Influence of beta-amyloid pathology on emotional learning and memory in the APPswe model of Alzheimer's disease

Previous studies have shown that both the amygdala and frontal cortex contribute to emotional and motivational processes in rodents and humans. These regions show extensive amyloid pathology in humans with Alzheimer's disease (AD) and in mouse models of AD. However, the impact of amyloid production on emotional and motivational processes in mouse models of AD has not been systematically examined. The presence of pathology within key regions linked to emotional processes led to the hypothesis that Tg2576 mice, which express a human genetic mutation associated with early onset AD, would show age-related deficits in emotional reactivity and incentive and aversive learning and memory processes. Biochemical and immunohistochemical analysis confirmed the presence of extensive amyloid pathology in cortical, amygdala and medial temporal lobe structures in Tg2576 mice. Behavioural studies established impairments in anxiety, behavioural disinhibition and fear conditioning in Tg2576 mice. In contrast, other experiments showed that appetitive instrumental and Pavlovian conditioning remained goal-directed in aged Tg2576 mice. However, context-outcome associations were insensitive to post-conditioning changes in the value of the outcome in aged but not in young Tg2576 mice. In order to gain insight into how Ap pathology influenced hippocampal-amygdala system activity during emotional learning, the final set of experiments assessed changes in the expression of the immediate early gene product c-Fos following acquisition and retrieval of fear memories. The findings from this thesis indicate that Tg2576 mice display relatively circumscribed changes in emotional reactivity and emotional memory processes that may reflect age-related alterations in amygdalo-hippocampal network interactions

Cognitive training modifies disease symptoms in a mouse model of Huntington's disease

Huntington's disease (HD) is an incurable neurodegenerative disorder which causes a triad of motor, cognitive and psychiatric disturbances. Cognitive disruptions are a core feature of the disease, which significantly affect daily activities and quality of life, therefore cognitive training interventions present an exciting therapeutic intervention possibility for HD. We aimed to determine if specific cognitive training, in an operant task of attention, modifies the subsequent behavioural and neuropathological phenotype of the Hdh(Q111) mouse model of HD. Three testing groups comprising both Hdh(Q111) mice and wildtype controls were used. The first group received cognitive training in an operant task of attention at 4 months of age. The second group received cognitive training in a comparable non-attentional operant task at 4 months of age, and the third group were control animals that did not receive cognitive training. All groups were then tested in an operant task of attention at 12 months of age. Relative to naïve untrained mice, both wildtype and Hdh(Q111) mice that received cognitive training in the operant task of attention demonstrated an increased number of trials initiated, greater accuracy, and fewer ‘time out’ errors. A specific improvement in response time performance was observed in Hdh(Q111) mice, relative to naïve untrained Hdh(Q111) mice. Relative to the group that received comparable training in a non-attentional task, both wildtype and Hdh(Q111) mice that received attentional training demonstrated superior accuracy in the task and made fewer ‘time out’ errors. Despite significant behavioural change, in both wildtype and Hdh(Q111) mice that had received cognitive training, no significant changes in neuropathology were observed between any of the testing groups. These results demonstrate that attentional cognitive training implemented at a young age significantly improves attentional performance, at an older age, in both wildtype and Hdh(Q111) mice. Attentional cognitive training also improved motor performance in Hdh(Q111) mice, thus leading to the conclusion that cognitive training can improve disease symptoms in a mouse model of HD

Direct comparison of rat- and human-derived ganglionic eminence tissue grafts on motor function

Huntington’s disease (HD) is a debilitating, genetically-inherited neurodegenerative disorder that results in early loss of medium spiny neurons from the striatum and subsequent degeneration of cortical and other subcortical brain regions. Behavioural changes manifest as a range of motor, cognitive and neuropsychiatric impairments. It has been established that replacement of the degenerated medium spiny neurons with rat-derived fetal whole ganglionic eminence (rWGE) tissue can alleviate motor and cognitive deficits in preclinical rodent models of HD. However, clinical application of this cell replacement therapy requires the use of human-derived (hWGE), not rWGE, tissue. Despite this, little is currently known about the functional efficacy of hWGE. The aim of this study was to directly compare the ability of the gold-standard rWGE grafts, against the clinically-relevant hWGE grafts, on a range of behavioural tests of motor function. Lister-hooded rats either remained as unoperated controls or received unilateral excitotoxic lesions of the lateral neostriatum. Subsets of lesioned rats then received transplants of either rWGE or hWGE primary fetal tissue into the lateral striatum. All rats were tested post-lesion and post-graft on the following tests of motor function: staircase test, apomorphine-induced rotation, cylinder test, adjusting steps test and vibrissae-evoked touch test. At 21 weeks post-graft, brain tissue was taken for histological analysis. The results revealed comparable improvements in apomorphine-induced rotational bias and the vibrissae test, despite larger graft volumes in the hWGE cohort. hWGE grafts, but not rWGE grafts, stabilised behavioural performance on the adjusting steps test. These results have implications for clinical application of cell replacement therapies, as well as providing a foundation for the development of stem cell-derived cell therapy products

Novel application of behavioral assays allows dissociation of joint pathology from systemic extra-articular alterations induced by inflammatory arthritis

Introduction: Although rheumatoid arthritis (RA) is a disease of articular joints, patients often suffer from co-morbid neuropsychiatric changes, such as anxiety, that may reflect links between heightened systemic inflammation and abnormal regulation of the hypothalamic-pituitary-adrenal (HPA) axis. Here, we apply behavioral neuroscience methods to assess the impact of antigen-induced arthritis (AIA) on behavioral performance in wild type (WT) and interleukin-10 deficient (Il10-/-) mice. Our aim was to identify limb-specific motor impairments, as well as neuropsychological responses to inflammatory arthritis. Methods: Behavioral testing was performed longitudinally in WT and Il10-/- mice before and after the induction of arthritic joint pathology. Footprint analysis, beam walking and open field assessment determined a range of motor, exploratory and anxiety-related parameters. Specific gene changes in HPA axis tissues were analyzed using qPCR. Results: Behavioral assessment revealed transient motor and exploratory impairments in mice receiving AIA, coinciding with joint swelling. Hind limb coordination deficits were independent of joint pathology. Behavioral impairments returned to baseline by 10 days post-AIA in WT mice. Il10-/- mice demonstrated comparable levels of swelling and joint pathology as WT mice up to 15 days post-AIA, but systemic differences were evident in mRNA expression in HPA axis tissues from Il10-/- mice post-AIA. Interestingly, the behavioral profile of Il10-/- mice revealed a significantly longer time post-AIA for activity and anxiety-related behaviors to recover. Conclusions: The novel application of sensitive behavioral tasks has enabled dissociation between behaviors that occur due to transient joint-specific pathology and those generated by more subtle systemic alterations that manifest post-AIA

c-Fos expression reveals aberrant neural network activity during cued fear conditioning in APPswe transgenic mice

The neural circuitry underlying emotional learning and memory is known to involve both the amygdala and hippocampus. Both of these structures undergo anatomical and functional changes during the course of Alzheimer’s disease. The present study used expression of the immediate early gene c-Fos to examine the effect of amyloid-induced synaptic pathology on neural activity in the hippocampus and amygdala immediately following Pavlovian fear conditioning. Tg2576 mice underwent cued fear conditioning and the regional interdependencies of c-Fos expression in the hippocampus and the amygdala were assessed using structural equation modelling. Tg2576 mice displayed normal acquisition of conditioned freezing to a punctate auditory cue paired with shock. However, the analysis of c-Fos expression indicated abnormal regional activity in the hippocampal dentate gyrus of Tg2576 mice. Structural equation modelling also supported the view that activity within the amygdala was independent of hippocampal activity in Tg2576 mice (unlike control mice) and regional interaction between the dentate gyrus and CA3 region was disrupted. The results provide novel insight into the effects of excess amyloid production on brain region interdependencies underpinning emotional learning

Aberrant dopamine transmission and cognitive dysfunction in animal models of Parkinson's disease

Due to the relative success of therapeutic interventions aimed at treating the overt motor symptoms evident in Parkinson's disease (PD), a greater appreciation of the non-motor aspects of the disease has emerged in recent time. Indeed, evidence suggests that impairments in emotional processing, behavioural control and cognitive function may emerge early in the onset of the disease. Decades of experimental research have seen the development of diverse animal models, all of which have aimed to mimic the characteristic features of the disease process including the dopaminergic neural cell loss, the molecular neuropathology and the concomitant behavioural impairments. The following review provides an overview of the use of animal, particularly rodent, models in the quest to obtain a greater understanding of the role of corticostriatal dopamine in cognitive and neuropsychiatric functions. Given the limitations of using the available rodent models of PD, including altered motor and motivational function, it has become necessary to employ a range of techniques to eke out the precise function of this neurotransmitter in corticostriatal function. Combinations of lesion and pharmacological studies have allowed the assessment of dopamine depletion and precise receptor populations in the learning or expression of a range of executive functions, which has gained us considerable insight into the relationship between the neuropathology that occurs in PD and the resulting impairments in cognitive and neuropsychiatric function

Nigral grafts in animal models of Parkinson's disease. Is recovery beyond motor function possible?

Parkinson's disease (PD) has long been considered predominantly to be a “movement disorder,” and it is only relatively recently that nonmotor symptoms of PD have been recognized to be a major concern to patients. Consequently, there has been surprisingly little investigation into the feasibility of utilizing cell replacement therapies to ameliorate any of the nonmotor dysfunctions of PD. In this chapter, we identify nonmotor impairments associated predominately with dopaminergic dysmodulation, evaluate the few emerging studies that have identified a role for dopamine and nigral transplantation in nonmotor performance, and consider a number of outstanding questions and considerations dominating the field of nigral transplantation today. Preliminary results obtained from rodent models of PD, despite being limited in number, give clear indications of graft effects on striatal processing beyond the simple activation of motor output and promise a major, exciting, and fruitful new avenue of research for the next decade. We can now consider the prospect of rewriting the opportunities for treating patients, with new stem cell sources to be complemented by new targets for therapeutic benefit

Impaired sensitivity to Pavlovian stimulus-outcome learning after excitotoxic lesion of the ventrolateral neostriatum

Subregions of the neostriatum have been dissociated according to their role in specific aspects of instrumental and Pavlovian learning. While the dorsomedial striatum is critical for the acquisition of goal-directed behaviours, the dorsolateral striatum has been shown to be necessary for the formation of habits. The ventrolateral subregion of the neostriatum (VLS), which supports a distinct cortical–subcortical circuitry, has not, however, been investigated within these paradigms. Thus, to determine whether the VLS is involved in the formation of action–outcome associations, Experiment 1 used a sensory specific devaluation procedure to assess the role of the VLS in the acquisition of goal-directed instrumental behaviours. Experiment 2 examined the ability of VLS lesion rats to form Pavlovian–outcome associations and to adjust responses according to the current incentive value of the reward by using a Pavlovian approach task, while Experiment 3 assessed the development and expression of habitual responding. Results indicated an intact ability of both sham and VLS lesion rats to form instrumental action–outcome associations and to use such representations to direct behaviour according to the incentive value of the outcome. VLS lesion rats equally demonstrated intact development of habitual lever press responses, which were shown to be impervious to lithium chloride devaluation treatment. VLS lesion rats did, however, demonstrate aberrant goal-directed responding to a Pavlovian auditory stimulus after outcome specific devaluation treatment. Thus, these results indicate that the VLS is necessary for utilising a representation of a Pavlovian stimulus–outcome association to direct behaviour according to the current incentive value of a reward

Do alpha-synuclein vector injections provide a better model of Parkinson's disease than the classic 6-hydroxydopamine model?

Improvements in modelling Parkinson's disease in rodents contribute to the advancement of scientific knowledge and open innumerable pathways for the development of new therapeutic interventions. In a recent article in this journal, Decressac and co-workers present an interesting comparison between two classic 6-hydroxydopamine (6-OHDA) models and the more recently established rodent model of Parkinson's disease induced by over-expression of α-synuclein using adeno-associated viral vectors. As expected, injections of 6-OHDA result in extensive loss of dopamine associated with pronounced motor deficits. Interestingly, over-expression of α-synuclein in the substantia nigra pars compacta also results in a considerable loss of dopamine as well as motor impairments. Both the level of dopamine loss and the motor deficits seen after α-synuclein over-expression were similar in extent to that seen after intrastriatal injections of 6-OHDA, but the temporal profile of degeneration and the development of motor deficits were progressive, more closely mimicking the clinical condition. This commentary offers further insights into the differences between these two rodent models, and asks how well they each replicate idiopathic PD. In addition, the translational relevance, reliability, and predictive value of this more recently developed AAV α-synuclein model are considered