František Vožeh

Purkinje cell loss affects differentially the execution, acquisition and prepulse inhibition of skeletal and facial motor responses in Lurcher mice

Adult heterozygous Lurcher mice show a degeneration of almost all Purkinje cells and 90% of the granular cells of the cerebellum, resulting in ataxia or general deficits in motor coordination. These mice are therefore an excellent model for studying the role of the cerebellar cortex in motor performance, including the acquisition of new motor abilities. The performance of 3‐month‐old Lurcher mice was studied in various behavioural (fall, horizontal bar, rotating cylinder, and ladder), spatial orientation (water maze) and associative learning (eyelid classical conditioning) tasks and compared with that of wild‐type mice. Behavioural tasks indicated a deficit for motor abilities in Lurcher mice but with some adaptation to the tests and improvement in performance. Wild‐type and Lurcher mice performed swimming equally, but the latter learned the task significantly more slowly than the former. The late component of reflex blinks was smaller in amplitude and had a longer latency in Lurcher mice than in controls. Learning curves for Lurcher mice during classical conditioning of eyelid responses were similar to controls, but the amplitude of the learned response in Lurcher mice was significantly lower. The startle response to a severe tone was similar in both control and Lurcher mice but the latter were unable to produce prepulse inhibition. These results suggest that the cerebellar cortex is not indispensable for the performance of this complete set of skeletal and facial tasks, or for the acquisition of new motor abilities, but it is for the appropriate execution and adjustment of any of these motor activities.

Ataxic gait analysis in a mouse model of the olivocerebellar degeneration

Lurcher mutant mice represent a model of olivocerebellar degeneration. Postnatally, a complete loss of Purkinje cells and secondary reduction of granule cells and inferior olive neurons occurs. Cerebellar ataxia is among the symptoms of degeneration of the cerebellum. The aim of the work was to identify gait parameters which are changed in Lurcher mice due to cerebellar ataxia arising from functional cerebellar decortication, and to assess the correlation between gait parameters, walking speed and performance in rotarod test. We used the adult Lurcher mutant and wild type mice of the B6CBA strain. For gait analysis the CatWalk system was used. Motor functions were examined with the rotarod. Data analysis revealed significant differences between Lurchers and controls in many gait parameters. However, almost all parameters correlated with the walking speed and the differences disappeared after the correction to the walking speed. The question is what is the primary change in Lurchers-whether the walking speed or individual gait parameters. In the rotarod test, the Lurcher mutants revealed significantly worse results than the wild type animals. No correlation between the gait parameters and performance in the rotarod test was found.

Behavioral Characteristics, Associative Learning Capabilities, and Dynamic Association Mapping in an Animal Model of Cerebellar Degeneration

Young adult heterozygous Lurcher mice constitute an excellent model for studying the role of the cerebellar cortex in motor performance-including the acquisition of new motor abilities-because of the early postnatal degeneration of almost all of their Purkinje and granular cells. Wild-type and Lurcher mice were classically conditioned for eyelid responses using a delay paradigm with or without an electrolytic lesion in the interpositus nucleus. Although the late component of electrically evoked blink reflexes was smaller in amplitude and had a longer latency in Lurcher mice than that in controls, the two groups of animals presented similar acquisition curves for eyeblink conditioning. The lesion of the interpositus nucleus affected both groups of animals equally for the generation of reflex and conditioned eyelid responses. Furthermore, we recorded the multiunitary activity at the red and interpositus nuclei during the same type of associative learning. In both nuclei, the neural firing activity lagged the beginning of the conditioned response (determined by orbicularis oculi muscle response). Although red nucleus neurons and muscle activities presented a clear functional coupling (strong correlation and low asymmetry) across conditioning, the coupling between interpositus neurons and either red nucleus neurons or muscle activities was slightly significant (weak correlation and high asymmetry). Lurcher mice presented a nonlinear coupling (high asymmetry) between red nucleus neurons and muscle activities, with an evident compensatory adjustment in the correlation of firing between interpositus and red nuclei neurons (a coupling with low asymmetry), aimed probably at compensating the absence of cerebellar cortical neurons.

The Effect of Cerebellar Transplantation and Enforced Physical Activity on Motor Skills and Spatial Learning in Adult Lurcher Mutant Mice

Lurcher mutant mice represent a model of olivocerebellar degeneration. They are used to investigate cerebellar functions, consequences of cerebellar degeneration and methods of therapy influencing them. The aim of the work was to assess the effect of foetal cerebellar graft transplantation, repeated enforced physical activity and the combination of both these types of treatment on motor skills, spontaneous motor activity and spatial learning ability in adult B6CBA Lurcher mice. Foetal cerebellar grafts were applied into the cerebellum of Lurchers in the form of solid tissue pieces. Enforced motor activity was realised through rotarod training. Motor functions were examined using bar, ladder and rotarod tests. Spatial learning was tested in the Morris water maze. Spontaneous motor activity in the open field was observed. The presence of the graft was examined histologically. Enforced physical activity led to moderate improvement of some motor skills and to a significant amelioration of spatial learning ability in Lurchers. The transplantation of cerebellar tissue did not influence motor functions significantly but led to an improvement of spatial learning ability. Mutual advancement of the effects of both types of treatment was not observed. Spontaneous motor activity was influenced neither by physical activity nor by the transplantation. Physical activity did not influence the graft survival and development. Because nerve sprouting and cell migration from the graft to the host cerebellum was poor, the functional effects of the graft should be explained with regard to its trophic influence rather than with any involvement of the grafted cells into neural circuitries.

Quantitative changes of dendrites in rat dentate gyrus and basal nucleus of Meynert after passive avoidance training in the neonatal period

Quantitative morphological analysis of the number of granule cell dendritic spines, as well as total dendritic length and dendritic branching of neurons in the dentate gyrus and the nucleus of Meynert was done in 11-day-old rats after passive avoidance training in the neonatal period. Learning improved stepwise and its neuromorphological sequels were characterized by a statistically significant enhanced number of dendritic spines, due to an increase of thin spines, enhanced dendritic branching in both structures, and increased total dendritic length in the dentate gyrus compared with the controls.

Evaluation of lipofuscin-like pigments as an index of lead-induced oxidative damage in the brain

This study was carried out to investigate the role of lead in the development of oxidative stress in the brain. We examined the rate of lipid peroxidation and we determined lipid fluorescence products (lipofuscin-like pigments - LFP) as a marker of lipid peroxidation after short in vitro incubation of rat brain homogenates with lead acetate (10(-2), 10(-4), 10(-6) M lead acetate, 2 h). Simultaneously we examined by the same method in vivo indices of oxidative stress in brains of mice exposed for 12 weeks to 0.2% lead acetate in drinking water. The results show that the concentration of LFP in rat brain homogenates increased significantly after 2 h incubation with 10(-2) M lead acetate as compared to controls (P<0.0001). This effect was not observed in lower doses of lead acetate (10(-4) and 10(-6) M). After the long-term exposure of mice to 0.2% lead acetate, pronounced accumulation of lead and significantly increased concentration of LFP (P<0.004) in the brains of exposed animals as compared to controls were observed. The evidence for the formation of specific fluorophores originating from oxidative damage was shown also in qualitative changes in 3D spectral arrays and synchronous spectra. The presented results proved the influence of lead on the activation of radical reactions in the brain after short in vitro exposure of rat brain as well as within long-term in vivo exposure in mice using lipofuscin-like pigments as an indicator of oxidative stress.

Intracerebellar application of P19-derived neuroprogenitor and naive stem cells to Lurcher mutant and wild type B6CBA mice

Summary Background Neurotransplantation has great potential for future treatments of various neurodegenerative disorders. Preclinically, the Lurcher mutant mouse represents an appropriate model of genetically-determined olivocerebellar degeneration. The aim of the present study was to assess survival of naïve and neurally differentiated P19 carcinoma stem cells following transplantation into the cerebellum of Lurcher mice and wild type littermates. Material/Methods Adult normal wild type (n=51) and Lurcher mutant mice (n=87) of the B6CBA strain were used. The mean age of the animals at the time of transplantation was 261.5 days. Suspension of naive and neurally differentiated P19 carcinoma stem cells was injected into the cerebellum of the mice. In the Lurcher mutants, 2 depths of graft injection were used. Three weeks after implantation the brains of experimental animals were examined histologically. Results Survival of neuroprogenitor grafts at a depth of 1.6 mm was significantly higher in wild type vs. Lurcher mutant mice. In wild type mice, the typical graft localization was in the middle of the cerebellum, whereas in Lurcher mice the graft was never found inside the degenerated cerebellum and was primarily localized in the mesencephalon. Conclusions We conclude that the appearance and low survival rate of cerebellar P19 carcinoma stem cell grafts in the Lurcher mutant mice weigh against the therapeutic value of this cell line in preclinical studies of neurodegeneration.

Long-term survival of solid embryonic cerebellar grafts in Lurcher mice.

Lurcher mutant mice represent a natural model of olivocerebellar degeneration. They serve as a tool to study pathogenesis, the functional impact of the degeneration as well as therapeutic approaches. Wild type littermates are used as healthy controls. Neurotransplantation may be a promising method of therapy for neurodegenerative diseases. The aim of this work was to compare the long-term survival rate of the solid embryonic cerebellar graft in adult Lurcher mutant and wild type mice of the B6CBA strain and to assess the fundamental structural features of the graft. The graft was obtained from 12-day-old GFP mouse embryos. The brains of host mice were examined histologically 6 months after the transplantation. The graft was identified according to its GFP fluorescence. The graft presence and structure was assessed. The graft survived in all 14 Lurcher mice and in 12 of the 14 wild type mice. Cell migration and fibre sprouting from the graft were poor. No marked differences in the graft morphology between Lurcher mutant and wild type mice were found. The graft survival and appearance were similar to those after a shorter period described in a previous study. This suggests that during the 6 months, no intensive or commonly occurring processes changing the graft had proceeded and that the Lurcher mutant cerebellum niche had no strong influence over the fate of the solid cerebellar graft.

Changes of motor abilities during ontogenetic development in Lurcher mutant mice.

Lurcher mutant mice represent a natural model of olivocerebellar degeneration. This degeneration is caused by a mutation of the gene for the delta2 glutamate receptor. Lurcher mutants suffer from cerebellar ataxia and cognitive functions deficiency as a consequence of excitotoxic apoptosis of Purkinje cells in the cerebellar cortex and a secondary decrease of granule cells and inferior olive neurons. This process finishes by the 90th day of postnatal life, but already by 14 days, the Purkinje cells are damaged and the ataxia is fully developed. Purkinje cells die by apoptosis within the first 3 weeks of life. The aim of our work was to study the development of motor functions in the course of the ontogenetic development in Lurcher mutant mice of the B6CBA strain and to compare it with wild type mice of the same strain. Mice aged 2, 3, 6, 9, and 22 weeks were used in our experiment. Motor skills were examined using four standard tests: the horizontal wire, rotating cylinder, footbridge and slanting ladder. Our findings in Lurcher mutant mice show a significant increase of motor abilities up to the sixth postnatal week and selective decrease early after this period. This improvement of motor skills is caused by the physiological development of musculature and the nervous system, probably with some contribution of plasticity of the maturing brain. The cause of the decline of these abilities immediately after the completion of the development is unknown.

Timing correlations between cerebellar interpositus neuronal firing and classically conditioned eyelid responses in wild-type and Lurcher mice

Classical eyeblink conditioning is an experimental model widely used for the study of the neuronal mechanisms underlying the acquisition of new motor and cognitive skills. There are two principal interpretations of the role of the cerebellum in the learning of eyelid conditioned responses (CRs). One considers that the cerebellum is the place where this learning is acquired and stored, while the second suggests that the cerebellum is mostly involved in the proper performance of acquired CRs, implying that there must be other brain areas involved in the learning process. We checked the timing of cerebellar interpositus nucleus (IPN) neurons’ firing rate with eyelid CRs in both wild-type (WT) and Lurcher (a model of cerebellar cortex degeneration) mice. We used delay and trace conditioning paradigms. WT mice presented a better execution for delay vs. trace conditioning and also for these two paradigms than did Lurcher mice. IPN neurons were activated during CRs following the activation of the orbicularis oculi muscle. Firing patterns of IPN neurons were altered in Lurcher mice. In conclusion, the cerebellum seems to be mostly related with the performance of conditioned responses, rather than with their acquisition.