in determining which pathway is activated.
Using anatomical methods, we characterized the connectivity of PPN neurons with two key motor structures from the ascending and descending PPN motor pathways (STN and GiN) and investigated their neurochemical composition. In addition, we used immunohistochemistry to evaluate the product of the immediate early gene, Egr-1, in control and 6-hydroxydopamine (6-OHDA)-lesioned rats to determine the regulation of PPN motor connections in the Parkinsonian state (Beckmann and Wilce
1997; Chaudhuri et al.
1997; O’Donovan et al.
1999).
Methods
Animals
All animal procedures used in this study were carried out under the authority of the Animals (Scientific Procedures) Act, 1986 (UK) and in accordance with the Society for Neuroscience policy of the use of animals in neuroscience research. Sprague-Dawley rats (200–300 g) were used for the tracer injections, 6-OHDA lesions and immunohistochemical analyses.
6-Hydroxydopamine lesions
Unilateral 6-OHDA lesions were carried out under anesthesia which was induced and maintained with isoflurane (Iso, Schering-Plough Ltd., Welwyn Garden City, UK). The animals were placed in a stereotaxic frame (David Kopf Instruments) and injected with desipramine (i.p.; 25 mg/kg in 0.9 % NaCl in dH2O; Sigma) 20 min before the 6-OHDA injections. A small craniotomy was made in the right hemisphere and 3 μl of a 6-OHDA solution (3 mg/ml of 6-OHDA hydrochloride salt; dissolved immediately before use in an ice-cold solution of 0.9 % NaCl and 0.02 % ascorbic acid in dH2O; Sigma) was injected (10 μl syringe; Hamilton 701RN; HA-763501; Jaytee Biosciences Ltd., Herne Bay, Kent, UK) into the medial forebrain bundle at the following co-ordinates: 4.5 mm posterior to Bregma, 1.3 mm lateral to Bregma and 7.9 mm ventral to the dura. Injections were carried out with the aid of a micropump at a rate of 0.5 μl/min. The syringe was left in place for 5 min before and after the injections and then slowly withdrawn.
The extent of the 6-OHDA lesion was assessed 14–15 days after the injection by challenge with a subcutaneous injection of apomorphine (0.05 mg/kg; 0.9 % NaCl, Sigma). A lesion was considered successful in animals that made 80 or more contraversive rotations in 20 min in response to the apomorphine injection. Only animals with successful lesions were subsequently used for this study. Typically 1 day after the apomorphine test, animals were injected with retrograde tracers into the STN and GiN.
Tracer injections
Fluorescently labeled red and green retrobeads (red retrobeads: 530 nm excitation and 590 nm emission wavelengths; green retrobeads IX; 460 nm excitation and 505 nm emission wavelengths; Lumafluor, Inc, Durham NC, USA) were injected into the STN or GiN, respectively, of control and 6-OHDA-lesioned animals. Anesthesia was induced using 4 % isoflurane in O2 and maintained during surgery using an average of 2 % isoflurane (Iso, Schering-Plough Ltd., Welwyn Garden City, UK). The animals were placed in a stereotaxic frame (David Kopf Instruments, Tujunga, CA, USA), a small craniotomy was made above the STN (3.7 mm posterior to Bregma, 2.6 mm lateral to Bregma and 7.6 mm ventral to the dura) and 100 nl of red retrobeads were injected in the STN (1 μl syringe, 70 mm long; SGE, World Precision Instruments, Stevenage, UK). After withdrawal of the syringe, a second small craniotomy was made above the GiN (10.5 mm posterior to Bregma, 0.9 mm lateral to Bregma and 9.5 mm ventral to the dura), into which 150 nl of green retrobeads were injected. The syringe was left in place for 5 min before and after the injections and then withdrawn.
After 2 weeks of tracer injections, the animals were perfuse-fixed at the beginning of the dark phase of the 12:12 h light/dark cycle. They were deeply anesthetized using a mixture of ketamine (30 mg/kg, i.p.; Ketaset, Willow Francis, Crawley, UK) and xylazine (3 mg/kg, i.p.; Rompun, Bayer, Germany) and intracardially perfused with 0.1 M phosphate-buffered saline (PBS) followed by 4 % paraformaldehyde (PFA) in 0.1 M phosphate buffer (PB; pH 7.4) as fixative. Brains were removed and post-fixed in the same fixative for 0.5–1.5 h at room temperature. After washing, sagittal sections (50 μm thick) of the brainstem were then cut using a vibratome (Leica Microsystems, UK), collected in six series and stored in PBS containing 0.05 % sodium azide at 4 °C.
Processing of the tissue and immunohistochemistry
Sections lateral and medial to the PPN (containing the STN and the GiN, respectively), were collected to localize the sites of the tracer injections under the fluorescent microscope. Two series of control sections were double-immunolabeled for calretinin and ChAT or calbindin and ChAT (one series of sections for each). They were washed three times in PBS, blocked for 1 h in normal donkey serum (NDS; Jackson Immunoresearch Laboratories Inc., West Grove, PA; 10 % in 0.3 % Triton X-100 in PBS) before primary antibodies against ChAT together with antibodies against calretinin or calbindin were added (ChAT raised in goat, AB144P, Millipore, Temecula, CA, 1:500 dilution; calbindin raised in mouse, CB300, Swant, Switzerland, 1:5,000 dilution; calretinin raised in rabbit, 7699/3H, Swant, Switzerland, 1:5,000 dilution, in 1 % NDS, 0.3 % Triton X-100 in PBS) and incubated overnight at 4 °C. They were then washed in PBS and the secondary antibodies were added in NDS: donkey anti-goat-AMCA, 1:100 dilution, and either donkey anti-mouse-Cy5 1:250 dilution or donkey anti-rabbit-Cy5 (Jackson Immunoresearch Laboratories Inc) 1:250 dilution in 1 % NDS, 0.3 % Triton X-100 in PBS and incubated at 4 °C overnight.
Preliminary incubations in control and 6-OHDA-lesioned animals were used to determine the most suitable transcription factor to detect changes in the PPN as a consequence of the lesion (data not shown). We incubated with antibodies raised against Fos B (sc-48, raised in goat, dilutions 1:250, 1:500; Santa Cruz Biotechnology, Inc., USA), Egr-1 (early growth response 1; sc-189, raised in rabbit, dilutions 1:2,000, 1:2,500; Santa Cruz Biotechnology, Inc) and phosphorylated cAMP response element-binding (pCREB; raised in rabbit, dilutions 1:50, 1:100, 1:200, 1:500; Cell Signaling Technology, USA). The main criteria for selection included detectable expression in the PPN and adequate signal-to-noise ratio to allow their quantification in retrogradely labeled neurons. Thus, whereas the Fos B expression was adequate, but showed low basal levels, the pCREB expression was abundant and compromised the accurate detection in the nuclei of neurons labeled with other markers. Only Egr-1 provided an optimal signal-to-noise ratio for the purpose of this study.
Sections from control and 6-OHDA-lesioned animals, with accurate tracer injections into the STN and GiN, were immunolabeled to reveal Egr-1 and ChAT. One of the six series of brain sections collected were rinsed in PBS (3 times, 10 min each) and blocked for 1 h in NDS (10 % in PBS), before adding primary antibodies (anti-Egr-1, raised in rabbit, Santa Cruz, 1:2,500; anti-ChAT, raised in goat, Millipore, 1:500; in 1 % NDS in PBS, incubated overnight at 4 °C). The following day, sections were washed in PBS then incubated overnight at 4 °C in secondary antibodies (donkey anti-rabbit-Cy5, 1:250; donkey anti-goat-AMCA, 1:100; Jackson Immunoresearch Laboratories Inc; in 1 % NDS in PBS). They were then washed 3 times in PBS, mounted on to slides with Vectashield mounting medium (Vector Laboratories Inc.) and stored in the dark at 4 °C until examined. Control reactions for all the experiments were performed by omitting each of the primary antibodies in turn, which revealed a complete absence of fluorescence for the omitted antibody.
Image acquisition
Immunofluorescent and retrogradely labeled neurons were analyzed by capturing images using a LSM-710 (CarlZeiss, Germany) confocal microscope (20 × 0.8 NA dry objective lens) with an ApoTome-structured illumination system and using Colibri LED fluorescence as illumination source, or an Axio Imager M2 microscope (Plan-Apochromat 20 ×/0.8 M27 dry objective; Carl Zeiss, Germany). Multi-channel stacks of images were taken in the Z-plane using a digital camera (Axiocam HRm or HD Cam) in combination with acquisition software Axiovision 4.8.1 (Carl Zeiss AG, Germany). Confocal microscope images were obtained using the ZEN software version 5.8 (Plan-Apochromat 40 ×/1.3 oil DIC M27 objective). The software’s default settings were used for filters: Ch1-T1 504, Ch2-T2 560 and Ch3-T3 650 and the laser wavelengths were 488 nm for green retrobeads, 543 nm for red retrobeads and 633 nm for Cy5. The brightness and contrast of the images were subsequently adjusted in Photoshop (Adobe Systems Inc., Mountain view, CA, USA).
Analysis of retrogradely labeled PPN neurons
The quantification and rostro-caudal distribution of STN- and GiN-projecting neurons that were positive for calbindin and ChAT or calretinin and ChAT were analyzed using a method based on the subdivision of the PPN into equally spaced segments, as described previously (Mena-Segovia et al.
2009). Using the center of the SNr, concentric circles at 300 μm intervals were drawn outwards to cover the entire extent of the PPN; the first two segments covered the SNr, then up to ten segments covered the PPN up to its caudal extremity (from S1 to S10). The limits of the PPN were defined by the cholinergic (ChAT-positive) neurons, with segment S1 being the most rostral and closest to the SNr and segment S10 being the most caudal.
Immunofluorescent and retrogradely labeled neurons were analyzed by capturing images of the entire PPN. Multi-channel stacks of images were taken in the
Z-plane, each separated by approximately 3 μm. For each
Z-plane level, squares of tissue were captured in the
X and
Y axes, each overlapping slightly with adjacent squares, to create an image of the whole PPN. Following the same method, low magnification images were captured (using a 5 × 0.16 NA dry objective) to include the entire PPN as well as the SNr. Using the center of the SNr as a reference point, concentric circles (330 μm apart) were drawn to delimit segments of the PPN (see Martinez-Gonzalez et al.
2012; Mena-Segovia et al.
2009) to allow the distributions of labeled neurons to be analyzed using Image J software. The distances between concentric circles were modified from previous analyses (see Mena-Segovia et al.
2009; Martinez-Gonzalez et al.
2012) as non-dehydrated sections shrank 10–13 % less than dehydrated sections (measurements were done in each of the analyzed brains in the
Z-plane from the top to the bottom of the section, using Stereo Investigator software). This was confirmed by measurements taken between the center of the SNr and the superior cerebellar peduncle (approximately 1.9 mm lateral to Bregma; using Stereo Investigator software). In dehydrated sections, this distance was 4,125 ± 43 μm (
n = 6; Mena-Segovia et al.
2009) as opposed to 4,659.4 ± 16.8 μm in non-dehydrated sections (mean ± SEM;
n = 3).
For the evaluation of Egr-1 labeling, the analyses were performed as before but with a Zeiss fluorescent microscope attached to a Hamamatsu digital video camera and Stereo Investigator software. Z-plane stacks of images were acquired at intervals of 4 μm and the use of low magnification images to define the segments of the PPN was not necessary. Stereo Investigator software was able to define these segments, using the high magnification (20×) images, once the center of the SNr and the boundaries of the PPN were specified.
Statistics
All data are presented as mean ± SEM; Student’s t test, Rank sum Mann–Whitney and ANOVA tests were performed using Sigma Plot software version 12.0 as appropriate.
Discussion
We present here evidence of two distinct, largely non-overlapping pathways arising from the PPN that innervate different motor structures involved in different functions. We further show that these pathways are neurochemically distinct and are differentially affected in the Parkinsonian rat. Thus, PPN neurons projecting to the STN are heterogeneous, showing expression of ChAT, calbindin and calretinin, and an increased level of activity following a 6-OHDA lesion of the SNc, as suggested by the expression of Egr-1. In contrast, PPN neurons projecting to the GiN are less heterogeneous, they do not express calbindin and a larger proportion is cholinergic, but they do not show changes in the expression of Egr-1, following a 6-OHDA lesion. Our results provide a basis for understanding distinct motor pathways of the PPN and support a role of PPN neurons in the upstream changes in the basal ganglia following dopamine depletion.
The motor function of the PPN
The PPN has been traditionally considered as a part of the MLR. Early experiments showed that electrical stimulation in the region of the PPN was able to elicit locomotion (Skinner et al.
1990). The results of more recent studies using more refined techniques suggest that PPN maintains a close relationship with the MLR, and its downstream projections inhibit locomotion. Thus, through its descending projections, mediated in part by the reticulospinal neurons of the GiN, the effect of PPN activation would be the excitation of inhibitory interneurons in the spinal cord and the modulation of the excitatory output of the MLR (Takakusaki
2008; Takakusaki et al.
2004). On the other hand, the PPN is known to have close interconnectivity with many elements of the basal ganglia (Mena-Segovia et al.
2004), including the STN (Nomura et al.
1980; Edley and Graybiel
1983; Hammond et al.
1983). Activation of the STN, driven at least in part by direct cortical inputs, increases the inhibition of basal ganglia targets, mediated by its connections with the substantia nigra pars reticulata (SNr). Thus, an increased STN output would lead to an increased inhibition of the reticular targets of the SNr. In vitro experiments have shown that the overall effect of PPN activation on STN is excitation (Hammond et al.
1983). Hence, the net effect of the ascending (activation of the STN and basal ganglia output) and descending (activation of inhibitory spinal neurons) output of the PPN is likely to be motor inhibition.
Based on the above rationale, and the position of the PPN in the inhibitory output stream of the basal ganglia (i.e., SNr), a dysfunction in the PPN output is likely to aggravate the motor impairment in PD. Animal models of PD have shown some degree of change in the activity of the PPN (Nandi et al.
2002; Breit et al.
2001; Aravamuthan et al.
2008), but the nature and causes for such changes remain elusive. The neurochemical, electrophysiological, topographical and functional heterogeneity of PPN neurons (Mena-Segovia et al.
2008,
2009; Ros et al.
2010; Martinez-Gonzalez et al.
2012; Wang and Morales
2009; Boucetta and Jones
2009; Alderson et al.
2008) suggests it is impractical to attempt to understand the output of the PPN based simply on activation or inhibition. In the present paper, we endeavored to take into consideration the heterogeneity by incorporating different variables (projection targets, topography, neurochemical makers and level of activity). Our findings thus support the hypothesis that activity of different subclasses of neurons in the PPN is differentially regulated in Parkinsonian animals.
Functionally distinct motor pathways in the PPN
Our results show that a subpopulation of PPN neurons that have ascending projections to the STN are distinct from the neurons that have descending projections to the GiN (Mena-Segovia et al.
2008; Ros et al.
2010). We did not observe a distinct topographical gradient between these projections. This finding concurs with a previous report on the distribution of STN-projecting neurons (Kita and Kita
2011) and suggests that the PPN projects largely separately to these two motor structures but the projections arise from neurons that are intermingled in the same regions of the PPN. We have previously identified local synaptic contacts arising from different subclasses of cholinergic and non-cholinergic neurons within the PPN (Mena-Segovia et al.
2008; Ros et al.
2010). It is thus possible that the axon collaterals of the projection neurons in one pathway contact the projection neurons from the other pathway and vice versa. When considering the heterogeneity of afferents to the PPN that arise from diverse neuronal systems (reviewed in Martinez-Gonzalez et al.
2011), this suggests an integrative role within PPN microcircuits. In turn, the distribution of cholinergic, GABAergic and glutamatergic neurons (Mena-Segovia et al.
2009; Wang and Morales
2009; Martinez-Gonzalez et al.
2012) suggests that the rostral PPN is predominantly inhibitory (GABAergic) whereas the caudal PPN is predominantly excitatory (glutamatergic). Thus, it is likely that both motor projections (i.e., STN and GiN) are predominantly glutamatergic, and the fact that they contain a different balance of calcium-binding proteins suggests that different subtypes of glutamatergic neurons may be involved. Nevertheless, it should be noted that a GABAergic component is also present (Bevan and Bolam
1995).
To identify the neurochemical nature of the STN- and GiN-projecting neurons, we used immunohistochemistry for ChAT, calbindin and calretinin. The two calcium-binding proteins have been shown by in situ hybridization to be expressed in a large number of GABAergic and glutamatergic neurons of the PPN (Martinez-Gonzalez et al.
2012). We observed that the number of cholinergic neurons projecting to either target was greater in the caudal PPN compared to its rostral portion, suggesting that cholinergic-mediated excitation of motor structures arises largely in the caudal PPN. Interestingly, we detected more cholinergic neurons retrogradely labeled from the GiN than the STN despite the fact that the tracer deposits included a much smaller proportion of the GiN than the STN. We also detected ChAT expression in neurons projecting to both structures, which is consistent with the collateralization reported in individually labeled and reconstructed neurons (Mena-Segovia et al.
2008). About two-thirds of the double-projection neurons were identified as non-cholinergic. In contrast to the cholinergic neurons, calretinin-positive neurons were observed to project to STN and GiN, but never in the same neurons, whereas calbindin-positive neurons were only found to project to the STN. Our findings thus suggest that the output of the PPN to the STN and GiN is highly complex and heterogeneous. Given the caveats of false-negatives in retrograde labeling studies (see above), our findings suggest that sub-populations of cholinergic neurons project to either the STN or the GiN and a sub-population projects to both structures. Similarly, sub-populations of non-cholinergic neurons (presumably GABAergic and glutamatergic) project to either the STN or the GiN and sub-populations project to both structures (not previously identified). The heterogeneity is even more complex, not just because of their potentially GABAergic or glutamatergic nature, but also as consequence of the differential expression of the calcium-binding proteins. Our findings are largely consistent with our previous in vivo electrophysiological characterization of cholinergic and non-cholinergic neurons in the PPN (Mena-Segovia et al.
2008; Ros et al.
2010), although we did not detect non-cholinergic neurons protecting to both structures. Non-cholinergic neurons with descending projections were shown to have distinct electrophysiological properties to non-cholinergic neurons with ascending projections, supporting the notion of functional differences between these two pathways in normal animals (Ros et al.
2010).
The analysis of the two pathways following a 6-OHDA lesion of dopamine neurons in the SNc, showed an increase in the number of active STN-projecting neurons, as indicated by Egr-1 up-regulation. This was also most evident in double-projection neurons, suggesting that overall, PPN neurons with ascending projections (both STN-only and double-projection) show Egr-1 up-regulation. Because Egr-1 expression has been extensively associated with increased neuronal activity (for reviews see Beckmann and Wilce
1997; O’Donovan et al.
1999), we interpret these findings as an increased activation of PPN neurons with ascending projections, and consequently, an increased synaptic drive of their target structures. Although our data show no Egr-1 expression in cholinergic neurons, suggesting that they may not be affected in this animal model, we cannot rule out the existence of false negatives. The difference in the expression between the ascending and descending pathways may reflect a selective excitatory drive of STN-projecting neurons and a potential increased inhibition of GiN-projecting neurons (not detectable by the basal level of IEGs expression), in agreement with the data from other groups proposing an increased excitation (Breit et al.
2001; Orieux et al.
2000; Barroso-Chinea et al.
2011) or an increased inhibition (Nandi et al.
2002) in the Parkinsonian PPN. In this way, an imbalanced output between the two motor pathways may underlie the gait disturbances associated with PD.
In conclusion, our data provide evidence of functional differences associated with distinct neuronal subtypes in the PPN that contribute to different neuronal circuits. We and others have proposed a functional topography in the PPN associated with the afferent and efferent connectivity. Here, we show evidence of functional divergence among intermingled neurons located in the same functional domains of the PPN. Further detailed characterization of the neuronal circuits that constitute the PPN will be necessary to understand its role in behavior and its contribution to pathological processes that distinguish some neurological disorders.