Abstract
Somatostatin receptor 2 (SSTR2) mediates neuromodulatory signals of somatostatin and cortistatin in the cerebral cortex. Recently, SSTR2 has been shown to enhance conserved death ligand- and mitochondria-mediated apoptotic pathways in non-neuronal cells. Whether somatostatin receptors are activated in cerebrocortical neurons and contribute to neurodegeneration after experimental focal ischemia was unknown until now. Here we examined internalization of SSTR2 in a rat model of middle cerebral artery occlusion (MCAO) by confocal microscopy. At 3 and 6 hr after MCAO, SSTR2 was internalized excessively in cerebrocortical neurons adjacent to the infarct, which was prevented by intracerebroventricular application of the SSTR2-selective antagonist BIM-23627. SSTR2 internalization was associated with a transient depletion of somatostatin from axonal terminals and increased expression of SSTR2 mRNA. The initial loss of somatostatin was followed by an increase in somatostatin mRNA levels, whereas cortistatin mRNA expression was decreased. In SSTR2-deficient mice with lacZ under the control of the SSTR2 promoter, MCAO-induced upregulation of SSTR2 gene expression was less pronounced than in wild types. SSTR2-deficient mice exhibited a 40% reduction of infarct size after permanent distal MCAO and a 63% reduction after transient proximal MCAO. In summary, we provide direct evidence for activation of SSTR2 by an endogenous ligand after focal ischemia. Activation of functional SSTR2 receptors contributes to increased SSTR2 gene expression and postischemic neurodegeneration.
- somatostatin
- cortistatin
- sst2
- internalization
- apoptosis
- in situ hybridization
- immunohistochemistry
- neuroprotection
Introduction
All five somatostatin receptors (SSTRs) belong to the G-protein-coupled receptor family and are expressed by numerous neuronal and non-neuronal cells. SSTRs inhibit adenylate cyclase and reduce cAMP levels (Hannon et al., 2002), which are important determinants of neuronal survival in numerous culture models (Rydel and Greene, 1988; Hanson et al., 1998; Putcha et al., 1999; Piiper et al., 2002; Poser et al., 2003). In non-neuronal cells, SSTR2 has been shown to enhance death ligand- and mitochondria-mediated apoptosis (Guillermet et al., 2003), indicating that conserved signaling pathways in programmed cell death can be influenced by SSTRs. Intracerebral applications of SSTR ligands before middle cerebral artery occlusion (MCAO) affect the infarct volume in a dose-dependent manner (Rauca et al., 1999), suggesting that SSTRs may influence neurodegeneration after brain ischemia.
The endogenous peptides somatostatin and cortistatin exhibit similar affinities for the SSTRs. Because cortistatin exerts some functions that are distinct from those of somatostatin, the existence of a cortistatin-specific receptor has been proposed (Spier and de Lecea, 2000). Somatostatin and cortistatin peptides are highly expressed in the cerebral cortex. Somatostatin is localized in cortical GABAergic interneurons, some of which coexpress cortistatin (de Lecea et al., 1997). Both peptides exhibit neuromodulatory roles in the cortex by depressing the activity of pyramidal cells (Moore et al., 1988; de Lecea et al., 1996; Hicks et al., 1998; Schweitzer et al., 2003). Because SSTR2 accounts for most of the somatostatin-binding sites in the cortex (Videau et al., 2003), these neuromodulatory effects are most likely mediated by SSTR2. In addition to the cortex, MCAO also affects the striatum, where somatostatinergic GABAergic interneurons exert neuromodulatory effects on SSTR2-expressing projection neurons (Vilchis et al., 2002; Allen et al., 2003).
Biosynthesis and release of somatostatin is increased after experimental seizures (Binaschi et al., 2003), suggesting that the somatostatin system is activated during hyperexcitation of neuronal circuits. Recently, SSTR2 activation has been shown to cause homologous upregulation of SSTR2 mRNA levels (Boudin et al., 2000; Tannenbaum et al., 2001), a mechanism that may counteract desensitization of SSTR2 during sustained receptor stimulation. To our knowledge, activation of neuropeptide receptors has not been shown in models of neurodegenerative diseases. For SSTR2 in particular, little is known about its activation, regulation, and contribution to brain infarction after focal ischemia.
In the present study, postischemic internalization of SSTR2 immunoreactivity was analyzed in cortical neurons by confocal microscopy, which is an established approach to reveal ligand-induced activation of neuropeptide receptors in the nervous system (Mantyh et al., 1995). By in situ hybridization, upregulation of SSTR2 mRNA expression was detected in areas with SSTR2 internalization and, using SSTR2-deficient mice with a lacZ knock-in allele, functional SSTR2 protein was shown to contribute to SSTR2 upregulation. Finally, reduced infarct volumes in SSTR2-deficient mice in permanent and transient MCAO models provide evidence that SSTR2 enhances neurodegeneration after focal ischemia.
Materials and Methods
For all animal procedures, ethical approval was sought before the experiments according to the requirements of the German National Act on the Use of Experimental Animals.
Animal models of focal cerebral ischemia. Permanent MCAO and sham operation were performed in 6-week-old male Long-Evans rats (Mollegaard) as described previously (Culmsee et al., 1999; Stumm et al., 2001), with the modification that sodium pentobarbital was applied (40 mg/kg, i.p.) for anesthesia. Permanent and transient mouse MCAO models (Stumm et al., 2002; Katchanov et al., 2003) were performed in C57BL/6 SSTR2 knock-out lacZ knock-in mice (Allen et al., 2002) backcrossed for >10 generations to a C57BL/6 background. All experiments were conducted with knock-out and wild-type littermates obtained by heterozygous intercrossing. Infarct volumes 7 d after permanent MCAO were determined by integrating infarct areas, which were measured in 400 μm intervals in cresyl violet-stained cryostat sections using NIH Image 1.62 software. In the transient MCAO model, infarcts were determined after 3 d as described previously (Endres et al., 2000). Differences in infarct size between wild-type and SSTR2-deficient mice were analyzed in both MCAO models by a Mann-Whitney U test. Mice subjected to transient MCAO were tested for neurological deficits before they were killed and were rated on a scale from 0 (no observable deficit) to 3 (severe) (Bederson et al., 1986). Briefly, failure to extend the forepaw when suspended vertically was graded as mild injury (grade 1), circling was graded as moderate (grade 2), and loss of circling or righting reflex was graded as severe (grade 3). Animals were graded by an observer blinded to genotype.
Drug application into the lateral ventricle. Efficacy of the SSTR2 antagonist BIM-23627 (Biomeasure, Milford, MA) in vitro and in vivo has been described previously (Zatelli et al., 2001; Tulipano et al., 2002). In 12 rats (300 gm) anesthetized with sodium pentobarbital (40 mg/kg, i.p.), the skull was exposed and trepanated (1 mm diameter; stereotaxic coordinates, 0.25 mm posterior and 1.6 mm lateral to bregma). One week after surgery, animals were again anesthetized and mounted in a stereotaxic frame. A needle was inserted through the trepanation site to a depth of 4 mm, and 5 μl of saline or 5 μl of saline containing 0.5 nmol/μl BIM-23627 was applied. The needle was left in place for an additional 2 min and then retracted. MCAO and sham operation were performed 30 min after delivery of the drug or saline (n = 3).
In situ hybridization. Generation of [35S]-labeled and digoxigenin-labeled riboprobes, hybridization and washing procedures, as well as detection of hybridization signals were performed according to standard protocols (Stumm et al., 2002). Template rat cDNAs used to transcribe probes for somatostatin, parvalbumin, vesicular glutamate transporter 1 (VGLUT1), and glutamic acid decarboxylase (GAD) (Mr 67,000) have been described recently (Stumm et al., 2004). A rat cortistatin cDNA (GI:6978682; nucleotides 4-286), a rat heat shock protein 70 (HSP70) cDNA (GI:294567; nucleotides 493-696), and a mouse SSTR2 cDNA (GI:54197; nucleotides 611-1510) were isolated from brain RNA by reverse transcription-PCR and cloned into the pGEM-Teasy vector (Promega, Madison, WI) for transcription. Probes for rat SSTRs were generated using previously described cDNAs (Kreienkamp et al., 1997) that correspond to nucleotides 1-2752 of SSTR1 (GI:6981583), nucleotides 368-1477 of SSTR2 (GI:207026), nucleotides 657-1716 of SSTR3 (GI: 34866768), nucleotides 59-1303 of SSTR4 (GI:40254790), and nucleotides 154-1381 of SSTR5 (GI:6981587). Nucleotides 1123-1954 of a lacZ cDNA (GI:41901) were cloned into EcoRV/SacI sites of pBluescript KS(+) (Stratagene, La Jolla, CA) for transcription.
Image analysis. Densitometric analysis of hybridization signals and cell counts were conducted as described previously (Stumm et al., 2001) using NIH Image 1.62. For densitometry, sections of an experimental group, the respective control group, and a [14C] standard (ARC-146; Biotrend Chemicals, Köln, Germany) were exposed to the same x-ray film, and the autoradiograms were digitized. Calibration was performed by plotting the density measurements of the [14C] standard against the given tissue radioactivity equivalents (nanoCuries per gram of tissue). Then, the integrated optical density was determined in selected brain regions by averaging measurements from three sections per individual. Measurements were performed for the SSTRs and somatostatin in rats 6 hr, 1 d, 2 d, and 4 d after MCAO (n = 6) and in stage-matched sham-operated groups (n = 4). Corresponding groups were compared by a non-paired, two-way Student's t test. For cortistatin, naive rats (n = 3) were added to the above experimental groups, and a one-way ANOVA with Newman-Keuls multiple comparison test was performed. To determine the numbers of the neurons expressing SSTR2, cortistatin, and somatostatin mRNA in a given area, the hybridized sections were coated with NTB2 emulsion (Eastman Kodak, Rochester, NY) and photographed under dark-field illumination with an Axioskop microscope (Zeiss, Oberkochen, Germany) equipped with a digital camera (SV MICRO; Electroimage, Great Neck, NY). Cell counts for each individual were averaged from three specimens. MCAO-treated and control groups were compared by Student's t test. In SSTR2-deficient and wild-type mice (n = 8 each), the HSP70 mRNA-positive area, 6 hr after permanent MCAO, was determined in x-ray autoradiograms by setting a threshold level that excluded areas with low-signal intensities. Comparison of the two groups was performed using a Mann-Whitney U test. Levels of SSTR2 mRNA in wild-type mice (n = 11) and lacZ mRNA in SSTR2-deficient mice (n = 14) were determined ipsilaterally and contralaterally 6 hr after MCAO by densitometry. Ipsilateral and contralateral values were compared by a Wilcoxon signed rank test. Then, the fold upregulation was calculated for SSTR2 and lacZ as ipsilateral versus contralateral change, and comparison of both groups was performed by a Mann-Whitney U test.
For cortistatin and parvalbumin mRNAs as well as cortistatin and somatostatin mRNAs, semiquantitative proportional analysis of coexpression was performed in the cingulate and frontal cortical areas by counting single- and double-labeled neurons in four rats 2 d after MCAO and in three naive rats. Coexpression of SSTR2 and GAD mRNAs as well as SSTR2 and VGLUT1 mRNAs was analyzed in the same way in layers 2/3 and 5/6 of the forelimb cortical area in four sham-operated and four MCAO-treated rats after 6 hr.
Immunohistochemistry. Immunohistochemistry for SSTR2a and somatostatin was performed in naive rats (n = 3); 3 hr, 6 hr, 1 d, 2 d, and 4 d after MCAO (n = 5); as well as after sham operation at each time point (n = 3), using the affinity-purified anti-SSTR2a antibody [6291] at 1 μg/ml as described previously (Schulz et al., 1998; Allen et al., 2002) and the monoclonal SOM-14 antibody (Biomeda) at a dilution of 1:50. For immunohistochemical controls, brains of SSTR2-deficient mice were shown to be SSTR2a immunonegative. In addition, primary antibodies were omitted (SOM-14; [6291]), replaced by preimmune sera, or absorbed with several concentrations (ranging from 1 to 10 μg/ml) of homologous or heterologous peptides for 2 hr at room temperature [6291]. Specimens were examined using a TCS-NT laser scanning confocal microscope (Leica, Heidelberg, Germany) equipped with a krypton-argon laser. Cy3 was imaged with a 568 nm excitation and 570-630 nm bandpass emission filter. To analyze internalization of SSTR2a, a 100× objective was used. Neuronal cell bodies in the cerebral cortex that did not contain internalized SSTR2a showed faint SSTR2a-like immunoreactivity (SSTR2a-LIR) on the cell surface and neuropil (Csaba et al., 2001). In neurons with internalized SSTR2, the cytoplasm contained 5-10 bright, immunofluorescent structures (weak internalization) or was filled with confluent SSTR2a-LIR (strong internalization).
Immunocytochemistry. Human embryonic kidney (HEK) 293 cells stably transfected with T7-tagged SSTR2a (Pfeiffer et al., 2002) were grown overnight on poly-l-lysine-treated coverslips. Somatostatin-14 (100 nm), BIM-23627 (1 μm), or both compounds were applied for 30 min. Cells were fixed, washed, stained with 1 μg/ml affinity-purified serum [6291], and detected as described previously (Stumm et al., 2002). For quantitative analysis of internalization, an established ELISA was used (Pfeiffer et al., 2002). The transfected cells were preincubated with 1 μg of affinity-purified rabbit anti-T7 antibody for 2 hr in OPTIMEM (Invitrogen, San Diego, CA) at 4°C. Then, they were treated with 100 nm somatostatin-14, 1 μm BIM-23627, or both compounds for 1 hr, fixed, and incubated with peroxidase-conjugated anti-rabbit antibody (1:1000; Amersham Biosciences, Braunschweig, Germany) for 2 hr at room temperature. After washing, the plates were developed with 250 μl of 2,2′-azino-di-[3-ethylbenzthiazoline sulfonate] solution (Roche, Penzberg, Germany). After 30 min, 200 μl of the substrate solution from each well was transferred to a 96-well plate and analyzed at 405 nm using a microplate reader (Bio-Rad, Munich, Germany).
Results
Internalization of SSTR2a by endogenous ligands after MCAO
To test whether SSTR2a is activated by endogenously released ligands after focal ischemia, we characterized the spatial and temporal patterns of SSTR2a internalization in a rat model of permanent distal MCAO. In controls, which comprised brains of naive and sham-operated rats as well as the contralateral hemisphere of ischemic rats, SSTR2a-LIR diffusely labeled the neuropil in the infragranular layers V and VI of the cingulate, frontal, and parietal cerebrocortical subregions (Fig. 1A,D) (contralateral hemisphere 6 hr after MCAO). High-power analysis showed that the cytoplasm of neuronal perikarya in infragranular layers (Fig. 1F) and dendrites in supragranular layers (Fig. 1H) were either spared from or slightly decorated with SSTR2a-LIR. The observed pattern of SSTR2a-LIR in the forebrain of controls matched exactly previous reports (Csaba et al., 2001), and SSTR2a-LIR in ischemic and control brains was fully absorbed by preincubation with the immunizing peptide (Fig. 1B). At 3 and 6 hr after focal ischemia, profound internalization of SSTR2a-LIR was seen in cerebrocortical tissues adjacent to the primary infarct dorsally and ventrally. For simplicity, the perifocal cortical areas (Fig. 1A, arrowheads) will now be referred to as ventral and dorsal penumbra. In the dorsal penumbra, internalization of SSTR2a was seen frequently in perikarya in infragranular layers (Fig. 1C,E) (6 hr after MCAO) and occasionally in supragranular layers. The strongly internalizing neurons showed confluent SSTR2-LIR in the cytoplasm of the cell bodies. SSTR2a-like immunoreactive dendrites, which were sparsely labeled in controls (Fig. 1D,H), exhibited an accumulation of internalized SSTR2a-LIR after focal ischemia (Fig. 1C,G) and could be easily traced from infragranular to supragranular layers. Also in the ventral penumbra, striking internalization of SSTR2a-LIR was seen both at 3 hr (Fig. 1I,I′--K,K′) and 6 hr after MCAO (see below). Outside the penumbra, an increase in internalized SSTR2a-LIR was seen ipsilaterally in the nonlesioned cingulate and frontal cortical areas at 3 and 6 hr after MCAO. The internalized SSTR2a-LIR typically formed several intracellular clusters but was not confluent (data not shown), suggesting that the amount of internalized SSTR2a-LIR per cell was less in nonlesioned areas than in the penumbra. An increase in internalized SSTR2a-LIR was not observed in the hemisphere contralateral to MCAO compared with the naive specimen. At the late stages (2 and 4 d after MCAO), an increase in internalized SSTR2a-LIR was observed neither ipsilaterally nor contralaterally.
In addition to internalization, our immunohistochemical analysis revealed an increase in SSTR2a-like labeling in the neuropil in distinct ipsilateral brain regions after 6 hr. In ipsilateral versus contralateral comparison (Fig. 1A), these comprised the cingulate, frontal, insular, and piriform areas of the cortex (arrows), claustrum (Cl), and dorsal endopiriform nucleus (DEn).
The SSTR2 antagonist BIM-23627 blocks SSTR2a internalization in vitro and in vivo
To substantiate that SSTR2 was internalized by endogenously released ligands, we next attempted to block this process pharmacologically. The SSTR2-selective antagonist BIM-23627 proved to be a suitable compound to block ligand-induced SSTR2 internalization in HEK293 cells stably expressing SSTR2a (Fig. 2A-D). Quantitatively, internalization of SSTR2a-LIR by 0.1 μm somatostatin-14 was reduced from 58% to 15% by coapplication of 1 μm BIM-23627 (Fig. 2E) (p < 0.05). When BIM-23627 was applied at 1 μm without somatostatin-14, it did not affect the subcellular distribution of SSTR2a (Fig. 2D,E). Next, 2.5 nmol of the compound or vehicle was injected into the ventricle 30 min before MCAO and sham operation. Analysis was performed in the ventral cortical penumbra (piriform cortex) 3 hr after the operation. In this area, SSTR2a-LIR strongly decorated the plasma membrane and, to a weaker extent, the cytoplasm of neurons in naive rats, sham-operated rats receiving BIM-23627 or vehicle, and contralaterally in ischemic rats receiving BIM-23627 or vehicle (Fig. 1J,J′) (shown for the latter group). Thus, BIM-23627 had no effect on the subcellular distribution of SSTR2a under normal conditions. After ischemia, however, internalization of SSTR2a in the ipsilateral hemisphere, as seen after vehicle treatment (Fig. 1I,I′), was absent after BIM-23627 treatment (Fig. 1K,K′).
Depletion of somatostatin from axonal terminals
Given the evidence for activation of SSTR2a by endogenous ligands after focal ischemia, we assessed postischemic changes of the somatostatin content in terminals by immunohistochemistry (Fig. 3). Somatostatin-LIR in terminals was strongly decreased ipsilaterally in the entire cortex, claustrum, and dorsal endopirifom nucleus at 3 hr, 6 hr, and 1 d after MCAO (shown in detail for the cortex at 6 hr as ipsilateral versus contralateral comparison) (Fig. 3B,C). During this time, somatostatin-LIR was unchanged in the ipsilateral striatum and septal area (Fig. 3A), as well as contralaterally (compared with naive animals; data not shown). Thus, the spatial pattern of the depletion of somatostatin from axonal terminals during the first 24 hr after MCAO mimicked that of SSTR2a internalization. After 2 and 4 d, somatostatin-LIR was similar to naive rats in all noninfarcted areas, and a slight increase was observed ipsilaterally in the cortex (data not shown), suggesting that absence of somatostatin-LIR from terminals in this area during the first 24 hr after MCAO was not attributable to degeneration of axons.
Differential regulation of somatostatin and cortistatin mRNA expression after focal ischemia
To determine whether ischemia-induced changes of somatostatin-LIR were related to alterations in somatostatin gene expression, levels of somatostatin mRNA were quantified at 6 hr, 1 d, 2 d, and 4 d after MCAO and sham operation by in situ hybridization ipsilaterally and contralaterally in the noninfarcted brain regions identified in Figure 4P, as well as in the dorsal and ventral penumbra (Fig. 4G, arrows). Areas exhibiting significant changes compared with the stage-matched, sham-operated groups are marked by asterisks in Figure 4. Significant increases (p < 0.05) in somatostatin mRNA expression were found ipsilaterally in the cortex after 2 d (+71 ± 32%) and 4 d (+61 ± 33%) as well as in the dorsal striatum after 2 d (+50 ± 32%) and 4 d (+59 ± 38%). Expression of somatostatin mRNA was unchanged in all noninfarcted areas after 6 hr and at 1 d. Thus, the loss of somatostatin from cortical axonal terminals 3 hr to 1 d after MCAO was associated with increased somatostatin mRNA levels after 2 and 4 d, possibly reflecting a reactive increase in the synthesis of the peptide.
Cortistatin is the second endogenous ligand at the SSTRs and is expressed selectively in the cerebral cortex. Surprisingly, cortistatin mRNA levels exhibited a strong and sustained decrease in both cortical hemispheres after MCAO (Fig. 5, asterisks), with the maximal change in nonlesioned areas occurring in the cingulate/frontal cortex after 2 d. Because sham operation provoked changes in cortistatin expression, a group of naive rats was used as reference to quantify changes in the sham-operated and ischemic groups (Table 1). The downregulation of cortistatin expression was further confirmed by cell counts in the ipsilateral cingulate/frontal cortical area, which revealed a decrease in the number of cortistatin mRNA-positive neurons per millimeters squared by 73% (p < 0.01) (Fig. 6A,D).
Cortistatin is known to be synthesized by somatostatin-expressing and parvalbumin-expressing cortical GABAergic neurons (de Lecea et al., 1997). Because these types comprise two nonoverlapping populations with distinct intracortical connectivity (for review, see Kawaguchi and Kondo, 2002), the effects of cortistatin derived from parvalbumin-positive and somatostatin-positive circuits are likely to affect different targets. To test whether cortistatin mRNA levels were differentially regulated in the two neuronal types, digoxigenin-labeled probes for parvalbumin and somatostatin were each cohybridized with a 35S-labeled probe for cortistatin (Fig. 6B,C,E,F), and coexpression analysis was performed ipsilaterally in the cingulate/frontal cortex 2 d after MCAO compared with naive animals. In controls, cortistatin mRNA was frequently detected in the two neuronal types (Fig. 6B,C, arrows). After MCAO, cortistatin expression was virtually absent from the parvalbumin-expressing population (Fig. 6E, arrowheads) and restricted to the somatostatin-expressing population (Fig. 6F, arrows), whereas numbers of parvalbumin- and somatostatin-expressing neurons per area were unaltered. The observation that cortistatin was downregulated in parvalbumin-expressing neurons was further substantiated by semiquantitative analyses, in which marker-positive cells, cortistatin-positive cells, and marker/cortistatin-positive cells were counted and the relative proportions were calculated (Fig. 6G,H). Together, the analyses of somatostatin and cortistatin mRNA expression showed that the levels of the two mRNAs were oppositely regulated during the late stages after focal ischemia (1-4 d), which was attributable to massive downregulation of cortistatin in nonsomatostatinergic neurons.
Upregulation of SSTR2 mRNA expression in the cortical penumbra
Because activation and internalization of SSTR2 has been reported to increase SSTR2 mRNA expression in cortical slices (Boudin et al., 2000), we next determined changes in SSTR2 mRNA levels (regions of interest corresponded to those for somatostatin) (Fig. 4P). All changes in SSTR2 mRNA expression were essentially confined to the ipsilateral side (Fig. 4G-J, highlighted area). After 6 hr, SSTR2 mRNA levels in the cortex were increased in the dorsal penumbra (+106 ± 42%; p < 0.01), ventral penumbra (+178 ± 22%; p < 0.01), and cingulate/frontal area (+37 ± 23%; p < 0.05). In addition, SSTR2 mRNA expression was increased in the ventral striatum after 6 hr (+263 ± 158%; p < 0.05) and 1 d (+395 ± 97%; p < 0.01) as well as in the dorsal striatum after 1 d (+199 ± 116%; p < 0.05). Thus, cortical regions with internalized SSTR2a-LIR exhibited increased SSTR2 mRNA levels 6 hr after MCAO.
Unchanged mRNA expression of SSTR1, SSTR4, and SSTR5 in the penumbra
To test whether the observed regulation was selective for SSTR2, changes in mRNA levels of SSTR1, SSTR4, and SSTR5 were analyzed. SSTR1 mRNA was abundantly expressed in the cortex, but the levels were unchanged in nonlesioned areas (Fig. 4A-E). Expression levels of SSTR4 mRNA were decreased contralaterally in the parietal cortex after 6 hr (-29 ± 18%; p < 0.05) and increased ipsilaterally in the cingulate/frontal cortex after 1 d (+73 ± 49%; p < 0.05) (Fig. 4L,M, asterisks). Two animals showed a strong increase in SSTR4 mRNA levels in the ipsilateral striatum after 1 d (Fig. 4M). Striatal SSTR4 mRNA levels of the entire group, however, were not statistically different when compared with the respective sham-operated group. Levels of SSTR5 mRNA were below the detection limit in the cortex and striatum (data not shown). Thus, upregulated mRNA expression in the cortical penumbra during the first 6 hr after focal ischemia was selective for the SSTR2 gene and not observed for the SSTR1, SSTR4, and SSTR5 genes.
Induction of SSTR2 in penumbral pyramidal cells
The induction of SSTR2 mRNA expression in the dorsal cortical penumbra (dorsomedial forelimb area) after 6 hr was then analyzed in detail (Fig. 7). Cell counts in this area showed that the number of SSTR2 mRNA-positive cells per millimeters squared were increased by 420% in supragranular layers (p < 0.01) and by 190% in infragranular layers (p < 0.05) compared with the corresponding area of sham-operated rats (Fig. 7A-D), indicating that expression of the SSTR2 gene was induced in a substantial proportion of penumbral cells. To further characterize the transmitter types of SSTR2-expressing neurons in the penumbra and normal cortex, coexpression analyses were performed. Digoxigenin-labeled probes for GAD67 mRNA and VGLUT1 mRNA, which identify GABAergic neurons and glutamatergic pyramidal cells, respectively, were used. Together, these two neuronal populations comprise the preponderant part of cortical neurons. The probes for the marker mRNAs were each cohybridized with the probe for SSTR2 mRNA in sections from rats 6 hr after sham operation and MCAO (Fig. 7E-H). For both combinations of probes, marker-positive cells, SSTR2-positive cells, and marker/SSTR2-positive cells were counted, and the proportions of the three populations from all counted cells were calculated (Fig. 7I,J). Because SSTR2 expression differs strongly between infragranular and supragranular layers (Fig. 7C), segregated analyses were performed for layers 2/3 and 5/6. After sham treatment, SSTR2/GAD-expressing neurons formed a small population, both in layers 2/3 and 5/6 (Fig. 7I). SSTR2/VGLUT1-positive neurons constituted only a very small population in layers 2/3 but the predominant population in layers 5/6 (Fig. 7J). These patterns suggest that in the cortex of the controls, SSTR2 mRNA was expressed at high levels by the majority of pyramidal cells in layers 5/6, sparsely by layer 2/3 pyramidal cells, and at high levels by few GABAergic neurons in layers 2-6. After ischemia, the proportion of SSTR2/VGLUT1-positive neurons increased strongly both in layers 2/3 and 5/6 (Fig. 7J). Correspondingly, the proportion of SSTR2-positive/GAD-negative neurons increased, and the proportion of SSTR2-positive/GAD-positive neurons decreased (Fig. 7I). This proportional shift showed that SSTR2 mRNA expression was upregulated in almost all pyramidal cells in the penumbra. In contrast, SSTR2 mRNA was detected only in a small population of GABAergic inhibitory neurons, both after sham treatment and ischemia.
Functional SSTR2 receptors contribute to the upregulation of SSTR2 mRNA
Given the close spatial and temporal correlation between SSTR2 activation and SSTR2 mRNA upregulation, we hypothesized that an SSTR2-mediated signal may contribute to the enhanced SSTR2 mRNA expression after focal ischemia. A similar mechanism has been proposed previously to counteract ligand-induced downregulation of SSTR2 after application of agonist to brain slices (Boudin et al., 2000). To test this hypothesis, wild-type mice and mutant mice with a sstr2 knock-out/lacZ knock-in were subjected to 6 hr MCAO. SSTR2 gene expression was then visualized by hybridization with a probe for SSTR2 mRNA in the wild types and a probe for lacZ mRNA in the mutants. Ipsilateral versus contralateral comparison of mRNA levels in wild types and mutants revealed strongly increased SSTR2 and moderately increased lacZ mRNA expression in the dorsal and ventral cortical penumbra (Fig. 8D,E, arrows). Quantitative analysis in the ventral penumbra and comparison with the corresponding contralateral area (Fig. 8A,B) showed a 2.7-fold upregulation of SSTR2 mRNA in the wild types (p < 0.01) and a 1.5-fold upregulation of lacZ mRNA in the mutants (p < 0.01). Thus, an SSTR2-derived signal was not required for enhanced SSTR2 gene expression. However, SSTR2 mRNA upregulation was significantly larger than lacZ mRNA upregulation (p < 0.01), suggesting that an SSTR2-derived signal might contribute to enhanced SSTR2 gene expression after MCAO.
Reduced infarct size in SSTR2-deficient mice in models of transient and permanent focal ischemia
To address whether the endogenous somatostatin system might protect from or contribute to the infarction process via SSTR2, infarct volumes in SSTR2-deficient mutants and wild types were compared in models of transient and permanent MCAO (Fig. 9A,B). In both models, the infarcts were significantly smaller in the mutant mice than in the wild types. At 7 d after permanent MCAO, the infarct volume was reduced by 40% (p < 0.01). After transient MCAO, a 63% reduction of the infarct volume was found after 3 d (p < 0.05). The animals exhibited a neurological deficit score of ≥2 (i.e., moderate or severe deficit) 30 min after the onset of ischemia. At 3 d, the deficits were improved in the SSTR2-deficient group compared with wild type (Table 2).
If excessive activation of SSTR2 in perifocal regions hours after MCAO contributes to infarct expansion, early markers of neuronal damage are expected to be differentially activated in SSTR2-deficient mice and wild-type mice. Previously, perifocal regions expressing HSP70 mRNA during the first hours after MCAO have been shown to correspond to the penumbral region undergoing degeneration until the lesion gained its full size (Hata et al., 2000). As determined by in situ hybridization 6 hr after permanent MCAO, the HSP70 mRNA-positive area was reduced by 45% (p < 0.01) in SSTR2-deficient mice compared with wild-type mice. Thus, SSTR2-deficient mice exhibited smaller mature infarcts and smaller HSP70-positive penumbral regions after MCAO.
Discussion
Here we provide the first evidence for a role of the endogenous somatostatin system in focal cerebral ischemia. We show internalization and upregulation of SSTR2 hours after MCAO in perifocal pyramidal neurons. Using SSTR2-deficient mice with lacZ expression under the control of the SSTR2 promoter, functional SSTR2 signaling was shown to contribute to ischemia-induced upregulation of SSTR2. In two distinct models of cerebral ischemia, SSTR2-deficient mice exhibited smaller infarct volumes than wild-type mice, strongly suggesting the involvement of SSTR2 in neurodegeneration under ischemic conditions. In addition, we show strong downregulation of cortistatin expression in exofocal cortical GABAergic neurons days after MCAO.
Activation and upregulation of SSTR2 in the cerebral cortex after focal ischemia
Previous studies established SSTR2 internalization in cortical neurons in vivo as an indicator for SSTR2 activation after intracortical application of SSTR2 ligand (Csaba et al., 2001). This study provides the first evidence for in vivo internalization of SSTR2 by endogenous ligands and shows that SSTR2 internalization can be blocked pharmacologically by intracerebral application of an SSTR2 antagonist. The close association of SSTR2 internalization and SSTR2 mRNA upregulation in cortical regions suggests an involvement of an SSTR2-dependent signal in SSTR2 upregulation. SSTR2 activation is known to trigger upregulation of SSTR2 mRNA expression in tumor cells in vitro (Bruno et al., 1994; Hukovic et al., 1996) and in vivo (Froidevaux et al., 1999). Recently, intravenous application of SSTR2-preferring ligands has been shown to be associated with increased SSTR2 mRNA levels in the arcuate nucleus, which is accessible for systemically administered drugs (Tannenbaum et al., 2001). In brain slices, SSTR2 activation induces SSTR2 mRNA upregulation by a mechanism that involves SSTR2 internalization (Boudin et al., 2000). The assumption that an SSTR2-dependent mechanism contributes to ischemia-induced upregulation of SSTR2 gene expression is further supported by our finding that, in mice expressing lacZ instead of SSTR2, upregulation of SSTR2 gene expression was reduced. Notably, the observation that lacZ mRNA levels were increased in SSTR2-deficient mice after ischemia provides evidence for additional SSTR2-independent mechanisms. Thus, SSTR2-dependent and SSTR2-independent signals contribute to postischemic upregulation of SSTR2 expression that may represent a regulatory mechanism to compensate for SSTR2 desensitization. Although activation of SSTR2 is apparently linked to enhanced SSTR2 expression, sustained downregulation of cortistatin was not associated with changes in SSTR expression. Our comparative expression analysis of the five SSTRs showed further that upregulation in perilesional areas during the first hours after MCAO was selective for SSTR2 and points to a particular relevance of this SSTR subtype in the pathobiology of cerebral ischemia.
Involvement of the endogenous somatostatin system in post-stroke neurodegeneration
Internalization of SSTR2 in ipsilateral perifocal and exofocal cortical regions hours after MCAO was paralleled by depletion of somatostatin from axonal terminals, suggesting excessive release of the peptide. In perifocal regions, reduced protein synthesis (Christensen et al., 1996) may contribute to the observed depletion of axonal somatostatin. SSTR2 expression was detected in the vast majority of perifocal neurons that are at risk to die. Smaller mature infarcts in SSTR2-deficient mice suggest that activation of SSTR2 in perifocal neurons contributes to neurodegeneration under ischemic conditions. The reduced final infarct size corresponded to a smaller perifocal HSP70-positive area in the mutants 6 hr after MCAO. Because HSP70 is an established marker of neuronal stress, this finding supports the assumption that rapid activation of SSTR2 in the penumbra contributes to infarct growth. Along with the reduction in infarct size, we observed a significant improvement in neurological sensory-motor scores, which supports the notion that lack of SSTR2 had functional consequences in post-stroke neurodegeneration.
The MCAO models we applied are different with respect to the infarcted brain regions. Although permanent occlusion of the distal middle cerebral artery causes neurodegeneration in the cerebral cortex, transient occlusion of the proximal middle cerebral artery affects the striatum and cortex (Welsh et al., 1987; Katchanov et al., 2003). In both brain regions, somatostatin is contained in local circuits and acts on SSTR2-expressing projection neurons (Hicks et al., 1998; Vilchis et al., 2002; Allen et al., 2003).
Which SSTR2-activated pathways may contribute to neurodegeneration under ischemic conditions? Elevated cAMP levels are important survival and differentiation signals in cultured neurons (Rydel and Greene, 1988; Tanaka et al., 1997; Hanson et al., 1998; Putcha et al., 1999; Piiper et al., 2002; Vaudry et al., 2002). The Gs-coupled EP2 E-prostanoid receptor reduces neuronal death in cultured neurons subjected to oxygen glucose deprivation in a cAMP-dependent manner and is protective in focal cerebral ischemia (McCullough et al., 2004). Conversely, Gi-coupled SSTR2 may interfere with neuronal survival in the penumbra by reducing neuronal cAMP levels. In addition, SSTR2 may induce apoptosis by activating SHP-1 (Guillermet et al., 2003), a tyrosine phosphatase that blocks neurotrophin- and nicotine-induced neuroprotective signals and induces neuronal death (Marsh et al., 2003; Shaw et al., 2003). Furthermore, somatostatin has been shown to activate a large variety of potassium channels (Patel et al., 1995). Potassium efflux from mitochondria and the cytoplasm through activated potassium channels has been identified in neurons subjected to chemical hypoxia, excitotoxicity, and staurosporine treatment (Liu et al., 2003). In a variety of in vitro and in vivo models, activated potassium channels contribute to neuronal death (Yu et al., 1998, 1999; McLaughlin et al., 2001; Liu et al., 2003; Pal et al., 2003; Wei et al., 2003).
Regulation of somatostatin and cortistatin in GABAeric cortical neurons
The initial depletion of somatostatin from axonal terminals was followed by a slight increase in somatostatin mRNA and a strong decrease in cortistatin mRNA levels 2 and 4 d after MCAO. These changes occurred in nonlesioned brain areas at stages when the infarction process was complete and reflect most likely adaptive changes of the cortical neuronal network. Somatostatin and cortistatin are known to depress neuronal activity in the cerebral cortex (Spier and de Lecea, 2000). In our studies, SSTR2 was detected only in a very small fraction of the inhibitory cortical GABAergic neurons. In contrast, strong expression of SSTR2 was found in 58% of pyramidal cells in infragranular layers under normal conditions and in >90% of pyramidal cells in all perifocal layers 6 hr after MCAO. This suggests that cortistatin and somatostatin exert their SSTR2-mediated effects directly on excitatory neurons, both under normal and postischemic conditions. However, additional SSTR-independent effects of cortistatin have to be considered (Spier and de Lecea, 2000).
As reported previously for the somatosensory cortex (de Lecea et al., 1997), we found cortistatin in somatostatinergic and parvalbumin-positive neurons in frontal and cingulate regions. Parvalbumin-positive and somatostatin-positive neurons are two distinct populations of GABAergic local circuit neurons in the frontal cerebral cortex (Kawaguchi and Kondo, 2002). Although somatostatinergic neurons have ascending axons that tend to target the distal dendrites of pyramidal cells, parvalbumin-positive neurons tend to target the proximal dendrites and perisomatic regions (Freund, 2003). Dendritic inhibition is considered to control the excitatory input and plasticity of pyramidal cells, whereas perisomatic inhibition is thought to control output and synchronization of pyramidal cells (Freund, 2003). Thus, although cortistatin and somatostatin share similar pharmacological characteristics at the known SSTRs, the localization of cortistatin in neurons with a connectivity different from that of somatostatinergic neurons may enable distinct SSTR-mediated functions of both peptides in the cortical circuitry. The regulation pattern of cortistatin and somatostatin we observed after MCAO was completely different from the regulation of these genes in a kainic acid seizure model, in which somatostatin expression was strongly increased in pyramidal cells and cortistatin expression was unaltered (Calbet et al., 1999). To our knowledge, we provide the first report of sustained downregulation of cortistatin expression after cortical lesion. Given the neuromodulatory role of cortistatin (Spier and de Lecea, 2000), loss of cortistatin as an inhibitory cotransmitter in GABAergic circuits may contribute to known alterations in cortical network activity after focal ischemia (Carmichael and Chesselet, 2002).
Conclusion
Together, this study provides the first evidence for activation and upregulation of SSTR2 in perifocal pyramidal neurons after focal ischemia. Upregulation of SSTR2 is most likely the result of both SSTR2-derived and heterologous signals and may counteract SSTR2 desensitization. Excessive activation of SSTR2 in perifocal neurons by endogenous ligands is likely to account for the larger infarcts in wild-type mice than in SSTR2-deficient mice. Sustained loss of cortistatin expression in inhibitory circuits regulating output and synchronization of pyramidal cells may contribute to altered excitability of nondegenerating cortical areas during late stages after ischemia.
Footnotes
This work was supported by grants from the Deutsche Forschungsgemeinschaft (Ra 698/4 to C. Rauca and V.H.; En343/7-1 to M.E.); the Bundesministerium für Bildung, Wissenschaft, Forschung und Technologie (NBL3 to R.K.S.); and Volkswagen-Stiftung (M.E.). We thank Dr. Michael Culler (Biomeasure, Milford, MA) for the generous gift of BIM-23627 and Dr. Hans-Jürgen Kreienkamp (Institut für Zellbiochemie und Klinische Neurobiologie, Universität Hamburg, Hamburg, Germany) for kindly providing rat SSTR cDNAs. Excellent technical assistance by Anke Reichenauer and Karina Schäfer is gratefully acknowledged.
Correspondence should be addressed to Dr. Ralf K. Stumm, Institut für Pharmakologie und Toxikologie, Otto-von-Guericke-Universität Magdeburg, Leipziger Strasse 44, 39120 Magdeburg, Germany. E-mail: ralf.stumm{at}medizin.uni-magdeburg.de.
G. Tulipano's present address: Department of Biomedical Sciences and Biotechnology, University of Brescia, 25123 Brescia, Italy.
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↵* R.K.S. and C.Z. contributed equally to this work.