Protective and detrimental effects of neuroectodermal cell–derived tissue factor in mouse models of stroke
Shaobin Wang, Brandi Reeves, Erica M. Sparkenbaugh, Janice Russell, Zbigniew Soltys, Hua Zhang, James E. Faber, Nigel S. Key, Daniel Kirchhofer, D. Neil Granger, Nigel Mackman, Rafal Pawlinski
Shaobin Wang, Brandi Reeves, Erica M. Sparkenbaugh, Janice Russell, Zbigniew Soltys, Hua Zhang, James E. Faber, Nigel S. Key, Daniel Kirchhofer, D. Neil Granger, Nigel Mackman, Rafal Pawlinski
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Research Article Hematology Neuroscience

Protective and detrimental effects of neuroectodermal cell–derived tissue factor in mouse models of stroke

Abstract

Within the CNS, a dysregulated hemostatic response contributes to both hemorrhagic and ischemic strokes. Tissue factor (TF), the primary initiator of the extrinsic coagulation cascade, plays an essential role in hemostasis and also contributes to thrombosis. Using both genetic and pharmacologic approaches, we characterized the contribution of neuroectodermal (NE) cell TF to the pathophysiology of stroke. We used mice with various levels of TF expression and found that astrocyte TF activity reduced to ~5% of WT levels was still sufficient to maintain hemostasis after hemorrhagic stroke but was also low enough to attenuate inflammation, reduce damage to the blood-brain barrier, and improve outcomes following ischemic stroke. Pharmacologic inhibition of TF during the reperfusion phase of ischemic stroke attenuated neuronal damage, improved behavioral deficit, and prevented mortality of mice. Our data demonstrate that NE cell TF limits bleeding complications associated with the transition from ischemic to hemorrhagic stroke and also contributes to the reperfusion injury after ischemic stroke. The high level of TF expression in the CNS is likely the result of selective pressure to limit intracerebral hemorrhage (ICH) after traumatic brain injury but, in the modern era, poses the additional risk of increased ischemia-reperfusion injury after ischemic stroke.

Authors

Shaobin Wang, Brandi Reeves, Erica M. Sparkenbaugh, Janice Russell, Zbigniew Soltys, Hua Zhang, James E. Faber, Nigel S. Key, Daniel Kirchhofer, D. Neil Granger, Nigel Mackman, Rafal Pawlinski

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Figure 6

Reduced inflammation and vascular permeability in the brain of low-TF mice after ischemia/reperfusion injury.

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Reduced inflammation and vascular permeability in the brain of low-TF mi...
(A) Protein array analysis of various cytokines/chemokines in the brain of WT and low-TF mice (A1,A2 and F1,F2 reference spots: B3,B4 – C5/C5A; B5,B6 – GCSF; D1,D2 – IP10 [CXCL10]; D5,D6 – KC[CXCL1]; D9,D10 – JE[CCL2/MCP1]; D19,D20 – MIP2[CXCL2]; E3,E4 – TIMP1). (B) ELISA analysis of chemokines/cytokines in the brain of sham-operated and injured (1 hour ischemia/23 hours reperfusion) WT (n = 10) and low-TF (n = 9) mice. Data (mean ± SEM) were analyzed by two-way ANOVA followed by Bonferroni multiple comparisons. Asterisks above the bars indicate significance vs. left sham-operated animals within the same genotype. Asterisks above the horizontal brackets indicate significance between genotypes. (C) Representative images and quantitation of vascular leakage measured by extravasation of Evans blue into brain parenchyma of WT (n = 6) and low-TF (n = 6) mice subjected to 1 hour of ischemia followed by 24 hours of reperfusion. Data (mean ± SEM) were analyzed by two-way ANOVA followed by Bonferroni multiple comparisons. **P < 0.01, ***P < 0.001, ****P < 0.0001.