Erin L. Zelinski

The trouble with circadian clock dysfunction: multiple deleterious effects on the brain and body.

This review consolidates research employing human correlational and experimental work across brain and body with experimental animal models to provide a more complete representation of how circadian rhythms influence almost all aspects of life. In doing so, we will cover the morphological and biochemical pathways responsible for rhythm generation as well as interactions between these systems and others (e.g., stress, feeding, reproduction). The effects of circadian disruption on the health of humans, including time of day effects, cognitive sequelae, dementia, Alzheimers disease, diet, obesity, food preferences, mood disorders, and cancer will also be discussed. Subsequently, experimental support for these largely correlational human studies conducted in non-human animal models will be described.

Multiple effects of circadian dysfunction induced by photoperiod shifts: alterations in context memory and food metabolism in the same subjects.

Humans exposed to shiftwork conditions have been reported to have increased susceptibility to various health problems including various forms of dementia, cancer, heart disease, and metabolic disorders related to obesity. The present experiments assessed the effects of circadian disruption on learning and memory function and various food related processes including diet consumption rates, food metabolism, and changes in body weight. These experiments utilized a novel variant of the conditioned place preference task (CPP) that is normally used to assess Pavlovian associative learning and memory processes produced via repeated context-reward pairings. For the present experiments, the standard CPP paradigm was modified in that both contexts were paired with food, but the dietary constituents of the food were different. In particular, we were interested in whether rats could differentiate between two types of carbohydrates, simple (dextrose) and complex (starch). Consumption rates for each type of carbohydrate were measured throughout training. A test of context preference without the food present was also conducted. At the end of behavioral testing, a fasting glucose test and a glucose challenge test were administered. Chronic photoperiod shifting resulted in impaired context learning and memory processes thought to be mediated by a neural circuit centered on the hippocampus. The results also showed that preferences for the different carbohydrate diets were altered in rats experiencing photoperiod shifting in that they maintained an initial preference for the simple carbohydrate throughout training. Lastly, photoperiod shifting resulted in changes in fasting blood glucose levels and elicited weight gain. These results show that chronic photoperiod shifting, which likely resulted in circadian dysfunction, impairs multiple functions of the brain and/or body in the same individual.

Expression of a conditioned place preference or spatial navigation task following muscimol-induced inactivations of the amygdala or dorsal hippocampus: A double dissociation in the retrograde direction

Previous work indicates an essential role of the basolateral amygdala in stimulus-reward learning and the dorsal hippocampus in spatial learning and memory. The goal of the present, experiments was to examine the involvement of the amygdala and hippocampus in performance of tasks requiring stimulus-reward and spatial/relational learning and memory processes in the retrograde direction. Accordingly, this series of experiments tested the effects of temporary, inactivations directed at the basolateral nucleus of the amygdala or dorsal hippocampus on the, expression of a conditioned place preference (CPP) task or a spatial navigation water task. The results, of Experiments 1a and b showed that inactivations of the amygdala impaired the expression of a, previously acquired CPP but did not impair the expression of a learned spatial response required for, accurate performance of a spatial navigation task. The results of Experiments 2a and b showed that, inactivations of the dorsal hippocampus impaired expression of a learned response required for the, accurate performance of a spatial navigation task but did not impair the learned response required for, the expression of a CPP. Taken together, the results showed a functional dissociation between the, effects of amygdala or hippocampal dysfunction on the expression of these different classes of tasks.

Persistent impairments in hippocampal, dorsal striatal, and prefrontal cortical function following repeated photoperiod shifts in rats

Cognitive impairments are observed when learned associations are being acquired or retrieved during a period of circadian disruption. However, the extent of the functional impacts on previously acquired associations following circadian rhythm re-entrainment is unknown. The impacts of repeated photoperiod shifts on learning and memory in male and female rats were examined. For these experiments, rats were trained on a spatial version of the Morris water task (MWT) and a visual discrimination task designed for the 8-arm radial maze. Following asymptotic performance on these tasks, rats experienced a repeating photoperiod shift procedure and were then re-entrained. Following circadian re-entrainment, retention of pre-photoperiod-shift-acquired associations was tested. In addition, an extra-dimensional set shift was performed using the 8-arm radial maze. Impaired retention of the MWT platform location was observed in photoperiod-shifted subjects relative to subjects with stable, unmanipulated photoperiods. Repeated photoperiod shifts negatively impacted retention in males and females compared with subjects with stable photoperiods. Retention and the ability to detect extra-dimensional shifts on the visual discrimination task were also impaired, though not consistently by sex or photoperiod condition. Running wheel availability was also included in the analyses to determine whether exercise influenced the effects of photoperiod shifting. The absence of a running wheel produced significant declines in memory retention on both MWT and the visual discrimination task, but only for male rats. The observed impairments indicate that multiple neural systems supporting different learning and memory functions are susceptible to circadian disruption, even if the association is acquired prior to rhythm fragmentation and tested following rhythm re-entrainment.

Persistent impairments in hippocampal function following a brief series of photoperiod shifts in rats

The impact of an acute circadian disruption on learning and memory in male and female rats was examined. Circadian disruption was elicited using a brief series of photoperiod shifts. Previous research using male rats showed that acute circadian disruption during acquisition of a spatial navigation task impaired long-term retention and that chronic circadian disruption impaired acquisition of the same task. However, the long-term effects of acute circadian disruption following circadian re-entrainment and whether sex differences in response to circadian disruption exist are still unknown. For the present study, rats were trained on the standard, spatial version of the Morris water task (MWT) and a visual discrimination task developed for the eight-arm radial maze. After reaching asymptotic performance, behavioural training was terminated and the experimental group experienced a series of photoperiod shifts followed by circadian re-entrainment. Following circadian re-entrainment, the subjects were given retention tests on the MWT and visual discrimination task. Following retention testing, an extra-dimensional shift using the eight-arm radial maze was also performed. An acute episode of circadian disruption elicited via photoperiod shifts negatively impacted retention of spatial memory in male and female rats. Retention of the visual discrimination task and the ability to detect extra-dimensional shifts were not impaired. The observed impairments on the MWT indicate that hippocampal representations are susceptible to a small number of photoperiod shifts even if the association is acquired prior to rhythm manipulation and retention is assessed following rhythm stabilization. Effects were limited to a hippocampus-dependent task, indicating that impairments are specific, not global.

Heterarchic reinstatement of long-term memory: A concept on hippocampal amnesia in rodent memory research

Evidence from clinical and animal research highlights the role of the hippocampus in long-term memory (LTM). Decades of experimental work have produced numerous theoretical accounts of the hippocampus in LTM, and each suggests that hippocampal disruption produces amnesia for specific categories of memory. These accounts also imply that hippocampal disruption before or soon after a learning episode should have equivalent amnestic effects. Recent evidence from lesion and inactivation experiments in rodents illustrates that hippocampal disruption after a learning episode causes memory impairment in a wider range of memory tasks than if the same disruption occurs before learning. Although this finding supports that multiple circuits can acquire and retrieve similar information, it also suggests they do not do so independently. In addition, damage after learning produces amnesia for simple elements of a task as well as complex, conjunctive features. Here we develop an explanation for why anterograde and retrograde hippocampal effects differ. This explanation, the heterarchic reinstatement view, also generates novel predictions.

A novel method for reliable nuclear antibody detection in tissue with high levels of pathology-induced autofluorescence

Immunofluorescence is the basis for many techniques used to quantify phenomena in neuroscience research, in both normal and pathological tissue. Autofluorescence (non-specific, broad spectrum background fluorescence) is an unfortunate consequence of damage to brain tissue. Damage-induced autofluorescence potentially confounds analyses of tissue labeled with fluorescent markers in many experiments. This is especially problematic in protocols that utilize co-localization methods such as BrdU/NeuN in which autofluorescence might lead to overestimates of the number of double-labeled cells. Techniques to reduce autofluorescence are variable and relatively ineffective in damaged brain tissue. Here we show using confocal microscopy that damage-induced autofluorescence does not co-localize with the nuclear specific markers DAPI or Hoechst. Further co-localization of nuclear markers such as Ki67 or BrdU/NeuN with DAPI or Hoechst should serve to help discriminate between intended and spurious fluorescent signal.

The effect of exercise on carbohydrate preference in female rats

Exercise has a myriad of health benefits, including positive effects against heart disease, diabetes, and dementia. Cognitive performance improves following chronic exercise, both in animal models and humans. Studies have examined the effect of exercise on feeding, demonstrating a preference towards increased food consumption. Further, sex differences exist such that females tend to prefer carbohydrates over other macronutrients following exercise. However, no clear effect of exercise on macronutrient or carbohydrate selection has been described in animal or human studies. This research project sought to determine the effect of voluntary exercise on carbohydrate selection in female rats. Preference for a complex (starch) versus a simple (dextrose) carbohydrate was assessed using a discriminative preference to context paradigm in non-exercising and voluntarily exercising female rats. In addition, fasting blood glucose and performance in the Morris water task was examined in order to verify the effects of exercise on performance in this task. Female rats given access to running wheels preferred a context previously associated with starch, whereas females with no running wheel access preferred a context previously associated with dextrose. No changes in blood glucose were observed. However, cognitive differences in the Morris water task were observed such that voluntary exercise allowed rats to find a new location of a hidden platform following 4 days of training to an old platform location. These results suggest that voluntary exercise may decrease preservative behaviors in a spatial navigation task through the facilitation of plasticity mechanisms. This study is the first of its kind to demonstrate the influence of exercise on taste preference for complex and simple carbohydrates with this context conditioning paradigm.

Targeting inflammatory monocytes in sepsis-associated encephalopathy and long-term cognitive impairment

Sepsis-associated encephalopathy manifesting as delirium is a common problem in critical care medicine. In this study, patients that had delirium due to sepsis had significant cognitive impairments at 12-18 months after hospital discharge when compared with controls and Cambridge Neuropsychological Automated Test Battery-standardized scores in spatial recognition memory, pattern recognition memory, and delayed-matching-to-sample tests but not other cognitive functions. A mouse model of S. pneumoniae pneumonia-induced sepsis, which modeled numerous aspects of the human sepsis-associated multiorgan dysfunction, including encephalopathy, also revealed similar deficits in spatial memory but not new task learning. Both humans and mice had large increases in chemokines for myeloid cell recruitment. Intravital imaging of the brains of septic mice revealed increased neutrophil and CCR2+ inflammatory monocyte recruitment (the latter being far more robust), accompanied by subtle microglial activation. Prevention of CCR2+ inflammatory monocyte recruitment, but not neutrophil recruitment, reduced microglial activation and other signs of neuroinflammation and prevented all signs of cognitive impairment after infection. Therefore, therapeutically targeting CCR2+ inflammatory monocytes at the time of sepsis may provide a novel neuroprotective clinical intervention to prevent the development of persistent cognitive impairments.