Tcf7l2 Is Required for Left-Right Asymmetric Differentiation of Habenular Neurons

Hüsken, Ulrike; Stickney, Heather L.; Gestri, Gaia; Bianco, Isaac H.; Faro, Ana; Young, Rodrigo; Roussigné, Myriam; Hawkins, Thomas A.; Beretta, Carlo A.; Brinkmann, Irena; Paolini, Alessio; Jacinto, Raquel; Albadri, Shahad; Dreosti, Elena; Tsalavouta, Matina; Schwarz, Quenten; Cavodeassi, Florencia; Barth, Anukampa; Lü, Wen; Zhang, Bo; Blader, Patrick; Yaksi, Emre; Poggi, Lucia; Žigman, Mihaela; Lin, Shuo; Wilson, Stephen W.; Carl, Matthias

doi:10.1016/j.cub.2014.08.006

Cited by 53 publications

(73 citation statements)

References 45 publications

(106 reference statements)

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“…Ablation of the parapineal, an accessory organ to the pineal, results in right isomerization of the dHb, in which both nuclei develop symmetrically with right identity [12, 13]. Conversely, loss of canonical Wnt signaling in homozygous tcf7l2 mutants causes left isomerization of the dHb [14]. Larvae with right isomerized dHb exhibit a significant reduction in locomotor activity post-shock (Figure 3A,B), increased duration of freezing (Figure 3C), and higher cortisol levels (Figure 3D), relative to controls with normal situs ( situs solitus ).…”

Section: Resultsmentioning

confidence: 99%

Left Habenular Activity Attenuates Fear Responses in Larval Zebrafish

et al. 2017

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Summary Fear responses are defensive states that ensure survival of an organism in the presence of a threat. Perception of an aversive cue causes changes in behavior and physiology, such as freezing and elevated cortisol, followed by a return to the baseline state when the threat is evaded [1]. Neural systems that elicit fear behaviors include the amygdala, hippocampus and medial prefrontal cortex. However, aside from a few examples, little is known about brain regions that promote recovery from an aversive event [2]. Previous studies had implicated the dorsal habenular nuclei in regulating fear responses and boldness in zebrafish [3–7]. We now show that perturbation of the inherent left-right (L-R) asymmetry of the dorsal habenulo-interpeduncular (dHb-IPN) pathway at larval stages expedites the return of locomotor activity following an unexpected negative stimulus, electric shock. Severing habenular efferents to the IPN, or only those from the left dHb, prolongs the freezing behavior that follows shock. Individuals with symmetric, right isomerized dHb also exhibit increased freezing. In contrast, larvae that have symmetric, left-isomerized dHb, or in which just the left dHb-IPN projection is optogenetically activated, rapidly resume swimming post shock. In vivo calcium imaging reveals a neuronal subset, predominantly in the left dHb, whose activation is correlated with resumption of swimming. The results demonstrate functional specialization of the left dHb-IPN pathway in attenuating the response to fear.

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Section: Resultsmentioning

confidence: 99%

Left Habenular Activity Attenuates Fear Responses in Larval Zebrafish

et al. 2017

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“…The functional specialization of habenular neurons clearly correlates with the previously characterized neuroanatomical asymmetry of the habenulae. Indeed, manipulations that result in embryos with right or left habenular isomerism lead to a loss of habenular responsiveness to light or odor, respectively (49,82). Thus, correct LR asymmetry in the dorsal habenula is crucial to segregate the processing of visual and olfactory stimuli.…”

Section: The Zebrafish Epithalamus: a Model To Link Neuronal Asymmetrmentioning

confidence: 96%

“…However, the molecular mechanisms underlying the timing of neuronal birth, its impact on habenular specification, and its link with pp function are not clear. Studies from the Wilson and, more recently, Carl labs have revealed that the acquisition of dHbl or dHbm fate requires the precise control of Wnt signaling (26,81,82) (Table 1). Indeed, genetic contexts that result in increased Wnt signaling (axin1 mutant) lead to a double right habenular phenotype (26).…”

Section: Figurementioning

confidence: 97%

Asymmetry of the Brain: Development and Implications

et al. 2015

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Although the left and right hemispheres of our brains develop with a high degree of symmetry at both the anatomical and functional levels, it has become clear that subtle structural differences exist between the two sides and that each is dominant in processing specific cognitive tasks. As the result of evolutionary conservation or convergence, lateralization of the brain is found in both vertebrates and invertebrates, suggesting that it provides significant fitness for animal life. This widespread feature of hemispheric specialization has allowed the emergence of model systems to study its development and, in some cases, to link anatomical asymmetries to brain function and behavior. Here, we present some of what is known about brain asymmetry in humans and model organisms as well as what is known about the impact of environmental and genetic factors on brain asymmetry development. We specifically highlight the progress made in understanding the development of epithalamic asymmetries in zebrafish and how this model provides an exciting opportunity to address brain asymmetry at different levels of complexity.

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“…Experiments of PpO ablation and mutant conditions that delay the onset of PpO asymmetric translocation reveal a requirement of an asymmetrically positioned PpO for the subsequent development of a sub-type of asymmetries in the Hb ( figure 4a(iii)) [40][41][42]58]. These asymmetries result from L-R differences in cell fate decisions towards two main neuronal identities, and it is possible that the PpO modulates these fate decisions as well as the timing of asymmetric habenular neurogenesis by acting on the Notch and Wnt signalling pathways [43,44].…”

Section: Nodal As Laterality Modulator In Midlineunpaired Structuresmentioning

confidence: 99%

Nodal signalling and asymmetry of the nervous system

Signore

Palma

Concha

2016

Phil. Trans. R. Soc. B

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One contribution of 17 to a theme issue 'Provocative questions in left -right asymmetry'. The role of Nodal signalling in nervous system asymmetry is still poorly understood. Here, we review and discuss how asymmetric Nodal signalling controls the ontogeny of nervous system asymmetry using a comparative developmental perspective. A detailed analysis of asymmetry in ascidians and fishes reveals a critical context-dependency of Nodal function and emphasizes that bilaterally paired and midline-unpaired structures/organs behave as different entities. We propose a conceptual framework to dissect the developmental function of Nodal as asymmetry inducer and laterality modulator in the nervous system, which can be used to study other types of body and visceral organ asymmetries. Using insights from developmental biology, we also present novel evolutionary hypotheses on how Nodal led the evolution of directional asymmetry in the brain, with a particular focus on the epithalamus. We intend this paper to provide a synthesis on how Nodal signalling controls left-right asymmetry of the nervous system. This article is part of the themed issue 'Provocative questions in leftright asymmetry'.

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Tcf7l2 Is Required for Left-Right Asymmetric Differentiation of Habenular Neurons

Cited by 53 publications

References 45 publications

Left Habenular Activity Attenuates Fear Responses in Larval Zebrafish

Left Habenular Activity Attenuates Fear Responses in Larval Zebrafish

Asymmetry of the Brain: Development and Implications

Nodal signalling and asymmetry of the nervous system

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