Exacerbation of ischemic brain injury in hypercholesterolemic mice is associated with pronounced changes in peripheral and cerebral immune responses.

Inflammation contributes to ischemic brain injury. However, translation of experimental findings from animal models into clinical trials is still ineffective, since the majority of human stroke studies mainly focus on acute neuroprotection, thereby neglecting inflammatory mechanisms and inflammation-associated co-morbidity factors such as hypercholesterolemia. Therefore, both wildtype and ApoE(-/-) mice that exhibit increased serum plasma cholesterol levels fed with normal or high cholesterol diet were exposed to transient middle cerebral artery occlusion. Analysis of peripheral immune responses revealed an ischemia-induced acute leukocytosis in the blood, which was accompanied by enhanced myeloid cell and specifically granulocyte cell counts in the spleen and blood of ApoE(-/-) mice fed with Western diet. These cellular immune changes were further associated with increased levels of pro-inflammatory cytokines like IL-6 and TNF-α. Moreover, endogenous stroke-induced endothelial activation as well as CXCL-1 and CXCL-2 expression were increased, thus resulting in accelerated leukocyte, particularly granulocyte accumulation, and enhanced ischemic tissue damage. The latter was revealed by larger infarct volumes and increased local DNA fragmentation in ischemic brains of ApoE(-/-) mice on Western diet. These effects were not observed in wildtype mice on normal or Western diet and in ApoE(-/-) mice on normal diet. Our data demonstrate that the combination of both ApoE knockout and a high cholesterol diet leads to increased ischemia-induced peripheral and cerebral immune responses, which go along with enhanced cerebral tissue injury. Thus, clinically predisposing conditions related to peripheral inflammation such as hypercholesterolemia should be included in up-coming preclinical stroke research.

Intracerebroventricularly delivered VEGF promotes contralesional corticorubral plasticity after focal cerebral ischemia via mechanisms involving anti-inflammatory actions.

Vascular endothelial growth factor (VEGF) has potent angiogenic and neuroprotective effects in the ischemic brain. Its effect on axonal plasticity and neurological recovery in the post-acute stroke phase was unknown. Using behavioral tests combined with anterograde tract tracing studies and with immunohistochemical and molecular biological experiments, we examined effects of a delayed i.c.v. delivery of recombinant human VEGF(165), starting 3 days after stroke, on functional neurological recovery, corticorubral plasticity and inflammatory brain responses in mice submitted to 30 min of middle cerebral artery occlusion. We herein show that the slowly progressive functional improvements of motor grip strength and coordination, which are induced by VEGF, are accompanied by enhanced sprouting of contralesional corticorubral fibres that branched off the pyramidal tract in order to cross the midline and innervate the ipsilesional parvocellular red nucleus. Infiltrates of CD45+ leukocytes were noticed in the ischemic striatum of vehicle-treated mice that closely corresponded to areas exhibiting Iba-1+ activated microglia. VEGF attenuated the CD45+ leukocyte infiltrates at 14 but not 30 days post ischemia and diminished the microglial activation. Notably, the VEGF-induced anti-inflammatory effect of VEGF was associated with a downregulation of a broad set of inflammatory cytokines and chemokines in both brain hemispheres. These data suggest a link between VEGF's immunosuppressive and plasticity-promoting actions that may be important for successful brain remodeling. Accordingly, growth factors with anti-inflammatory action may be promising therapeutics in the post-acute stroke phase.