Malalaniaina Rakotobe scite author profile

et al. 2018

The habenulo-interpeduncular system (HIPS) is now recognized as a critical circuit modulating aversion, reward, and social behavior. There is evidence that dysfunction of this circuit leads to psychiatric disorders. Because psychiatric diseases may originate in developmental abnormalities, it is crucial to investigate the developmental mechanisms controlling the formation of the HIPS. Thus far, this issue has been the focus of limited studies. Here, we explored the developmental processes underlying the formation of the medial habenula (MHb) and its unique output, the interpeduncular nucleus (IPN), in mice independently of their gender. We report that the Otx2 homeobox gene is essential for the proper development of both structures. We show that MHb and IPN neurons require Otx2 at different developmental stages and, in both cases, Otx2 deletion leads to disruption of HIPS subcircuits. Finally, we show that Otx2 ϩ neurons tend to be preferentially interconnected. This study reveals that synaptically connected components of the HIPS, despite radically different developmental strategies, share high sensitivity to Otx2 expression.

show abstract

Central role of the habenulo-interpeduncular system in the neurodevelopmental basis of susceptibility and resilience to anxiety in mice

Rakotobe¹,

Fjerdingstad²,

Ruiz-Reig³

et al. 2023

Preprint

0

View full text Add to dashboard Cite

Having experienced stress during sensitive periods of brain development strongly impacts how individuals cope with later stress. Many become more prone to develop anxiety or depression, but some appear resilient. The as-yet-unknown mechanisms underlying these differences may lie in how genes and environmental stressors interact to shape the circuits controlling emotions. Here, we investigated the role of the habenulo-interpeduncular system (HIPS), a critical node of reward circuits, in early stress-induced anxiety in mice. Based on immediate early gene expression, we found that a subcircuit of this system, characterized by Otx2 expression, is particularly sensitive to chronic restraint stress during the peripubertal period, and that this induces hypersensitivity of the HIPS to later stress and susceptibility to develop anxiety. We also show that conditional knockout of Otx2 restricted to the HIPS in mice counteracts these effects of stress. Together, these results demonstrate that a genetic factor, Otx2, and stress interact around puberty to shape the stress sensitivity of the HIPS, revealing this sensitivity as a key modulator of susceptibility/resilience to develop anxiety.

show abstract

Role of the habenulo-interpeduncular system in the neurodevelopmental basis of susceptibility and resilience to stress-induced anxiety

Rakotobe¹,

Fjerdingstad²,

Ruiz-Reig³

et al. 2022

Preprint

0

View full text Add to dashboard Cite

Experiencing stress during sensitive periods of brain development has a major impact on how individuals cope with later stress. Although many become more prone to develop anxiety or depression, some appear resilient. The mechanisms underlying these differences are unknown. Key answers may lie in how genetic and environmental stressors interact to shape the circuits controlling emotions. Here we studied the role of the habenulo-interpeducuncular system (HIPS), a critical node of reward circuits, in early stress-induced anxiety. We found that a subcircuit of this system, characterized by Otx2 expression, is particularly responsive to chronic stress during puberty, which induces HIPS hypersensitivity to later stress and susceptibility to develop anxiety. We further show that Otx2 deletion restricted to the HIPS counteracts these effects of stress. Together, these results demonstrate that Otx2 and stress interact, around puberty, to shape the HIPS stress-response, revealed here as a key modulator of susceptibility/resilience to develop anxiety.

show abstract

Central role of the habenulo-interpeduncular system in the neurodevelopmental basis of susceptibility and resilience to anxiety

Rakotobe¹,

Fjerdingstad²,

Ruiz-Reig³

et al. 2021

Preprint

0

View full text Add to dashboard Cite

Experiencing stress during sensitive periods of brain development has a major impact on how individuals cope with later stress. Although many become more prone to develop anxiety or depression, some appear resilient. The mechanisms underlying these differences are unknown. Key answers may lie in how genetic and environmental stressors interact to shape the circuits controlling emotions. Here we studied the role of the habenulo-interpeducuncular system (HIPS), a critical node of reward circuits, in early stress-induced anxiety. We found that a subcircuit of this system, characterized by Otx2 expression, is particularly responsive to chronic stress during puberty, which induces HIPS hypersensitivity to later stress and susceptibility to develop anxiety. We further show that Otx2 deletion restricted to the HIPS counteracts these effects of stress. Together, these results demonstrate that Otx2 and stress interact, around puberty, to shape the HIPS stress-response, revealed here as a key modulator of susceptibility/resilience to develop anxiety.

show abstract

Role of the habenulo-interpeduncular system in the neurodevelopmental basis of susceptibility and resilience to stressinduced anxiety

Rakotobe¹,

Fjerdingstad²,

Ruiz-Reig³

et al. 2022

Preprint

0

View full text Add to dashboard Cite

Experiencing stress during sensitive periods of brain development has a major impact on how individuals cope with later stress. Although many become more prone to develop anxiety or depression, some appear resilient. The mechanisms underlying these differences are unknown. Key answers may lie in how genetic and environmental stressors interact to shape the circuits controlling emotions. Here we studied the role of the habenulo-interpeducuncular system (HIPS), a critical node of reward circuits, in early stress-induced anxiety. We found that a subcircuit of this system, characterized by Otx2 expression, is particularly responsive to chronic stress during puberty, which induces HIPS hypersensitivity to later stress and susceptibility to develop anxiety. We further show that Otx2 deletion restricted to the HIPS counteracts these effects of stress. Together, these results demonstrate that Otx2 and stress interact, around puberty, to shape the HIPS stress-response, revealed here as a key modulator of susceptibility/resilience to develop anxiety.

show abstract