A model of global cerebral ischemia in C57 BL/6 mice.

A reproducible model of global cerebral ischemia in mice is essential for elucidating the molecular mechanism of ischemic neuronal injury. Such a model is particularly important in the mouse because many genetically engineered mutant animals are available. In C57BL/6 and SV129/EMS mice, we evaluated a three-vessel occlusion model. Occlusion of the basilar artery with a miniature clip was followed by bilateral carotid occlusion. The mean cortical cerebral blood flow was reduced to less than 10% of the preischemic value, and the mean anoxic depolarization was attained within 1 minute. In C57BL/6 mice, there was CA1 hippocampal neuronal degeneration 4 days after ischemia. Neuronal damage depended upon ischemic duration: the surviving neuronal count was 78.5 +/- 8.5% after 8-minute ischemia and 8.4 +/- 12.7% after 14-minute ischemia. In SV129/EMS mice, similar neuronal degeneration was not observed after 14-minute ischemia. The global ischemia model in C57BL/6 mice showed high reproducibility and consistent neuronal injury in the CA1 sector, indicating that comparison of ischemic outcome between wild-type and mutant mice could provide meaningful data using the C57BL/6 genetic background. Strain differences in this study highlight the need for consideration of genetic background when evaluating ischemia experiments in mice.     

Cerebral protection by hypoxic preconditioning in a murine model of focal ischemia-reperfusion.

Sublethal periods of hypoxia or ischemia can induce adaptive mechanisms to protect against subsequent lethal ischemic insults in a process known as ischemic preconditioning. In the present study, we developed a murine model of cerebral preconditioning using several common strains of adult mice. Animals were exposed to sublethal hypoxia (11% oxygen for 2 h) 48 h prior to a 90 min period of transient focal middle cerebral artery occlusion, induced by an intraluminal filament; injury was assessed 24 h later by TTC staining. Infarct volume in hypoxia-preconditioned animals was reduced 46%, 58%, and 64% in C57Bl/6, 129SvEv, and Swiss-Webster ND4 mice relative to their respective untreated controls. This non-invasive murine model of ischemic tolerance should be useful for elucidating the molecular basis of this protection using transgenic and knockout mice.     

A comparison of strain-related susceptibility in two murine recovery models of global cerebral ischemia

Genetically engineered mice are increasingly important in stroke research. The strains on which these constructs are built are known to have inherent differential sensitivities to ischemic insults. This has been largely attributed to differences in vascular anatomy. This study compared the outcome from forebrain ischemia in two common murine background strains using two different types of ischemic insult. C57Bl/6 and SV129 mice were subjected to two vessel (bilateral carotid) occlusion (2VO) or 2VO plus systemic hypotension (2VO+Hypo; mean arterial pressure=30+/-2 mmHg) for 10-20 min. Ventilation and pericranial temperature were controlled. Cerebral blood flow (CBF) was determined by 14C-iodoantipyrine autoradiography. Histologic damage in forebrain structures was measured 3 days post-ischemia. During 2VO+Hypo, the EEG became isoelectric in all animals. During 2VO alone, EEG isoelectricity occurred in 73% of C57Bl/6 and 50% of SV129 mice. Forebrain CBF was reduced to a similar extent in both strains. Greater CBF variability was seen with 2VO alone versus 2VO+Hypo. CBF was less in the 2VO+Hypo model. SV129 mice had wider posterior communicating but smaller basilar artery diameters. With or without hypotension, SV129 mice had markedly less severe histologic damage than C57Bl/6 mice. A time-dependent increase in histologic damage was demonstrated in the 2VO+Hypo model but not with 2VO alone. The 2VO and 2VO+Hypo models produced similar magnitudes of histologic injury in C57Bl/6 mice subjected to 10-min ischemia. SV129 mice were resistant to ischemia in either model. The 2VO+Hypo model produced a more uniform severity of ischemia as defined by CBF and EEG examination. Despite this, the murine strain had a substantially greater impact on histologic outcome than did cerebrovascular anatomy or the type of model used to produce the ischemic insult.     

Spreading depression induces long-lasting brain protection against infarcted lesion development via BDNF gene-dependent mechanism

Preconditioning the rat brain with spreading depression for 48 h induces potent ischemic tolerance (infarct tolerance) after an interval of 12-15 days, consequently reducing the infarcted lesion size in the acute phase following focal cerebral ischemia. However, persistence of the morphological and functional neuroprotection has not yet been proven. We tested whether tolerance-derived neuroprotection against focal cerebral ischemia persists or merely delays the progress of cerebral infarction. Prolonged spreading depression was induced in mice by placing a depolarized focus with intracerebral microinfusion of KCl for 24 h; after intervals of 3, 6, 9 or 12 days, temporary focal ischemia was imposed. In the analysis of the infarcted lesion volume 24 h after ischemia, groups with 6 or 9 day interval demonstrated significantly smaller lesion volume compared to time-matched vehicle control group (P=0.002). Significant reduction in cerebral infarction was also observed at the chronic phase, namely 14 days after ischemia (33% reduction) (P=0.021) accompanied with less severe neurological deficits (38% reduction) (P=0.020). Using this technique, we also investigated if the mice with targeted disruption of a single BDNF allele (heterozygous BDNF-deficient mice) can gain the same potency of tolerance as the wild mice. In the result on infarcted lesion volumes following temporary focal ischemia, potent tolerance developed in the wild type (35% reduction) (P=0.007) but not in the heterozygous BDNF-deficient mice (<19% reduction) (P=0.155), indicating that BDNF expression level following spreading depression is contributing to infarct tolerance development.     

Age dependence of strain determinant on mice motor coordination

Evaluation of motor coordination and motor learning in mice remains a challenge as many factors may interact with the different tests used. Among these factors, genetic background has been reported to be a major determinant of mice performances in motor coordination tests. However, it is not known if the strain dependence of motor coordination and motor learning remains constant through life. In order to assess this point, we tested during 5 days male and female mice of three different strains (NMRI, C57BL/6J, and C57BL/6J x 129OlaHsd) in runway, rotarod, and thin rod tests at juvenile (first day of testing = postnatal day 19) and adult (3 months) age. We found a strong strain effect on motor performances and motor learning at juvenile age (C57BL/6J performing more poorly than the two other strains), whatever the tests used. Interestingly, the C57BL/6J mice were the best performing mice at the adult age. These strain rankings were observed either in male and female groups. These results demonstrate that the strain determinant on mice performances and motor learning is highly age dependent.     

Microglial-macrophage synthesis of tumor necrosis factor after focal cerebral ischemia in mice is strain dependent.

Commonly used inbred mouse strains display substantial differences in sensitivity to focal cerebral ischemia. Such differences can often be ascribed to differences in vascular anatomy. The authors investigated whether a contributing factor could be strain-related differences in cellular synthesis of the pleiotropic and potential neurotoxic cytokine tumor necrosis factor (TNF) in the border zone of and within the focal cerebral infarct. In all mouse strains investigated they found that TNF was synthesized by infarct and periinfarct infiltrating Mac-1 immunopositive microglia-macrophages. BALB/c mice, which developed the largest infarcts, contained significantly fewer TNF-producing microglia-macrophages compared with SJL and C57BL/6 mice at both 12 and 24 hours after permanent occlusion of the distal part of the middle cerebral artery. SJL mice developed larger infarcts than C57BL/6 mice, whereas the number of TNF-producing microglia-macrophages per infarct volume unit was comparable. Western blotting data confirmed the increased TNF levels in SJL mice compared with BALB/c and C57BL/6 mice. Furthermore, mice with 12-hour postischemic survival consistently contained two-to threefold more TNF-producing microglia-macrophages than mice with 24-hour survival. The data show that the magnitude of the cellular TNF response to cerebral ischemia is strain dependent, while the time-profile and the cellular sources of TNF are similar irrespective of genetic background. Furthermore, the lack of correlation between infarct size and cellular TNF response suggests that the functionally important TNF is produced in the very early phase (minutes to a few hours) after induction of ischemia, just as it raises the possibility that different mouse strains display different sensitivities to TNF.     

The maturation of corticocollicular neurons in mice

The location and development of the neurons that give rise to the corticocollicular projection were studied in C57BL/6J and 129SV/CPor^J anophthalmic mice. The first neurons that project to the superior colliculus appear in the subplate zone at E13 in C57BL/6J mice. Cortical plate neurons reach the colliculus about 2 days later. The appearance and development of these neurons are delayed by about 2 days in the anophthalmic strain.     

Mouse strains differ in their susceptibility to poststroke infections

OBJECTIVE: Severe infections, in particular pneumonia, have a major impact on the clinical management and outcome of stroke patients. In a mouse model we have recently demonstrated that stroke induces immunodepression which can result in life-threatening infections. Here, we investigated whether the susceptibility to infections after stroke is strain dependent. METHODS AND RESULTS: Mice from 129SV, C57/B6, and Balb/C strains were subjected to experimental stroke by filament occlusion of the middle cerebral artery (MCAO) for 60 min. Infarct volumes were measured 3 days after MCAO. Microbiological assessment was based on cultures of bronchoalveolar lavage (BAL), lung tissue and blood of animals obtained 3 days after stroke. Three days after stroke 129SV mice did not only develop bacterial chest infection, but also had a strongly increased susceptibility to bacteremia. In contrast, C57BL/6 and Balb/C mice acquired bacterial lung infections only. In addition, bacterial load in BAL was significantly higher in 129SV mice than in the other mice strains. These differences in susceptibility to infection did not correlate with infarct volumes. CONCLUSIONS: Stroke-associated pneumonia developed in three commonly used mouse strains while severity of infections differed between strains. Since infections affect outcome, monitoring of infections is highly relevant for the interpretation of results in experimental stroke research.     

长春西汀注射液在小鼠永久性脑缺血小胶质细胞表型转化中的作用研究

目的 研究长春西汀注射液对小鼠永久性大脑中动脉远端缺血后神经功能恢复及小胶质细胞表型 转化的影响。 方法 36只雄性C57BL/6J小鼠随机分为永久性脑缺血组6只、生理盐水组12只、长春西汀组12只和 假手术组6只,前三组用高频电刀凝断小鼠右侧大脑中动脉远端,制作永久脑缺血模型,假手术组 仅暴露大脑中动脉远端,不凝断血管。模型成功后,生理盐水组尾静脉注射生理盐水,每次150 μL, 每天1次,持续14 d;长春西汀组尾静脉注射长春西汀注射液,每次150 μL（4.55 mg/kg）,每天1次, 持续14 d。模型成功后3 d、5 d、7 d、9 d、11 d和14 d进行改良加西亚评分和转棒测试评价小鼠感觉和 运动神经功能;模型成功后14 d用免疫荧光标记神经元,评价各组神经元损伤情况,免疫荧光染色 梗死周围小胶质细胞表型标志物Iba1、CD16/32和CD206的表达,评价M1型（Iba1及CD16/32阳性）和 M2型（Iba1及CD206阳性）小胶质细胞表型转化情况。 结果 长春西汀组小鼠模型成功后11 d和14 d的改良加西亚评分和14 d的转棒测试中的时间及速度 测试结果均优于永久性脑缺血组,差异均有统计学意义。长春西汀组14 d时神经元损伤较永久性脑 缺血组（P =0.008）和生理盐水组（P =0.037）减轻。永久缺血组（P <0.001）和生理盐水组（P =0.005） M1型小胶质细胞表达高于假手术组;长春西汀组M1型小胶质细胞表达低于永久缺血组（P <0.001） 和生理盐水组（P =0.038）。长春西汀组M2型小胶质细胞表达高于假手术组、永久性脑缺血组和生 理盐水组（均P <0.001）。 结论 长春西汀注射液可能通过促进小胶质细胞表型由促炎向抗炎转变,减少神经元损伤,从而 在小鼠永久性脑缺血后发挥神经保护和促进功能恢复的作用。     

Assessing the effects of the 129/Sv genetic background on swimming navigation learning in transgenic mutants: a study using mice with a modified β-amyloid precursor protein gene

The Morris water maze is frequently used to screen mutant mice generated by gene targeting. Targeted ES-cells are often derived from 129/Sv or BALB/c mice, known as poor swimming navigation learners. After mating the founders with C57BL/6 mice, the F2 or F3 hybrid generation is typically used for behavioral testing. In hybrid 129/Sv×C57BL/6 mice, a modification of the βAPP gene entails impaired swimming navigation learning. This is readily detected despite behavioral variability, because wild-type 129/Sv×C57BL/6 hybrids outperform either of the parental strains and provide a control sample with good baseline performance. However, after backcrossing to the 129/Sv(ev) strain, the mutation effects are no longer detectable, masked by the very poor performance of wild-type 129/Sv(ev) mice. We conclude that F2 and F3 generations of 129/Sv×C57BL/6 crosses provide a suitable genetic background for behavioral testing of transgenic mice, provided that the samples are large enough to compensate for genetic and epigenetic variability and provided that normal performance in the control group is verified by comparison against a large database of mice tested under identical conditions. Creating congenic lines by backcrossing to an inbred strain is unlikely to enhance the sensitivity of the Morris test. Backcrossing to 129/Sv(ev) may even reduce it.     

A forebrain ischemic preconditioning model established in C57Black/Crj6 mice

Although many kinds of rat and gerbil cerebral ischemic preconditioning models are available, only a focal ischemic preconditioning model in mice has been reported. As most genetic alterations have been performed in mice, it is urgent to develop mouse ischemic preconditioning models for investigating the molecular mechanisms of ischemic preconditioning in transgenic mice. In the present study, we developed a forebrain ischemic preconditioning model in C57Black/Crj6 (C57BL/6) mice. Forebrain ischemia was induced in C57BL/6 mice (8-10 weeks old) by bilateral common carotid artery occlusion (BCCAO) for 18 min. The conditioning ischemic insult lasting for 6 min was carried out 48 h before the 18-min BCCAO. On the seventh day after BCCAO, neuronal damage was visualized by microtubule-associated protein-2 immunohistochemistry and quantified by cresyl violet staining. Terminal deoxytransferase-mediated dUTP-nick end labeling (TUNEL) was performed 72 h after reperfusion to detect DNA fragmentation. Ischemia for 18 min resulted in injury to the striatum, cortex and hippocampus. In comparison to the hippocampus, striatal neuronal injury was more severe and reproducible. Although the conditioning ischemia itself caused neither noticeable striatal neuronal damage nor DNA fragmentation, it significantly reduced striatal neuronal damage and DNA fragmentation caused by the subsequent 18-min ischemia. These results indicate that striatal neuronal injury after transient BCCAO can be strongly reduced by a sublethal ischemic episode in C57BL/6 mice. As many kinds of gene-altered C57BL/6 mice are available, this preconditioning model may be useful for investigating the molecular mechanisms of ischemic preconditioning in transgenic mice.     

C57BL/6 strain is most susceptible to cerebral ischemia following bilateral common carotid occlusion among seven mouse strains: selective neuronal death in the murine transient forebrain ischemia

Rats and gerbils have been used widely to investigate the molecular mechanism of selective neuronal death following transient global ischemia. Recently, the availability of transgenic mice has enabled us to examine the involvement of specific gene products in various pathophysiological conditions. However, there has been only limited information about the experimental model of cerebral ischemia in mice, particularly in regard of selective neuronal death. We examined whether bilateral carotid occlusion produced global forebrain ischemia in seven common mouse strains including C57BL/6, ICR, BALB/c, C3H, CBA, ddY and DBA/2, based on neurological signs, histological findings and cortical microcirculatory as well as India ink perfusion patterns. The C57BL/6 strain was found to be the most susceptible among seven strains. All C57BL/6 mice died within 6 h after permanent bilateral carotid occlusion. After transient bilateral carotid occlusion for 20 min, more than 90% of C57BL/6 mice showed typical neurological signs such as torsion of the neck and rolling fits, and developed selective neuronal death in the hippocampus and caudoputamen. Hypothermia prevented the neuronal death. Visualization of brain vasculature by India ink perfusion indicated that the susceptibility of the mice after bilateral carotid occlusion depended mainly on the degree of anastomosis between carotid and basilar arteries. Our results showed the feasibility of investigating selective neuronal death in transgenic mice with simple temporary occlusion of both common carotid arteries, when those from the C57BL/6 strain or inbred transgenic mice from other strains with the C57BL/6 strain in a back-cross manner are used.     

Interplay between the gamma isoform of PKC and calcineurin in regulation of vulnerability to focal cerebral ischemia.

Protein phosphorylation and dephosphorylation mediated by protein kinases and protein phosphatases, respectively, represent essential steps in a variety of vital neuronal processes that could affect susceptibility to ischemic stroke. In this study, the role of the neuron-specific gamma isoform of protein kinase C (gammaPKC) in reversible focal ischemia was examined using mutant mice in which the gene for gammaPKC was knocked-out (gammaPKC-KO). A period of 150 minutes of unilateral middle cerebral artery and common carotid artery (MCA/CCA) occlusion followed by 21.5 hours of reperfusion resulted in significantly larger (P < 0.005) infarct volumes (n = 10; 31.1+/-4.2 mm3) in gammaPKC-KO than in wild-type (WT) animals (n = 12; 22.6+/-7.4 mm3). To control for possible differences related to genetic background, the authors analyzed Balb/cJ, C57BL/6J, and 129SVJ WT in the MCA/CCA model of focal ischemia. No significant differences in stroke volume were detected between these WT strains. Impaired substrate phosphorylation as a consequence of gammaPKC-KO might be corrected by inhibition of protein dephosphorylation. To test this possibility, gammaPKC-KO mice were treated with the protein phosphatase 2B (calcineurin) inhibitor, FK-506, before ischemia. FK-506 reduced (P < 0.008) the infarct volume in gammaPKC-KO mice (n = 7; 24.6+/-4.6 mm3), but at this dose in this model, had no effect on the infarct volume in WT mice (n = 7; 20.5+/-10.7 mm3). These results indicate that gammaPKC plays some neuroprotective role in reversible focal ischemia.     

Erythromycin pretreatment induces tolerance against focal cerebral ischemia through up-regulation of nNOS but not down-regulation of HIF-1α in rats

The purpose of this study was to determine whether the antibiotic erythromycin induces tolerance against focal cerebral ischemia, and the possible underlying mechanism including the involvement of neuronal nitric oxide synthase (nNOS) and hypoxia-inducible factor-1α (HIF-1α). In rat focal cerebral ischemia models, we found that erythromycin preconditioning could significantly decrease the cerebral infarct volume and brain edema. Meanwhile, the neurological deficits from day 4 through 7 after surgery were also remarkably decreased after erythromycin preconditioning. Moreover, erythromycin preconditioning induced significantly increased nNOS levels and decreased HIF-1α levels in both mRNA and protein expression. This study for the first time indicated that erythromycin preconditioning could induce focal brain ischemic tolerance and attenuate brain injury of subsequent transient focal cerebral ischemia. The potential mechanism may be due to up-regulation of nNOS, but the HIF-1α system was not involved.     

Mouse model of focal cerebral ischemia using endothelin-1

Intracerebral injection of the vasoconstrictor peptide, endothelin-1 (ET-1), has been used as a method to induce focal ischemia in rats. The relative technical simplicity of this model makes it attractive for use in mice. However, the effect of ET-1 on mouse brains has not been firmly established. In this study, we determined the ability of ET-1 to induce focal cerebral ischemia in four different mouse strains (CD1, C57/BL6, NOD/SCID, and FVB). In contrast to rats, intracerebral injection of ET-1 did not produce a lesion in any mouse strain tested. A combination of ET-1 injection with either CCA occlusion or N(G)-nitro-l-arginine methyl ester (l-NAME) injection produced only a small infarct and its size was strain-dependent. A triple combination of CCA occlusion with co-injection of ET-1 and l-NAME produced a lesion in all mouse strains tested, and this resulted in a significant motor deficit. However, lesion size was still relatively small and strain-dependent. This study shows that ET-1 has a much less potent effect for producing an infarct in mice than rats.     

PGD(2) DP1 receptor protects brain from ischemia-reperfusion injury

Prostaglandin D(2) is the most abundant prostaglandin in the brain. It has long been described as a modulator of the neuroinflammatory process, but little is known regarding the role of its Galpha(s)-coupled receptor, DP1. Therefore, in this study, the effect of the DP1 receptor on the outcome of cerebral ischemia in wildtype (WT) and DP1 knockout (DP1(-/-)) C57Bl/6 mice was investigated. Ischemia-reperfusion injury was produced by a 90-min occlusion of the right middle cerebral artery followed by a 4-day reperfusion. Infarct size was 49.0 +/- 11.0% larger in DP1(-/-) mice (n = 11; P < 0.01) than in WT mice (n = 9 per group). However, no differences were detected in the relative cerebral blood flow (CBF) or any of the physiological parameters measured (n = 5 per group) or in the large blood vessel anatomy (n = 3 per group). To further address whether the DP1 protective role in the brain could be extended to neurons, mouse primary corticostriatal neuronal cultures were exposed to the DP1-selective agonist, BW245C, which provided dose-dependent protection against excitotoxicity induced by glutamate. Protection was significant at a dose as low as 0.05 microm. The results indicate that the DP1 receptor is neuroprotective in both in vivo and in vitro paradigms. Development of drugs to stimulate the DP1 receptor in brain could provide a new therapeutic strategy against cerebral ischemia and potentially other neurological conditions.     

A behavioral and neuroanatomical assessment of an inbred substrain of 129 mice with behavioral comparisons to C57BL/6J mice

The inbred 129 substrains have been characterized as poor learners that display hypoplasia of the corpus callosum. However, they are used extensively as a source of embryonic stem (ES) cells for creating mice carrying altered copies of a targeted gene ('knockout mice'). The present research investigated callosal agenesis and behavior in the 129/SvEvTac substrain and compared their behavior to that of C57BL/6J mice. In addition, the degree to which callosal agenesis affected behavior was assessed. Nearly 80% of 129/SvEvTac mice in the current sample exhibited callosal hypoplasia, although this was not subsequently found to be associated with any measure of cognition. They learned the Morris maze and a non-spatial pattern discrimination task, though at a level inferior to C57BL/6J mice. They were unable to learn shuttlebox avoidance or the Lashley III maze. The only measure on which they performed better than C57BL/6J mice was a simple water escape task. Thus, 129/SvEvTac mice, in addition to displaying aberrant neuroanatomy, perform poorly on many behavioral tasks, resulting in potential interpretational difficulties.     

Hyperbaric oxygen decreases infarct size and behavioral deficit after transient focal cerebral ischemia in rats

Cerebral hypoxia is a major component of immediate and secondary cell damage caused by ischemia. Hyperbaric oxygen (HBO) is a potent means to increase the amount of oxygen dissolved in blood plasma. The effectiveness of HBO in clinical and experimental cerebral ischemia, however, is controversial. We sought to determine whether treatment with HBO initiated early after focal cerebral ischemia-onset protects the brain when experimental conditions such as brain temperature are controlled. Male Wistar rats (n=57) underwent reversible filament occlusion of the right middle cerebral artery (MCA) for 75 min. Animals were awakened after filament introduction and assessed for presence of forelimb paresis. Rats then underwent a 60-min course of either 100% O(2) at 1.0 atmosphere absolute (ata; control group), HBO 1.5 ata, or HBO 2.5 ata in a customized HBO chamber allowing physiological monitoring and pericranial temperature control. The filament was then removed. Seven days after ischemia, rat behavior was scored from 3-18 (18=normal) and brains were removed for histological analysis of infarct volume. Rats treated with HBO 2.5 ata had better mean+/-standard deviation (S.D.) behavioral scores (14+/-2; p<0.05) than control (10+/-3) or HBO 1.5-ata-treated animals (11+/-3). Similarly, total infarct volumes (mean+/-S.D.) were smaller in animals receiving HBO at 2.5 ata (76+/-65 mm(3); p<0.05) compared to control (129+/-83 mm(3)) and HBO 1.5-ata (119+/-68 mm(3))-treated groups. Cortical infarction occurred less frequently in HBO 2. 5-ata-treated than in control animals (44% vs. 71%; p<0.05). We conclude that HBO can improve outcome after temporary focal ischemia when treatment is started early after ischemia-onset but HBO dose appears important. Potential mechanisms include enhanced oxygen supply to marginally perfused cells.     

Genetic background influences the behavioural and molecular consequences of neurokinin-1 receptor knockout

Genetic background affects animal phenotype and therefore is of particular relevance to studies using genetically manipulated mice. Strain differences in hypothalamic–pituitary–adrenocortical (HPA) axis activity may contribute to background-specificity of some mutations. Here, we analysed components of the HPA axis in mice lacking a functional neurokinin-1 receptor (NK1–/–) on two backgrounds: backcrossed C57BL/6 (B6) and mixed C57BL/6 × 129/sv (129B6). We hypothesized that HPA axis activity would vary between these strains, leading to differences in the NK1–/– phenotype. We compared levels of plasma corticosterone between the groups, and found 129B6 mice exhibited elevated levels of stress-induced corticosterone compared with B6 mice, regardless of genotype. Although the level of basal corticotrophin-releasing factor and stress-induced c-fos mRNAs did not differ between the genotypes of either strain, examination of glucocorticoid receptor immunoreactivity within the hippocampus revealed that NK1–/– mice on the 129B6 background had elevated expression compared with wild-type, whilst there was no difference between genotypes in the B6 strain. Similarly, hippocampal neurogenesis in NK1–/– mice was greater than in wild-type on the 129B6 strain, and did not differ between genotypes on the B6 background. Finally, novelty- and morphine-induced locomotion were assessed. NK1–/– mice on the 129B6 background exhibited hyperlocomotion in response to novelty and greater sensitivity to the locomotor-stimulating properties of morphine than wild-type. In contrast, in B6 mice, no differences were observed between genotypes for either locomotor behaviour. In summary, we find that HPA axis activity differs between the strains and that there are profoundly background-specific effects of the NK1 receptor mutation.     

Regional metabolic disturbances and cerebrovascular anatomy after permanent middle cerebral artery occlusion in C57black/6 and SV129 mice.

C57Black/6 and SV129 mice are widely used for the production of transgenic mutants in molecular stroke research but the ischemic susceptibility of these strains is influenced by differences in vascular anatomy and the responsiveness to excitotoxins and vasodilatory stimuli. To differentiate between these opposing effects on infarct size, the vascular territory of the two strains was correlated with the hemodynamic, metabolic, and morphological consequences of permanent middle cerebral artery (MCA) occlusion. The vascular anatomy was studied by latex infusion, brain infarction by vital staining, the size of the ischemic penumbra by imaging of ATP and protein synthesis, and blood flow by laser-Doppler flowmetry. In C57Black/6 mice the MCA-supplied vascular territory and the size of brain infarcts were significantly larger than in SV129 mice but the size of the penumbra and the residual blood flow in the center of the MCA-supplying territory were similar in both strains. These findings suggest that differences in infarct size in C57Black/6 and SV129 mice are determined mainly by the vascular anatomy and not by differences in collateral vascular responsiveness or excitotoxicity.