Delayed Expression of Osteopontin after Focal Stroke in the Rat

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The Journal of Neuroscience, March 15, 1998, 18(6):2075-2083

Delayed Expression of Osteopontin after Focal Stroke in the Rat
Xinkang Wang¹, Calvert Louden², Tian-Li Yue¹, Julie A. Ellison¹, Frank C. Barone¹, Henk A. Solleveld², and Giora Z. Feuerstein¹
Departments of ¹ Cardiovascular Pharmacology and ² Experimental Pathology, SmithKline Beecham Pharmaceuticals, King of Prussia, Pennsylvania 19406

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Focal brain ischemia induces inflammation, extracellular matrix remodeling, gliosis, and neovascularization. Osteopontin (OPN)is a secreted glycoprotein that has been implicated in vascularinjury by promoting cell adhesion, migration, and chemotaxis.To investigate the possible involvement of OPN in brain matrixremodeling after focal stroke, we examined the expression of OPNin ischemic cortex after permanent or temporary occlusion of themiddle cerebral artery (MCAO) of the rat. OPN mRNA and proteinlevels in nonischemic cortex were not detected consistently, althoughsignificant induction of OPN was observed in the ischemic cortex.OPN mRNA increased 3.5-fold at 12 hr and reached peak levels 5d (49.5-fold; p < 0.001) after permanent MCAO. The profile ofOPN mRNA induction after transient MCAO (160 min) with reperfusionwas essentially the same as that of permanent MCAO. In situ hybridizationand immunohistochemical studies demonstrated strong inductionof OPN in the ischemic cortex, which was localized primarily ina subset of ED-1-positive macrophages that accumulated in theischemic zone. Moreover, OPN immunoreactivity was detected inthe matrix of ischemic brain, suggesting a functional role ofthe newly deposited matrix protein in cell-matrix interactionsand remodeling. Indeed, using a modified Boyden chamber, we demonstrateda dose-dependent chemotactic activity of OPN in C6 astroglia cellsand normal human astrocytes. Taken together, these data suggestthat the upregulation of OPN after focal brain ischemia may playa role in cellular (glia, macrophage) migration/activation andmatrix remodeling that provides for new matrix-cell interaction.

Key words: osteopontin; focal stroke; matrix protein; astrocyte; macrophage; rat

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Osteopontin (OPN) is a highly acidic, secreted phosphoglycoprotein of 41 kDa containing the adhesive motif arginine-glycine-aspartate(RGD), which interacts with the $alpha$ v $beta$ 3 integrin on the cell surface(Liaw et al., 1995). OPN was found originally in bone matrix andsubsequently in kidney, placenta, and blood vessels (Butler, 1989;Giachelli et al., 1995). The induced expression of OPN has beenidentified in a number of cell lines, including osteoclasts, fibroblasts,activated T-cells, macrophages, epithelial cells, and vascularsmooth muscle cells in response to inflammatory cytokines andgrowth factors (Butler, 1989; Patarca et al., 1989; Singh et al.,1990; Denhardt and Guo, 1993; Giachelli et al., 1995; Wang etal., 1996). Elevated expression of OPN also has been observedin a number of disease processes, including autoimmune disorders(Patarca et al., 1990; Lampe et al., 1991), neointima formationin carotid arteries subjected to balloon angioplasty (Giachelliet al., 1993; Wang et al., 1996), human atherosclerotic plaques(Giachelli et al., 1993; O'Brien et al., 1994), myocardial injury(Murry et al., 1994), and renal tubulointerstitial fibrosis (Giachelliet al., 1994; Pichler et al., 1994). Functionally, OPN has beenimplicated in cell attachment and chemotaxis for macrophages,smooth muscle cells, and endothelial cells (Singh et al., 1990;Liaw et al., 1994; Giachelli et al., 1995), which may bear onvascular remodeling processes in restenosis and atherosclerosis.

Cerebral ischemia is another condition characterized by significant leukocyte infiltration and tissue remodeling (Hallenbecket al., 1986; Clark et al., 1993, 1994; Garcia et al., 1994; Baroneet al., 1995). The inflammatory reaction after focal stroke ischaracterized by early neutrophil adherence to blood vessels andinfiltration into brain tissue, followed by significant accumulationof monocytes and activated macrophages in the lesion. These activatedmacrophages are associated with phagocytosis, connective tissuematrix formation, and resolution of the injured brain tissue.Although the expression of mRNA and protein for several inflammatorycytokines, chemokines, and cell adhesion molecules has been describedpreviously (Feuerstein et al., 1997), little is known about matrixremodeling processes in brain ischemia and especially RGD-matrixproteins that enable inflammatory cell adhesion and migrationinto the injury zone.

Because OPN expression has been found in a number of inflammatory reactions in peripheral organs (Giachelli et al., 1993,1994; Murry et al., 1994; O'Brien et al., 1994; Pichler et al.,1994; Wang et al., 1996), with spatial and temporal associationto macrophage migration and accumulation (Singh et al., 1990),we speculated that OPN also might be involved in a similar reactionelicited by ischemic brain injury. Therefore, we examined thespatial and temporal expression of OPN mRNA in two well characterizedmodels of focal brain ischemia (permanent or temporary occlusionof the middle cerebral artery). Using in situ hybridization andimmunohistochemistry methods, we investigated the temporal andspatial distribution of OPN in the ischemic cortex. In addition,because gliosis is one of the critical remodeling events in responseto focal stroke, we investigated the chemotactic activity of OPNon glial cell migration in vitro and demonstrated a potentialrole of OPN in glial cell activation and migration in additionto the actions postulated for OPN on macrophage recruitment andmatrix remodeling after ischemic injury.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Focal brain ischemia. Permanent or temporary cerebral focal ischemia or sham surgery was performed under stereotaxic controlin male spontaneously hypertensive rats (SHR) or in a normotensiverat strain [Wistar-Kyoto (WKY)], at 18 weeks of age and weighing250-330 gm, by permanent or temporary occlusion of the middlecerebral artery (MCAO), as described in detail previously (Baroneet al., 1992a,b, 1995, 1997a). These models are similar to thoseestablished and used by others (Brint et al., 1988; Duverger andMacKenzie, 1988; Buchan et al., 1992) and have been characterizedextensively over time, indicating extended time course evaluations,for the consistency of ischemic cortical blood flow effects andinfarction (Barone et al., 1992a,b), neurological deficits (Baroneet al., 1993), increased cytokine expression and influence ontissue injury (Barone et al., 1997a; Wang et al., 1997), cellularinfiltration, inflammation, tissue changes, and resolution ofinjury (Barone et al., 1991, 1992b, 1995; Clark et al., 1993,1994), and the influence of temperature on injury (Barone et al.,1997b). Complete tissue injury/necrosis was observed by 24 hrof permanent MCAO or within 24 hr of reperfusion in these models(Clark et al., 1993, 1994). Briefly, for permanent MCAO, the middlecerebral artery was occluded permanently and cut dorsal to thelateral olfactory tract at the level of the inferior cerebralvein by using electrocoagulation (Force 2 Electrosurgical Generator,Valley Lab). For temporary MCAO with reperfusion, the MCA waslifted from the brain surface to occlude blood flow for 160 minand then reperfused as described in detail previously (Baroneet al., 1992a,b, 1995, 1997a). Blood flow determinations havedemonstrated the validity of these techniques, i.e., flow is permanentlydecreased <25% of baseline after permanent MCAO and recovers to100% of blood flow after reperfusion of the temporary MCAO (Baroneet al., 1992a). SHR were selected as the focus of study in thepresent experiments because of their consistent response to permanentor transient focal ischemic injury (i.e., consistent infarctionswith low variability) (Duverger and MacKenzie, 1988; Ginsbergand Busto; 1989; Barone et al., 1992a). Body temperature was maintainedat 37°C with a heating pad during all surgical procedures andcontinued to be regulated at 37°C after head closure (i.e., duringrecovery of anesthesia) for several hours until normal motor activitywas resumed by individual animals. In sham-operated rats the durawas opened over the MCA, but the artery was not occluded. Ratsthen were overdosed with pentobarbital, and forebrains were removedat 1, 3, 6, and 12 hr and 1, 2, 5, 10, and 15 d after permanentMCAO or after reperfusion that followed temporary MCAO and at12 hr and 5 d after sham surgery. The ischemic cortex (i.e., thecortex ipsilateral to surgery) was dissected from the ipsilateralhemisphere; the contralateral (control) cortex was dissected fromthe nonischemic contralateral hemisphere from the same rat (Baroneet al., 1991, 1992b, 1995; Wang et al., 1997). The cortical sampleswere frozen immediately in liquid nitrogen and stored at $-$ 80°C.

Northern hybridization analysis. For RNA preparation, cortical samples were homogenized in an acid guanidinium thiocyanatesolution and extracted with phenol and chloroform as describedpreviously (Chomczynski and Sacchi, 1987; Wang et al., 1994a).RNA samples (40 µg/lane) were electrophoresed through formaldehyde-agaroseslab gels and transferred to GeneScreen Plus membranes (NEN LifeScience Products, Boston, MA). For Northern blot analysis, anOPN or ribosomal protein L32 cDNA was prepared as described previously(Wang et al., 1996) and was labeled uniformly with [ $alpha$ -³²P]dATP (3000 Ci/mmol, Amersham, Arlington Heights, IL), usinga random-priming DNA labeling kit (Boehringer Mannheim, Indianapolis,IN). Hybridization of each probe was performed overnight with1 × 10⁶ cpm/ml of probe at 42°C in 5× SSPE (750 mM NaCl, 50 mM NaH₂PO₄,pH 7.6, and 5 mM EDTA), 50% formamide, 5× Denhardt's solution,2% SDS, 100 µg/ml polyA, and 200 µg/ml boiled salmon sperm DNA.The membranes were washed in 2× SSPE/2% SDS at 65°C for 1-2 hr,with a change every 30 min, and then autoradiographed at $-$ 70°Cwith a Cronex Lightning-Plus intensifying screen for various times,depending on the signal intensity. The relative band intensitieswere measured by a PhosphorImager with an ImageQuant softwarepackage (Molecular Dynamics, Sunnyvale, CA). A probe was strippedfrom the membranes in 10 mM Tris, pH 7.5, 1 mM EDTA, pH 8.0, and1% SDS for 20 min at 95°C and then washed in 2× SSPE for 10 minbefore rehybridization with the other probe. The expression ofrpL32 gene is relatively constant in the present experimentalconditions (Wang et al., 1994a,b) and therefore was used to normalizethe differences of the samples loaded in each lane.

In situ hybridization. Tissue preparation, in vitro transcription, and combined in situ hybridization and immunohistochemistrywere performed as reported previously (Ellison et al., 1996),with slight modifications to the in situ hybridization protocolas indicated. Tissue sections (12 µm) were incubated with theED-1 antibody (BioSource International, Camarillo, CA) overnightat 4°C. Detection of the antibody was performed with the VectorLabs ABC kit (Burlingame, CA) according to the manufacturer'sinstructions, with diaminobenzidine as the substrate. Immediatelyafter antibody detection, the tissue was deproteinated in 0.2M HCl and then acetylated with 0.1 M triethanolamine, pH 8, with0.25% acetic anhydride. Antisense or sense [³³P]uridine triphosphate-labeled OPN probes (1 × 10⁶ cpm/ml) were applied to tissue and hybridized overnight at 60°C.Posthybridization washes were modified as follows: 4× SSC twicefor 10 min each at 50°C; 20 µg/ml RNase for 30 min at 37°C; 5min each of 2× SSC, 1× SSC, and 0.5× SSC at room temperature;0.1× SSC for 20 min at 55°C; and 0.1× SSC for 5 min at room temperature.Slides were dehydrated and dried and then exposed to Hyperfilm $beta$ max (Amersham) overnight. For emulsion autoradiography the slideswere dipped in NTB2 emulsion (Kodak, Rochester, NY) and exposedfor 7 d at 4°C.

Immunohistochemistry. For immunohistochemical studies, rats were killed at 6, 12, and 24 hr and 5, 10, and 15 d after permanentMCAO. After whole-body perfusion with 10% phosphate-buffered formalin,the brain from three rats (n = 3) at each time point was excisedand stored in formalin for 24 hr, after which time the sampleswere transferred to 70% ethanol and then subjected to standardhistological processing by using a Vacuum Infiltration Processor(Miles, Elkhart, IN). After paraffin embedding, 5 µm sectionswere cut, stained with hematoxylin and eosin, and evaluated microscopically.Additional sections were placed on Capillary Gap Plus MicroscopeSlides (Bio-Tek Instruments, Burlingame, CA) for immunohistochemicalevaluation of OPN, ED-1 (monocyte/macrophage marker), glial fibrillaryacidic protein (GFAP; marker for activated glia), and S-100 (neurofilamentmarker) expression. Immunohistochemistry was performed as describedpreviously (Wang et al., 1996) with mouse anti-rat OPN antibody,MPIIIB10 (at 1:50 dilution; Developmental Studies Hybridoma Bank,University of Iowa, Iowa City, IA), monoclonal anti-ED-1 (at 1:100dilution; Harlan BioProducts for Science, Indianapolis, IN), rabbitanti-cow GFAP (at a dilution of 1:750 or 1:20,000; Dako, Carpinteria,CA), and rabbit anti-cow S-100 (at 1:20,000 dilution; DAKO), respectively.

Cell culture and migration assay. Rat C6 glial cells (ATCC CCL107) were obtained from American Type Cultured Collection (ATCC,Rockville, MD) and cultured in DMEM (Life Technologies, Gaithersburg,MD) supplemented with 5% fetal bovine serum. Normal human astrocyteswere purchased from Clonetics and cultured in an astrocyte basalmedium (Clonetics, San Diego, CA) containing 5% fetal bovine serum,20 ng/ml human epidermal growth factor (hEGF), 25 µg/ml insulin,25 ng/ml progesterone, 50 µg/ml transferrin, 50 µg/ml gentamicin,and 50 ng/ml amphotericin-B. The human astrocytes were maintainedand subcultured according to the manufacturer's specificationsand were applied for the cell migration assays before the passage3.

Cell migration assays were performed in a Transwell cell culture chamber, using a polycarbonate membrane with 8 µM pores (Costar,Cambridge, MA) as reported previously (Hidaka et al., 1992). Thelower surface of the membrane was precoated with a different concentrationof recombinant rat OPN (Yue et al., 1994). C6 cells were suspendedin DMEM, and human astrocytes were resuspended in astrocyte basalmedium supplemented with 0.2% bovine serum albumin at a concentrationof 3 × 10⁶ and 2 × 10⁵ cells per milliliter, respectively. As a standard assay, 0.2ml of cell suspension was placed in the upper compartment of thechamber, and the lower compartment contained 0.6 ml of DMEM orastrocyte basal medium supplemented with 0.2% bovine albumin beforeuse. Incubation was performed at 37°C in 5% CO₂ for 24 hr. Afterincubation, nonmigrated cells on the upper surface were scrapedgently, and the filters were fixed in methanol and stained with10% Giemsa stain. The number of cells that migrated to the lowersurface of the filters either was measured by optical densityat 640 nm (C6 cells) or counted in four high-power fields (100×)per filter (Hidaka et al., 1992; Yue et al., 1994). The relativenumber of cells for optical density measurement was evaluatedin parallel with counting the cells under microscope, and thepercentage of cells migrated was determined (see Figure 7 legendfor detail). Experiments were performed in triplicate.

Statistical analysis. Statistical comparisons were made by ANOVA (Fisher's protected least-squares difference); values wereconsidered to be significant when p < 0.05.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Temporal expression of OPN mRNA in rat ischemic cortex after MCAO

Figure 1A illustrates a representative Northern blot for the OPN mRNA in the focal ischemic and nonischemic cortex and inthe sham-operated sample. Quantitative Northern blot signals forOPN (n = 4), after being normalized to a rpL32 probe, are illustratedin Figure 1B. OPN mRNA in the sham-operated animals or in thecontralateral (nonischemic) cortex was not detected consistently.The expression of OPN mRNA was induced in the ipsilateral (ischemic)cortex 12 hr after ischemic injury (3.5-fold increase over control),significantly upregulated at 2 d (12.1-fold; p < 0.05), peakedat 5 d (49.5-fold; p < 0.001), and then gradually decreased after10 d (11.0-fold; p < 0.05) following MCAO (Fig. 1).

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Figure 1. Northern blot analysis of OPN mRNA expression in rat ischemic cortex after permanent MCAO. A, Represent Northern blot forOPN and rpL32 cDNA probes to the samples from spontaneously hypertensiverats (SHR) after permanent MCAO. Total cellular RNA (40 µg/lane)was resolved by electrophoresis, transferred to a nylon membrane,and hybridized to the indicated cDNA probe. Ipsilateral and contralateralcortex samples (denoted by +) from individual rats of sham surgery(S; 5 d) or after 1, 3, 6, 12, and 24 hr and 2, 5, 10, and 15d of permanent MCAO are depicted. B, Quantitative Northern blotdata (n = 4) for OPN mRNA expression after focal stroke. The datawere generated by PhosphorImager analysis and were displayed graphicallyafter being normalized with rpL32 mRNA signals. *p < 0.05; ***p< 0.001, as compared with sham-operated animals.

A similar induction profile of OPN mRNA expression also was observed in a rat model of temporary MCAO (160 min) with reperfusion(Fig. 2), except that the upregulation of OPN mRNA at early timepoints (12 and 24 hr after reperfusion) revealed statistical significance(14.8- and 15.7-fold increase, respectively; p < 0.01), whichmay reflect the early infiltration of macrophages into the ischemiclesions after temporary MCAO (Clark et al., 1994). The peak expressionof OPN mRNA was observed at 5 d after reperfusion (40.0-fold overcontrol; p < 0.001) (Fig. 2).

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Figure 2. Northern analysis of OPN mRNA expression in rat ischemic cortex after temporary MCAO with reperfusion. This figure is illustratedas described in the Figure 1 legend except that temporary occlusion(160 min) of the middle cerebral artery was used. The indicatedtime points refer to the time of reperfusion. The hybridizationwas performed in the presence of OPN and rpL32 probes simultaneously.

To evaluate whether the elevated levels of OPN mRNA in the ischemic cortex are particular to the specific SHR strain thatcarries the stroke risk factor of hypertension, we compared thehypertensive strain (SHR) with the normotensive rat strain (Wistar-Kyoto)at 12 hr and 5 d after permanent MCAO (Fig. 3). Northern blotanalysis revealed that MCAO induced a higher level of OPN mRNAexpression in the ipsilateral (ischemic) cortex over controlsof both rat strains (at 5 d; p < 0.01) and in particular the SHR.The elevated OPN mRNA level was significantly higher in SHR (8.7-fold;p < 0.001) than in WKY at 5 d after MCAO, whereas no differencewas noted at 12 hr (Fig. 3). This difference is in accord withthe previous observation (Clark et al., 1993) of maximal accumulationof macrophages in the ischemic cortex 5 d after MCAO in SHR, ascompared with WKY, but not at the early time point (12 hr).

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Figure 3. Northern blot analysis of OPN mRNA expression in SHR and WKY at 12 hr and 5 d after permanent MCAO. A, Total cellular RNAwas isolated from the ischemic (Ipsilateral) and nonischemic (Contralateral)cortex of hypertensive (SHR) and normotensive (WKY) rats at 12hr and 5 d after permanent MCAO. This representative Northernblot was performed by using an OPN cDNA probe, as described inMaterials and Methods and in the legend to Figure 1A. B, Quantitativeanalysis of OPN mRNA expression in hypertensive (SHR) and normotensive(WKY) rats after permanent MCAO, as described in the legend toFigure 1B. The data are presented as the mean values of four animals(n = 4) from each strain after the samples loaded in each lanewith rpL32 were normalized. ***p < 0.001, as compared with WKYat the same time point.

In situ localization of OPN mRNA in ischemic cortex

Because maximal expression of OPN mRNA was observed at 5 d (n = 3) after MCAO (see Fig. 1), in situ hybridization was performedat this time point to identify the cells that were expressingOPN mRNA. As illustrated in Figure 4A, the expression of OPN mRNAdetected by in situ hybridization was seen in the ischemic cortexof the entire infarcted region (Fig. 4A). To identify phenotypicallythe cells expressing OPN mRNA, we used a technique of combinedin situ hybridization and immunohistochemistry. All of the cellsexpressing OPN mRNA in the infarct could be identified phenotypicallyas macrophages by the colocalization of ED-1 and OPN mRNA (Fig.4B). On the other hand, not all of the ED-1-positive macrophagesexpressed OPN mRNA. Instead, only those ED-1-positive macrophageswith an ameboid morphology characteristic of cells that were activelyphagocytosing expressed OPN mRNA (Fig. 4B, inset). No macrophagewas observed in the surgery cortex of sham-operated rats or inthe contralateral (nonischemic) cortex of MCAO rats. In addition,the sense probe gave no signal (data not shown). Therefore, macrophageinfiltration was observed only because of ischemia.

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Figure 4. In situ localization of OPN mRNA expression in the ischemic cortex. Shown is film autoradiography of OPN mRNA expression 5d after permanent MCAO (A). OPN mRNA-expressing cells are locatedabundantly throughout the entire infarcted region. The ED-1 antibodyand OPN mRNA colocalized in many, but not all, of the macrophagesin the infarct (B). Morphologically, the ED-1-positive and OPN-positivecells (B, inset) have an ameboid appearance indicative of theiractivated phagocytic state. Scale bars: in B, 20 µm; in inset,10 µm.

Immunohistochemical analysis of OPN expression in ischemic cortex

To define further the cellular components and the upregulation of OPN peptide in focal stroke, immunohistochemical techniqueswere applied by using a mouse anti-rat OPN antibody, MPIIIB10(1),to examine OPN expression in normal (sham) or ischemic brain tissuesat 6, 12, and 24 hr and 5, 10, and 15 d after permanent MCAO (n= 3). Selected slides for immunohistochemical staining and hematoxylinand eosin staining are illustrated in Figures 5 and 6. Controlsections stained with preimmune sera or the exclusion of the primaryantibody did not demonstrate detectable staining for OPN (datanot shown). In accord with the OPN mRNA expression data, OPN peptideexpression was not detected in uninjured or sham-operated brainsections. A very weak positive immunoreactive signal was observedin some cells (GFAP-positive and ED-1-positive) in the ischemiccortex 6-24 hr after permanent MCAO (data not shown). In contrast,there was strong positive immunoreactivity in all of the animals5 d after MCAO (Fig. 5D at low magnification and Fig. 6C at highmagnification), indicating abundant OPN expression in the focalischemic brains.

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Figure 5. Histological and immunohistochemical staining of OPN expression in ischemic cortex. A, Hematoxylin and eosin-stained (H&E)section of normal cerebral cortex (sham-operated animals at day5). B, H&E-stained focal ischemic zone at 24 hr after permanentMCAO. C, Focal ischemic zone at 5 d (H&E). D, Immunohistochemistryshowing numerous OPN-positive macrophages in this 5 d lesion.E, Focal ischemic cortex at 15 d (H&E). F, Immunohistochemistryfor OPN in focal ischemic lesion at 15 d.

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Figure 6. Immunohistochemical detection of temporal OPN expression in ischemic cortex after permanent MCAO. A, Immunostaining for GFAPat the boundary of the ischemic lesion 5 d after permanent MCAO.Note the strong immunostaining of GFAP in astrocytes of the nonischemiclesion. B, Immunostaining for GFAP 15 d after MCAO. The GFAP expressionpattern is similar to day 5, but the signal is stronger. C, Immunostainingfor OPN 5 d after MCAO. Note the diffuse cellular staining andthe large number of positive-staining cells in the middle of thelesion. See the inset for a detailed view of OPN in the cells(arrow) and extracellular matrix (arrowhead). D, Immunostainingfor OPN in the ischemic lesion 15 d after MCAO. Most of the cellsare negative for OPN. E, Ischemic lesion 5 d after MCAO, filledwith a large number of ED-1-positive cells that indicate macrophage/monocytelineage. F, Ischemic 15 d lesion with ED-1-positive cells. Notethe organization of this lesion.

The immunostaining demonstrated OPN expression in numerous cells in the necrotic area. Furthermore, the necrotic zone wasdemarcated by a dense band of OPN-positive cells at the interfaceof necrotic and viable tissue. OPN staining (Fig. 6C) was primarilycytoplasmic, with prominent staining around the perinuclear regionthat suggested localization to the Golgi apparatus. In addition,there was extracellular staining for OPN in the necrotic tissue,which appeared as tiny granules in the extracellular space (Fig.6C, inset). The OPN-positive staining cells had histological featuresof macrophages; to confirm this observation, we stained serialsections for ED-1 expression (Fig. 6E), a marker that is specificfor cells in the monocytes/macrophage lineage (Dijkstra et al.,1985). In general, similar to our in situ hybridization data,all cells expressing OPN also expressed ED-1, whereas a few ED-1-positivestaining cells did not express OPN.

It was interesting to observe that at day 15 after ischemia there was a remarkable decrease in the number of OPN-positivecells in the lesions (Figs. 5F, 6D) despite the fact that ED-1-positivemacrophages were still abundant in the granulation tissue (Fig.6F). At this late time point after injury, only a few OPN-positivecells were noted, which were located primarily in the peripheralregion of the lesion, in the perivascular region of the necrotictissue, and in some smooth muscle and endothelial cells of repairingvessels.

Effects of OPN on astrocyte cell migration

On the basis of the chemotactic feature of OPN for macrophages, smooth muscle cells, and endothelial cells (Singh et al.,1990; Liaw et al., 1994; Giachelli et al., 1995) and the inductionof glial cell activation and apparent mobilization in ischemicstroke (Clark et al., 1993), we speculated that elevated expressionof OPN after focal stroke might serve for glial cell activationand migration, a critical feature related to gliosis after focalstroke. To explore this potential role of OPN in stroke, we evaluatedthe effect of OPN on C6 glial cell migration in an in vitro assay.As shown in Figure 7A, OPN caused a concentration-dependent stimulationof C6 glial cell migration after a 24 hr incubation. A markedinduction was observed at 0.07 µM (4.6-fold induction over control;p < 0.001) and 0.24 µM (8.2-fold increase; p < 0.001). Similardose-dependent effects of OPN on normal human astrocytes wereobserved (Fig. 7B), showing 4.4-fold induction at 0.24 and 0.72µM (p < 0.05) over controls. Approximately 4% C6 cells or 3% humanastrocytes migrated in response to 0.24 µM OPN stimulation.

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Figure 7. Effects of OPN on C6 astroglia (A) and normal human astrocyte (B) cell migration. The migration assay was performed in theTranswell cell culture chamber, as described in Materials andMethods. The indicated concentration of OPN was coated on thelower surface of the membrane. The cell suspension (containing6 × 10⁵ C6 cells or 4 × 10⁴ human astrocytes in a vol of 0.2 µl) was added in the upper compartmentand incubated for 24 hr. The relative number of migrated cells(on the lower surface of the filters) was measured by opticaldensity at 640 nm for C6 cells or determined microscopically bycounting four high-power fields per filter for human astrocytes.In the concentration range of 0-0.24 µM OPN, ~0.5-4% of C6 cellsor 0.7-3% of human astrocytes were migrated. The data are themean ± SE of three experiments performed in triplicate. *p < 0.05;**p < 0.01; ***p < 0.001, as compared with the control.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The key novel findings of the present study are the de novo induction of OPN mRNA and peptide after focal stroke, its cellularlocalization, and putative function. OPN is a secreted glycoproteinpresent in the extracellular matrix. The conserved RGD sequencein OPN was demonstrated for its adhesive activity (Xuan et al.,1995) to cells via the cell surface receptor, $alpha$ v $beta$ 3 integrin (Liawet al., 1995). Various extracellular matrix proteins such as fibronectinand collagen or plasma proteins such as vitronectin and fibrinogenalso have been shown to contain an RGD motif and are associatedwith specific cellular adhesion and migration (Yamada, 1991).However, little is known about the involvement of the RGD-containingadhesive molecules in focal stroke and/or CNS injuries. Nevertheless,enhanced expression of tenasin, a developmentally regulated extracellularmolecule, has been reported in a discrete region of astrocytes(around the lesion) after stab brain injury (Laywell et al., 1992).Very recently, the induced expression of SC1, a brain extracellularmatrix glycoprotein related to secreted protein acidic and richin cysteine (SPARC), also has been demonstrated in the activeastrocytes after surgical wound (Mendis et al., 1996a), suggestinga potential role of SC1 in glial scar formation. The SPARC familyof extracellular matrix-associated glycoproteins has been shownto have anti-adhesive properties (Sage and Bornstein, 1991; Laneand Sage, 1994; Girard and Springer, 1996), which lack an RGDmotif. It is interesting to note that cellular expression of OPN(primarily in macrophages; the present report) is distinct fromthose of tenascin and SC1 (mainly in astrocytes; Laywell et al.,1992; Mendis et al., 1996a) after brain injury, although all ofthese molecules may be involved in matrix remodeling after injury.Similarly, differential expression of OPN with tenascin, SC1,or SPARC has been reported during development (Nomura et al.,1988; Laywell et al., 1992; Mendis et al., 1996b).

The biological or pathophysiological significance of OPN expression in cerebral ischemia is not yet clear, but several potentialroles can be inferred on the basis of previous reports on OPNexpression in peripheral organs in response to injury. First,the induced expression of OPN in macrophages in the ischemic lesionmay contribute to the recruitment of more macrophages into theinjured tissue, based on its adhesive and chemotactic properties(Giachelli et al., 1995). In particular, OPN has been shown tobind to macrophages in vitro and induce macrophage infiltrationin mice (Singh et al., 1990). The temporal expression of OPN inthe ischemic cortex is remarkably parallel to the accumulationof macrophages after focal stroke, suggesting that the inducedexpression of OPN may recruit additional macrophages in the ischemicbrain.

Second, OPN-expressing macrophages in the ischemic lesion may play an active role in tissue remodeling after ischemic stroke.OPN-expressing macrophages with the ameboid morphology characteristicof active cell phagocytosis were clustered mainly in the necroticlesion. The spatial expression of OPN after focal stroke confirmsthe previous observation concerning myeloperoxidase activity (Baroneet al., 1995), suggesting that these macrophages are active andplay a role in removing necrotic tissue. Interestingly, strongOPN-expressing macrophages also were localized in the necrotictissues after myocardial ischemia (Murry et al., 1994) or clusteredaround tubules of tubulointerstitial nephritis (Giachelli et al.,1994), supporting a common pattern of OPN function in acute tissueinjury. Additional parallelism can be drawn from the diminishedexpression of OPN in macrophages right after the removal of thenecrotic tissue in both myocardial ischemia (Murry et al., 1994)and focal brain ischemia (the present report), although a largenumber of macrophages were still present in the injury site, suggestingthat OPN expression marks a functional (phagocytosing) state ofthe macrophage.

The induced expression of OPN after focal stroke may involve general tissue repair and remodeling processes after ischemia.Time course studies reveal that ischemia-induced expression ofOPN parallels not only massive macrophage infiltration but alsosignificant extracellular matrix formation, neovascularization,and gliosis (Clark et al., 1993, 1994). Induced expression of $alpha$ v $beta$ 3 integrin recently has been demonstrated in selected microvesselsof ischemic lesion after focal cerebral ischemia (Okada et al.,1996), suggesting that the concomitant upregulation of OPN andits receptor may contribute to angiogenesis induced by focal ischemia.In addition, the dose-dependent effects of OPN on astroglial cellmigration were demonstrated for the first time, suggesting a roleof OPN in glial cell activation/migration, a critical elementof gliosis/remodeling in focal stroke. It is interesting to speculatethat the change of glial cells from being scattered adjacent tothe infarct to a focused glial scar and a walling off of the resolvedinfarct after 15 d [see Fig. 6A,B for the GFAP-positive astrocytestaining and Clark et al. (1993)] may be associated with the migratoryactivity of OPN. Further studies must be explored when specificantagonists against $alpha$ v $beta$ 3 integrin or neutralizing antibodies againstOPN become available.

Additional functions for ischemia-induced OPN in brain may include the inhibition of nitric oxide production (Rollo et al.,1996). Rollo et al. (1996) demonstrated that OPN could dose-dependentlysuppress inducible nitric oxide synthase (iNOS) expression inactivated RAW264.7 macrophages. The temporal expression of iNOS(induced at 48 hr and returned to basal level at 7 d after ischemia)(Iadecola et al., 1995, 1996) and OPN after focal stroke alsomay suggest such an inhibitory role.

The factors that induce OPN expression after focal stroke are not yet known. However, time course studies suggest that inflammatorycytokines, including TNF- $alpha$ and IL-1 $beta$ that are induced earlier(onset 1-3 hr and peak at 12 hr) (Liu et al., 1993, 1994; Wanget al., 1994b), or factors associated with tissue remodeling processesthat are upregulated late after ischemic injury, such as TGF- $beta$ 1(upregulated until 2-15 d after ischemic injury) (Wang et al.,1995), may be involved in the regulation of OPN gene expressionin focal stroke. The effect of these factors on OPN expressionhas been demonstrated previously in various cultured cells (Butler,1989; Patarca et al., 1989; Singh et al., 1990; Denhardt and Guo,1993; Giachelli et al., 1995; Wang et al., 1996). The presentmodel of focal ischemia (i.e., with infarct restricted to cortex)provides long-term histopathological and neurobehavioral evaluation(i.e., 100% survival beyond 30 d; Barone et al., 1993; Clark etal., 1993) and is ideal for full time course gene expression studies,including OPN, as demonstrated in the present work.

In conclusion, the present report demonstrates the delayed expression of OPN and its robust induction in macrophages afterischemic brain injury. The temporal and spatial distribution ofOPN suggests that the induced OPN in the ischemic cortex may playa role in macrophage recruitment, matrix repair, gliosis, andremodeling processes that occur after focal ischemia, althoughdirect evidence for these potential functions still needs to beexplored further.

  FOOTNOTES

Received Sept. 17, 1997; revised Dec. 29, 1997; accepted Jan. 6, 1998.

We extend our appreciation to Ray White, Juan-Li Gu, and Christine Webb for excellent technical assistance.
Correspondence should be addressed to Dr. Xinkang Wang, Department of Cardiovascular Pharmacology, SmithKline Beecham Pharmaceuticals,709 Swedeland Road, P.O. Box 1539, UW 2511, King of Prussia, PA19406.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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