Christoph Harms

Physical Activity Improves Long-Term Stroke Outcome via Endothelial Nitric Oxide Synthase–Dependent Augmentation of Neovascularization and Cerebral Blood Flow

Physical activity upregulates endothelial nitric oxide synthase (eNOS), improves endothelium function, and protects from vascular disease. Here, we tested whether voluntary running would enhance neovascularization and long-term recovery following mild brain ischemia. Wild-type mice were exposed to 30 minutes of middle-cerebral artery occlusion (MCAo) and reperfusion. Continuous voluntary running on wheels conferred long-term upregulation of eNOS in the vasculature and of endothelial progenitor cells (EPCs) in the spleen and bone marrow (BM). This was associated with higher numbers of circulating EPCs in the blood and enhanced neovascularization. Moreover, engraftment of TIE2/LacZ-positive BM-derived cells was increased in the ischemic brain. Four weeks after the insult, trained animals showed higher numbers of newly generated cells in vascular sites, increased density of perfused microvessels and sustained augmentation of cerebral blood flow within the ischemic striatum. Moreover, running conferred tissue sparing and improved functional outcome at 4 weeks. The protective effects of running on angiogenesis and outcome were completely abolished when animals were treated with a NOS inhibitor or the antiangiogenic compound endostatin after brain ischemia, and in animals lacking eNOS expression. Voluntary physical activity improves long-term stroke outcome by eNOS-dependent mechanisms related to improved angiogenesis and cerebral blood flow.

Neuroprotective effects of atorvastatin against glutamate-induced excitotoxicity in primary cortical neurones

Statins [3‐hydroxy‐3‐methylglutaryl‐coenzyme A (HMG‐CoA) reductase inhibitors] exert cholesterol‐independent pleiotropic effects that include anti‐thrombotic, anti‐inflammatory, and anti‐oxidative properties. Here, we examined direct protective effects of atorvastatin on neurones in different cell damage models in vitro. Primary cortical neurones were pre‐treated with atorvastatin and then exposed to (i) glutamate, (ii) oxygen–glucose deprivation or (iii) several apoptosis‐inducing compounds. Atorvastatin significantly protected from glutamate‐induced excitotoxicity as evidenced by propidium iodide staining, nuclear morphology, release of lactate dehydrogenase, and mitochondrial tetrazolium metabolism, but not from oxygen–glucose deprivation or apoptotic cell death. This anti‐excitototoxic effect was evident with 2–4 days pre‐treatment but not with daily administration or shorter‐term pre‐treatment. The protective properties occurred independently of 3‐hydroxy‐3‐methylglutaryl‐CoA reductase inhibition because co‐treatment with mevalonate or other isoprenoids did not reverse or attenuate neuroprotection. Atorvastatin attenuated the glutamate‐induced increase of intracellular calcium, which was associated with a modulation of NMDA receptor function. Taken together, atorvastatin exerts specific anti‐excitotoxic effects independent of 3‐hydroxy‐3‐methylglutaryl‐CoA reductase inhibition, which has potential therapeutic implications.

Ischemic injury in experimental stroke depends on angiotensin II

Since pharmacological interactions of the renin‐angiotensin system appear to alter the neurological outcome of stroke patients significantly, we examined the effect of elevated levels of angiotensin II and the role of its receptor subtype ATI in brain infarction in transgenic mice after focal cerebral ischemia. Angiotensinogen‐overexpressing and angiotensin receptor ATI knockout mice underwent 1 h or 24 h permanent middle cerebral artery occlusion (MCAO). The current study revealed a much smaller penumbra size, i.e., brain tissue at risk, in angiotensinogen‐over‐expressing animals compared with their wild‐type subgroup after 1 h MCAO, but an enlarged infarct size after 24 h. In contrast, a smaller lesion area of energy failure and a much larger penumbral area were found in AT1 knockout mice compared with wild‐type litter‐mates. Lower perfusion thresholds for ATP depletion and protein synthesis inhibition after MCAO in AT1‐deficient mice and reduced cell damage in an in vitro model using embryonic neurons of AT1 knockout mice suggest injury mechanisms independent of arterial blood pressure. Our data, therefore, demonstrate a direct correlation between brain angiotensin II and the severity of ischemic injury in experimental stroke.—Walther T., Olah, L., Harms, C., Maul, B., Bader M., Hörtnagl H., Schultheiss, H.‐P., Mies G., Ischemic injury in experimental stroke depends on angiotensin II. FASEB J. 16, 169–176 (2002)

Increased postischemic brain injury in mice deficient in uracil-DNA glycosylase

Uracil-DNA glycosylase (UNG) is involved in base excision repair of aberrant uracil residues in nuclear and mitochondrial DNA. Ung knockout mice generated by gene targeting are viable, fertile, and phenotypically normal and have regular mutation rates. However, when exposed to a nitric oxide donor, Ung(-/-) fibroblasts show an increase in the uracil/cytosine ratio in the genome and augmented cell death. After combined oxygen-glucose deprivation, Ung(-/-) primary cortical neurons have increased vulnerability to cell death, which is associated with early mitochondrial dysfunction. In vivo, UNG expression and activity are low in brains of naive WT mice but increase significantly after reversible middle cerebral artery occlusion and reperfusion. Moreover, major increases in infarct size are observed in Ung(-/-) mice compared with littermate control mice. In conclusion, our results provide compelling evidence that UNG is of major importance for tissue repair after brain ischemia.

Hyperbaric oxygenation induced tolerance against focal cerebral ischemia in mice is strain dependent

SV129 or C57BL/6 mice were exposed to hyperbaric oxygenation (HBO, 5 days, 1 h every day, 100% O(2) at 3 atm absolute). One day after the 5th HBO session focal cerebral ischemia was induced. In SV129 mice, HBO induced tolerance against permanent focal cerebral ischemia (n=42, mean infarct volume reduction 27%, P=0.001), but not against transient (30 or 60 min) focal cerebral ischemia. In the C57BL/6 strain of mice, HBO did not induce tolerance against focal cerebral ischemia, even when the duration of ischemia or the HBO protocol were modified. For the first time we demonstrate that HBO can induce tolerance to focal cerebral ischemia, but this effect is strain dependent.

Inhibition of histone deacetylation protects wildtype but not gelsolin-deficient mice from ischemic brain injury

Acetylation/deactylation of histones is an important mechanism to regulate gene expression and chromatin remodeling. We have previously demonstrated that the HDAC inhibitor trichostatin A (TSA) protects cortical neurons from oxygen/glucose deprivation in vitro which is mediated--at least in part--via the up regulation of gelsolin expression. Here, we demonstrate that TSA treatment dose-dependently enhances histone acetylation in brains of wildtype mice as evidenced by immunoblots of total brain lysates and immunocytochemical staining. Along with increased histone acetylation dose-dependent up regulation of gelsolin protein was observed. Levels of filamentous actin were largely decreased by TSA pre-treatment in brain of wildtype but not gelsolin-deficient mice. When exposed to 1 h filamentous occlusion of the middle cerebral artery followed by reperfusion TSA pre-treated wildtype mice developed significantly smaller cerebral lesion volumes and tended to have improved neurological deficit scores compared to vehicle-treated mice. These protective effects could not be explained by apparent changes in physiological parameters. In contrast to wildtype mice, TSA pre-treatment did not protect gelsolin-deficient mice against MCAo/reperfusion suggesting that enhanced gelsolin expression is an important mechanism by which TSA protects against ischemic brain injury. Our results suggest that HDAC inhibitors such as TSA are a promising therapeutic strategy for reducing brain injury following cerebral ischemia.

SUMO2/3 Conjugation is an Endogenous Neuroprotective Mechanism

Small ubiquitin-like modifier (SUMO)2/3 but not SUMO1 conjugation is activated after transient cerebral ischemia. To investigate its function, we blocked neuronal SUMO2/3 translation through lentiviral microRNA delivery in primary cortical neurons. Viability was unaffected by SUMO2/3 silencing unless neurons were stressed by transient oxygen–glucose deprivation (OGD). Both 15 and 45 minutes of OGD were tolerated by control microRNA-expressing neurons but damaged >60% of neurons expressing SUMO2/3 microRNA. Damaging OGD (75 minutes) increased neuronal loss to 54% (control microRNA) and to 99% (SUMO2/3 microRNA). This suggests that activation of SUMO2/3 conjugation is an endogenous neuroprotective stress response.

Protein kinase CK2 links extracellular growth factor signaling with the control of p27(Kip1) stability in the heart

p27Kip1 (p27) blocks cell proliferation through the inhibition of cyclin-dependent kinase-2 (Cdk2). Despite its robust expression in the heart, little is known about both the function and regulation of p27 in this and other nonproliferative tissues, in which the expression of its main target, cyclin E–Cdk2, is known to be very low. Here we show that angiotensin II, a major cardiac growth factor, induces the proteasomal degradation of p27 through protein kinase CK2-α′–dependent phosphorylation. Conversely, unphosphorylated p27 potently inhibits CK2-α′. Thus, the p27–CK2-α′ interaction is regulated by hypertrophic signaling events and represents a regulatory feedback loop in differentiated cardiomyocytes analogous to, but distinct from, the feedback loop arising from the interaction of p27 with Cdk2 that controls cell proliferation. Our data show that extracellular growth factor signaling regulates p27 stability in postmitotic cells, and that inactivation of p27 by CK2-α′ is crucial for agonist- and stress-induced cardiac hypertrophic growth.

Folate Deficiency Induces Neurodegeneration and Brain Dysfunction in Mice Lacking Uracil DNA Glycosylase

Folate deficiency and resultant increased homocysteine levels have been linked experimentally and epidemiologically with neurodegenerative conditions like stroke and dementia. Moreover, folate deficiency has been implicated in the pathogenesis of psychiatric disorders, most notably depression. We hypothesized that the pathogenic mechanisms include uracil misincorporation and, therefore, analyzed the effects of folate deficiency in mice lacking uracil DNA glycosylase (Ung−/−) versus wild-type controls. Folate depletion increased nuclear mutation rates in Ung−/− embryonic fibroblasts, and conferred death of cultured Ung−/− hippocampal neurons. Feeding animals a folate-deficient diet (FD) for 3 months induced degeneration of CA3 pyramidal neurons in Ung−/− but not Ung+/+ mice along with decreased hippocampal expression of brain-derived neurotrophic factor protein and decreased brain levels of antioxidant glutathione. Furthermore, FD induced cognitive deficits and mood alterations such as anxious and despair-like behaviors that were aggravated in Ung−/− mice. Independent of Ung genotype, FD increased plasma homocysteine levels, altered brain monoamine metabolism, and inhibited adult hippocampal neurogenesis. These results indicate that impaired uracil repair is involved in neurodegeneration and neuropsychiatric dysfunction induced by experimental folate deficiency.

Neuronal gelsolin prevents apoptosis by enhancing actin depolymerization

Gelsolin (gsn), an actin-severing protein, protects neurons from excitotoxic cell death via inactivation of membranous Ca(2+) channels. Its role during apoptotic cell death, however, has remained unclear. Using several models of neuronal cell death, we demonstrate that endogenous gelsolin has anti-apoptotic properties that correlate to its dynamic actions on the cytoskeleton. We show that neurons lacking gelsolin (gsn(-/-)) have enhanced apoptosis following exposure to staurosporine, thapsigargin, or the cholinergic toxin ethylcholine aziridinium (AF64A). AF64A-induced loss of mitochondrial membrane potential and activation of caspase-3 was specifically enhanced in gsn(-/-) neurons and could be reversed by pharmacological inhibition of mitochondrial permeability transition. Moreover, increased caspase-3 activation and cell death in AF64A-treated gsn(-/-) neurons were completely reversed by pharmacological depolymerization of actin filaments and further enhanced by their stabilization. In conclusion, actin remodeling by endogenous gelsolin or analogues protects neurons from apoptosis mediated by mitochondria and caspase-3.