Adam Morrill scite author profile

Scopolamine (hyoscine) is a muscarinic acetylcholine receptor antagonist that has traditionally been used to treat motion sickness in humans. However, studies investigating depressed and bipolar populations have found that scopolamine is also effective at reducing depression and anxiety symptoms. The potential anxiety-reducing (anxiolytic) effects of scopolamine could have great clinical implications for humans; however, rats and mice administered scopolamine showed increased anxiety in standard behavioural tests. This is in direct contrast to findings in humans, and complicates studies to elucidate the specific mechanisms of scopolamine action. The aim of this study was to assess the suitability of zebrafish as a model system to test anxiety-like compounds using scopolamine. Similar to humans, scopolamine acted as an anxiolytic in individual behavioural tests (novel approach test and novel tank diving test). The anxiolytic effect of scopolamine was dose dependent and biphasic, reaching maximum effect at 800 µM. Scopolamine (800 µM) also had an anxiolytic effect in a group behavioural test, as it significantly decreased their tendency to shoal. These results establish zebrafish as a model organism for studying the anxiolytic effects of scopolamine, its mechanisms of action and side effects.

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Cerebellar lesions disrupt spatial and temporal visual attention

Craig

Morrill

Anderson

et al. 2021

Cortex

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An ancient conserved role for prion protein in learning and memory

Leighton

Nadolski

Morrill

et al. 2018

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The misfolding of cellular prion protein (PrPC) to form PrP Scrapie (PrPSc) is an exemplar of toxic gain-of-function mechanisms inducing propagated protein misfolding and progressive devastating neurodegeneration. Despite this, PrPC function in the brain is also reduced and subverted during prion disease progression; thus understanding the normal function of PrPC in healthy brains is key. Disrupting PrPC in mice has led to a myriad of controversial functions that sometimes map onto disease symptoms, including a proposed role in memory or learning. Intriguingly, PrPC interaction with amyloid beta (Aβ) oligomers at synapses has also linked its function to Alzheimer's disease and dementia in recent years. We set out to test the involvement of PrPC in memory using a disparate animal model, the zebrafish. Here we document an age-dependent memory decline in prp2−/− zebrafish, pointing to a conserved and ancient role of PrPC in memory. Specifically, we found that aged (3-year-old) prp2−/− fish performed poorly in an object recognition task relative to age-matched prp2+/+ fish or 1-year-old prp2−/− fish. Further, using a novel object approach (NOA) test, we found that aged (3-year-old) prp2−/− fish approached the novel object more than either age-matched prp2+/+ fish or 1-year-old prp2−/− fish, but did not have decreased anxiety when we tested them in a novel tank diving test. Taken together, the results of the NOA and novel tank diving tests suggest an altered cognitive appraisal of the novel object in the 3-year-old prp2−/− fish. The learning paradigm established here enables a path forward to study PrPC interactions of relevance to Alzheimer's disease and prion diseases, and to screen for candidate therapeutics for these diseases. The findings underpin a need to consider the relative contributions of loss- versus gain-of-function of PrPC during Alzheimer's and prion diseases, and have implications upon the prospects of several promising therapeutic strategies.

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Cerebellar lesions disrupt spatial and temporal visual attention

Craig

Morrill

Anderson

et al. 2019

Preprint

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2 Cerebellar contributions to spatial and non-spatial attention ABSTRACTThe current study represents the first comprehensive examination of spatial, temporal and sustained attention following cerebellar damage. Results indicated that, compared to controls, cerebellar damage eliminated the onset of inhibition of return (IOR) during the reflexive covert attention task, and reduced the ability to detect successive targets during an attentional blink task.However, cerebellar damage had no effect on voluntary covert attention or the sustained attention to response task (SART). Lesion overlay analysis indicated that impaired performance on IOR and the attentional blink were associated with damage to Crus II and lobule VII (tuber) and VIII (pyramis) of the left posterior cerebellum. Critically, subsequent analyses indicated our results are not due to either general motor impairments or to damage to the deep cerebellar nuclei. Collectively these data demonstrate, for the first time, that the same cerebellar regions are involved in both spatial and temporal visual attention. Furthermore, these data suggest that damage to the cerebellum may induce a form of "attentional dysmetria," such that performance suffers under conditions in which the rapid deployment of attention (either spatial or temporal) is required.

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Adam Morrill

Object recognition memory in zebrafish

Establishing zebrafish as a model to study the anxiolytic effects of scopolamine

Cerebellar lesions disrupt spatial and temporal visual attention

An ancient conserved role for prion protein in learning and memory

Cerebellar lesions disrupt spatial and temporal visual attention

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