Spontaneous alternation behavior in larval zebrafish

Bögli, Stefan Yu; Huang, Yingyu

doi:10.1242/jeb.149336

Cited by 8 publications

(5 citation statements)

References 39 publications

(52 reference statements)

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“…This is likely related to how spontaneous alternation has evolved into a standard test for memory in transgenic rodent models of human conditions (e.g., O'Leary, Hussin, Gunn, & Brown, ; Snider & Obrietan, ) or evaluating effects of pharmacological agents (Hughes, ). However, spontaneous alternation has been observed in several other nonhuman organisms, including larval zebrafish (Bögli & Huang, ) and black molly fish (Creson, Woodruff, Ferslew, Rasch, & Monaco, ), ants (Czaczkes, Koch, Fröber, & Dreisbach, ), fruit flies ( Drosophila melanogaster ; Lewis, Negelspach, Kaladchibachi, Cowen, & Fernandez, ), paramecium (Harvey & Bovell, ), marmosets (Izumi, Tsuchida, & Yamaguchi, ), and in some species of crab (but not others—Balcı, Ramey‐Balcı, & Ruamps, ; Ramey, Teichman, Oleksiak, & Balci, ). In other species, evidence for spontaneous alternation behavior is debatable (lemurs, Dal‐Pan et al, ; chicks, Hayes & Warren, ; hens, Haskell, Forkman & Waddington, ) or contrary (e.g., pigeons, Hughes, ).…”

Section: Exploring Similarities and Differencesmentioning

confidence: 99%

The puzzle of spontaneous alternation and inhibition of return: How they might fit together

Phillmore

Klein

2019

Hippocampus

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Two isolated spatial phenomena share a similar “been there; done that” effect on spatial behavior. Originally discovered in rodent learning experiments, spontaneous alternation is a tendency for the organism to visit a different arm in a T‐maze on subsequent trials. Originally discovered in human studies of attention, inhibition of return is a tendency for the organism to orient away from a previously attended location. Whereas spontaneous alternation was identified by O'Keefe & Nadel as dependent on an intact hippocampus, inhibition of return is dependent on neural structures that participate in oculomotor control (the superior colliculus, parietal and frontal cortex). Despite the isolated literatures, each phenomenon has been assumed to reflect a basic novelty‐seeking process, avoiding places previously visited or locations attended. In this commentary, we explore and compare the behavioral manifestations and neural underpinnings of these two phenomena, and suggest what is still needed to determine whether they operate in parallel or serial.

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Section: Exploring Similarities and Differencesmentioning

confidence: 99%

The puzzle of spontaneous alternation and inhibition of return: How they might fit together

Phillmore

Klein

2019

Hippocampus

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“…Finally, this study also showed that noise-exposed 5 dpf larvae (under CN 150 ) displayed impaired innate Spontaneous Alternation Behaviour compared to control individuals. Bögli et al, (2017) 87 effectively established the presence of SAB in larval zebra sh (6 dpf) suggesting the presence of early mnestic capabilities. At this developmental stage (4 to 5 dpf), the hippocampal-like pallium develops 88 , and this brain structure is known to be related with navigation and spatiotemporal sensing in shes 89,90 .…”

Section: Discussionmentioning

confidence: 97%

“…Larval zebra sh were further tested regarding the Spontaneous Alternation Behaviour (SAB), which consists on the tendency of animals to alternate their movement directions in consecutive turns when navigating through their environment. The SAB was assessed in a 3D printed T-maze designed based on Bögli and Huang (2017) 107 and consisted in two starting arms converging into a main arm that bifurcated in the end into two goal arms, each leading to a pool (Fig. 5A).…”

Section: Spontaneous Alternation Behaviour Assaymentioning

confidence: 99%

Impact of noise exposure on development, physiological stress and behavioural patterns in larval zebrafish

LARA¹,

VASCONCELOS²

2020

Preprint

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Noise pollution is increasingly present in aquatic ecosystems, causing detrimental effects on growth, physiology and behaviour of organisms. However, limited information exists on how this stressor affects animals in early ontogeny, a critical period for development and establishment of phenotypic traits.We tested the effects of chronic noise exposure to increasing levels (130 and 150 dB re 1 μPa, continuous white noise) and different temporal regimes on larval zebrafish (Danio rerio), an important vertebrate model in ecotoxicology.The acoustic treatments did not affect general development or hatching but higher noise levels led to increased mortality. The cardiac rate, yolk sac consumption and cortisol levels increased significantly with increasing noise level at both 3 and 5 dpf (days post fertilization). Variation in noise temporal patterns (different random noise periods to simulate shipping activity) suggested that time regime adopted is more important than the total duration of noise exposure is important to down-regulate physiological stress. Moreover, 5 dpf larvae exposed to 150 dB continuous noise displayed increased dark avoidance in anxiety-related dark/light preference test and impaired spontaneous alternation behaviour.We provide first evidence of noise-induced physiological stress and behavioural disturbance in larval zebrafish, showing that both noise amplitude and timing negatively impact key developmental endpoints in early ontogeny.

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“…This is likely related to how spontaneous alternation has evolved into a standard test for memory in transgenic rodent models of human conditions (e.g., O'Leary, Hussin, Gunn, & Brown, 2018;Snider & Obrietan, 2018) or evaluating effects of pharmacological agents (Hughes, 2004). However, spontaneous alternation has been observed in several other nonhuman organisms, including larval zebrafish (Bögli & Huang, 2017) and black molly fish (Creson, Woodruff, Ferslew, Rasch, & Monaco, 2003), ants (Czaczkes, Koch, Fröber, & Dreisbach, 2018), fruit flies (Drosophila melanogaster; Lewis, Negelspach, Kaladchibachi, Cowen, & Fernandez, 2017), paramecium (Harvey & Bovell, 2006), marmosets (Izumi, Tsuchida, & Yamaguchi, 2013), and in some species of crab (but not others-Balcı, Ramey-Balcı, & Ruamps, 2014;Ramey, Teichman, Oleksiak, & Balci, 2009). In other species, evidence for spontaneous alternation behavior is debatable (lemurs, Dal-Pan et al, 2011;chicks, Hayes & Warren, 1963;hens, Haskell, Forkman & Waddington, 1998) or contrary (e.g., pigeons, Hughes, 1989).…”

Section: Comparative (Phylogeny)mentioning

confidence: 99%

Erratum

2020

Hippocampus

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Spontaneous alternation behavior in larval zebrafish

Cited by 8 publications

References 39 publications

The puzzle of spontaneous alternation and inhibition of return: How they might fit together

The puzzle of spontaneous alternation and inhibition of return: How they might fit together

Impact of noise exposure on development, physiological stress and behavioural patterns in larval zebrafish

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