Vascular integrin immunoreactivity is selectively lost on capillaries during rat focal cerebral ischemia and reperfusion.

The alpha1-integrin cell adhesion molecules, the principal endothelial receptors for basal lamina (BL) components disappear during transient ischemia. The current study investigated the localization of integrins, the time dependency and vessel size selectivity in the normal rat brain before and after 3 h of cerebral ischemia (I3) and reperfusion (R). Additionally we looked for a correlation to the amount of extravasation and hemorrhage. In the normal brain, there was a clear immunoreactivity for the alpha1, alpha6, and beta1 integrins on the endothelial perivascular cells. After I3 followed by variable reperfusion intervals of 0, 9, and 24 h (R0, R9 and R24; respectively), the number of vessels and staining intensity indicating immunoreactivity in the ischemic area were compared with the contralateral side. The number of the beta1-immunoreactive capillaries was steadily decreasing with the reperfusion time: -12+/-5%, -15+/-7% and -43+/-8% at I3R0, I3R9 and I3R24 (all p<0.05). The beta1-staining intensity decreased homogeneously to -21% at I3R24 (p<0.05). Vascular staining for alpha1 was affected similarly. Interestingly, the alpha6-positive arterioles/venules were also reduced by -21% at I3R24 (p<0.05) in a diameter-selective way on vessels with diameters larger than 15 mum. The correlated break-down of the blood-brain-barrier was demonstrated by the significant rise of the extravasation of BSA from the perfusion solution as well as the increased hemorrhage after MCAO/R (hemoglobin: 103+/-4% versus 330+/-17%; BSA 101+/-3% versus 132+/-9% in I0R0 and I3R24, respectively). The prominent capillary vulnerability contributes significantly to the impairment of the microvascular integrity and after ischemia and reperfusion.

Matrix metalloproteinase (MMP) induction and inhibition at different doses of recombinant tissue plasminogen activator following experimental stroke.

Although recombinant tissue plasminogen activator (rt-PA) is successfully used for thrombolysis in human stroke, it may increase the risk of haemorrhagic complications. It was shown that the matrix metalloproteinase (MMP) system is critically involved in basal lamina degradation after middle cerebral artery occlusion and reperfusion following rt-PA administration. We describe the effects of different doses of rt-PA (saline, 0.9, 9, or 18 mg rt-PA/kg body weight) on the MMPs, their specific inhibitors (TIMPs), and also their inducer protein EMMPRIN following experimental cerebral ischemia (3 hours [h], 24 h reperfusion, suture model) in rats. The amount of MMP-2 and -9 was measured by gelatine zymography, TIMP-1 and -2 by reverse gelatine zymography, and the content of EMMPRIN and the basal lamina component collagen type IV by Western blotting. The amount of both MMPs steadily rose with increasing doses of rt-PA (p<0.05). In contrast, their endogenous inhibitors TIMPs decreased (p<0.001). A balance between the proteases and their inhibitors was achieved at the low dose of 0.9 mg/kg rt-PA in the rats, which significantly coincided with the demonstrated protection of collagen type IV degradation at this dose. The inducer protein EMMPRIN increased in parallel to its substrate MMP-2. Exogenous rt-PA leads to an increase of the MMP-inducing system by EMMPRIN, and a rise of the degrading MMPs follows. However, at low to moderate doses of rt-PA the microvascular basal lamina was protected, probably due to inhibition of MMP-2 and MMP-9 by the upregulation of their inhibitors. This strongly supports use of the lowest effective dosage of rt-PA available.

rt-PA causes a dose-dependent increase in the extravasation of cellular and non-cellular blood elements after focal cerebral ischemia.

While recombinant tissue plasminogen activator (rt-PA) is successfully used for thrombolysis in human stroke, it may increase the risk of hemorrhagic complications. We describe the effects of different doses of rt-PA (saline, 0.9, 9, or 18 mg rt-PA/kg body weight) on the extravasation of blood components following experimental cerebral ischemia (3 h, 24 h reperfusion, suture model) in rats. The damage to the blood-brain barrier and the hemoglobin extravasation were quantified by Western blotting and immunohistochemistry. Both were significantly elevated in the ischemic cortex and basal ganglia. As rt-PA doses rose, the hemoglobin content as well as the damage to the blood-brain barrier in the ischemic side also rose significantly (p<0.001). This correlated significantly with the rising MMP-9 (matrix metalloproteinase) after increasing doses of rt-PA. Despite various benefits, rt-PA is responsible for a dose-dependent increase of edema and hemorrhage after cerebral ischemia. Clinicians should consider using the lowest effective dose of rt-PA in stroke patients.

Matrix metalloproteinase induction by EMMPRIN in experimental focal cerebral ischemia.

Focal cerebral ischemia leads to the gradual disruption of the extracellular matrix. A key role in the turnover of the extracellular matrix is played by the system of matrix metalloproteinases (MMPs). In this study we describe changes of the MMP inducer protein (EMMPRIN) following experimental cerebral ischemia (induced for 3 h and followed by 24 h reperfusion, suture model) in rats. Extracellular EMMPRIN was measured by Western blot of the ischemic and nonischemic basal ganglia and cortex separately. Compared with the contralateral nonischemic area, the ischemic hemisphere showed a significant increase in EMMPRIN: basal ganglia, 158% +/- 4% (P < 0.05); cortex, 128% +/- 25% (P < 0.05). Immunohistochemistry was used to localize EMMPRIN on cerebral microvessels. EMMPRIN-positive microvascular structures were quantified by automatic morphometric video-imaging analysis and a significant increase in the number of cerebral microvessels staining positive for EMMPRIN in the ischemic basal ganglia was shown. The significant loss of microvascular basal lamina antigen collagen type IV in ischemic cortex and basal ganglia was calculated by Western blot. Measured by gelatin zymography, we demonstrated an MMP-2 and MMP-9 increase in the ischemic brain regions (P < 0.05). For the first time the MMP activation system EMMPRIN was shown to be relevant in cerebral ischemia. These results raise the possibility that the increased expression of EMMPRIN, the increase in MMPs and the damage of the basal lamina following cerebral ischemia are connected and part of a network of related changes.

A new approach to reduce the number of animals used in experimental focal cerebral ischemia models.

We describe a novel experimental set-up that allows biochemical, immunohistochemical and morphometric recording of multiple parameters from a single rat brain. The whole brain was cut (coronal sectioning) in a volumetric manner, and 100 cryo-sections (10 microm) were collected from the region of infarction. By use of a scalpel to dissect the cryosection, crude brain material was obtained from the cortical and basal ganglia areas of ischemic and non-ischemic hemispheres. Material from four 10 microm thick sections of the same animal was pooled. About 30 microg protein lysate was extracted per four sections with various lysis buffers; this sufficed for one biochemical or enzymatic test called "micro-Western-blots" or "micro-zymographies". Scraping brain material from cryosections allows the detection of up to 25 parameters from adjacent brain sections of one single rat brain. Different analysis are possible, we have chosen, e.g. to compare factors affecting the basal lamina of cerebral microvessels like the content of the metalloproteinases-2/-9, their tissue inhibitors, the plasminogen activators, collagen type IV, parameters to test the blood-brain barrier: hemoglobin and the protein of the perfusion solution BSA and the infarction volume. On the basis of these parameters it was possible to compare the interactions of the complex processes in the ischemic brain in the same animal in adjacent sections. Thus, this method increases the validity of data comparisons and reduces significantly the number of animals needed in various experimental settings.

Rt-PA causes a significant increase in endogenous u-PA during experimental focal cerebral ischemia.

The aim of this study was to investigate the effects of different doses of exogenous recombinant human tissue plasminogen activator (rt-PA) on the endogenous cerebral plasminogen-plasmin system in focal ischemia in rats. Ischemia was induced using the suture model. Each group of rats (n = 6) received either treatment (0.9, 9 or 18 mg rt-PA/kg body weight) or saline (control group) at the end of ischemia; a sham-operated group was added. The activity of the plasminogen activators was measured by casein-dependent plasminogen zymography. In the cortex urokinase (u-PA) rose from sham (no ischemia), 91 +/- 7% to ischemia, 176 +/- 10% (P < 0.005). Increasing rt-PA doses led to further significant (P < 0.001) cortical u-PA activation which was maximal at 18 mg: 249 +/- 13%. An extreme increase in the u-PA activity was observed in the basal ganglia to 1019 +/- 22% (P < 0.001). This increase was further aggravated by higher rt-PA doses (18 mg, 1236 +/- 15%; P < 0.001). The t-PA level did not change I3R24 during (3 h ischemia followed by reperfusion for 24 h); however, during low and moderate doses of rt-PA, endogenous t-PA was reduced. In conclusion, while ischemia leads to a significant increase in u-PA, mainly in the basal ganglia, t-PA is not altered. Increasing doses of rt-PA lead to a further elevation of u-PA. Thus, u-PA seems to play a major role in the endogenous plasminogen activator system following focal cerebral ischemia.

Delayed moderate hypothermia reduces calpain activity and breakdown of its substrate in experimental focal cerebral ischemia in rats.

Calpains, intracellular proteases, are involved in various cerebral disorders. To determine the effect of moderate hypothermia on calpain activity, transient middle cerebral artery occlusion in rats was performed. For the reperfusion period normothermic temperature was compared to post-ischemic hypothermia (32 degrees C). Calpain expression was measured by Western blot analysis and immunohistochemistry. The loss of calpain substrate was determined by immunohistochemistry against the anti-microtubule-associated protein-2 (MAP-2). The increase of calpains in the ischemic as compared to the non-ischemic contralateral hemisphere and the loss of MAP-2 were reduced by hypothermia. These data indicate that calpain activity and calpain-induced proteolysis play an important role in the network of events following cerebral ischemia and can be reduced by hypothermia. Moderate hypothermia may be a useful tool to limit secondary injury induced by intracellular calpain degradation.

Mild to moderate hypothermia prevents microvascular basal lamina antigen loss in experimental focal cerebral ischemia.

BACKGROUND AND PURPOSE: Microvascular basal lamina damage occurs after cerebral ischemia and is important for the development of hemorrhage. The aim of this study was to determine whether hypothermia could maintain microvascular integrity in ischemic stroke. METHODS: Using the suture model, we subjected 12 rats to 3 hours of focal ischemia and 24 hours of reperfusion. Six rats received postischemic normothermia (37 degrees C) and 6 received hypothermia (32 degrees C to 34 degrees C) for the reperfusion period; a group of 6 sham-operated animals without ischemia was used as control. Collagen type IV and hemoglobin were measured by Western blot analysis, matrix metalloproteinase (MMP)-2 and MMP-9 by gelatin zymography, and urokinase-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA) by plasminogen-casein zymography. RESULTS: Hypothermia reduced basal lamina collagen type IV loss: 87+/-16% (hypothermia) versus 43+/-4% (normothermia) in basal ganglia and 74+/-16% versus 64+/-4% in cortex; hypothermia reduced hemorrhage from 431+/-65% (normothermia) to 241+/-28% (basal ganglia) (P<0.05). Hypothermia also reduced MMP-2, MMP-9, uPA, and tPA (basal ganglia: MMP-2: 71+/-20% [hypothermia] versus 109+/-3% [normothermia]; MMP-9: 38+/-12% versus 115+/-4%; uPA activity: 310+/-86% versus 1019+/-22%; tPA activity: 61+/-17% versus 111+/-13%; cortex: MMP-2: 53+/-6% versus 116+/-1%; MMP-9: 16+/-4% versus 123+/-3%; uPA: 180+/-27% versus 176+/-10%; tPA: 91+/-15% versus 101+/-8%; each difference: P<0.001) (nonischemic control side=100%). CONCLUSIONS: Hypothermia maintains microvascular integrity and reduces hemorrhage and the activities of MMP-2, MMP-9, uPA, and tPA.

Recombinant human tissue plasminogen activator protects the basal lamina in experimental focal cerebral ischemia.

While recombinant tissue plasminogen activator (rt-PA) is successfully used in human ischemic stroke, it may also cause hemorrhagic complications. Animal experiments have shown that hemorrhages are related to microvascular basal lamina damage. We investigated the effects of different doses of rt-PA on the brain microvasculature. Experimental cerebral ischemia in rats was induced for 3 h and followed by 24 h reperfusion (suture model). Each group of rats (n = 6) received either treatment (0.9, 9, or 18 mg rt-PA/kg body weight) or saline (control group) at the end of ischemia. The loss of microvascular basal lamina antigen collagen type IV was measured by Western blot of the ischemic and non-ischemic basal ganglia and cortex. Compared with the contralateral non-ischemic area, collagen type IV was significantly reduced in the ischemic area: (basal ganglia/cortex) 43% +/- 9% / 64% +/- 4 %. Low/moderate doses of rt-PA had a protective effect: 0.9 mg 79% +/- 3% / 89% +/- 6%, 9 mg 72% +/- 9%/ 81% +/- 12% (p < 0.05). Higher doses of rt-PA (18 mg) had a similar effect as seen in untreated controls: 57% +/- 11% / 59% +/- 9% (p < 0.05, Anova). MMP-9 and MMP-2, measured by gelatine zymography, steadily increased over higher doses of rt-PA: MMP-9 (basal ganglia/cortex): control 115% +/- 4% / 123% +/- 3% compared with 18 mg rt-PA 146% +/- 5%/ 162% +/- 6% (p < 0.05) and MMP-2: control 109% +/- 4%/ 116% +/- 5% and 18 mg rt-PA 222% +/- 15%/ 252% +/- 2% (p < 0.05). Low to moderate doses of rt-PA protect the microvascular basal lamina, whereas high doses of rt-PA have the opposite effect, probably due to increased coactivation of MMP-2 and MMP-9.