Vanessa M. Burns scite author profile

Prolonged behavioral challenges can cause animals to switch from active to passive coping strategies to manage effort-expenditure during stress; such normally adaptive behavioral state transitions can become maladaptive in psychiatric disorders such as depression. The underlying neuronal dynamics and brainwide interactions important for passive coping have remained unclear. Here, we develop a paradigm to study these behavioral state transitions at cellular-resolution across the entire vertebrate brain. Using brainwide imaging in zebrafish, we observed that the transition to passive coping is manifested by progressive activation of neurons in the ventral (lateral) habenula. Activation of these ventral-habenula neurons suppressed downstream neurons in the serotonergic raphe nucleus and caused behavioral passivity, whereas inhibition of these neurons prevented passivity. Data-driven recurrent neural network modeling pointed to altered intra-habenula interactions as a contributory mechanism. These results demonstrate ongoing encoding of experience features in the habenula, which guides recruitment of downstream networks and imposes a passive coping behavioral strategy.

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SPED Light Sheet Microscopy: Fast Mapping of Biological System Structure and Function

Tomer

Lovett-Barron

Kauvar

et al. 2015

Cell

234

165

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The goal of understanding living nervous systems has driven interest in high-speed and large field-of-view volumetric imaging at cellular resolution. Light sheet microscopy approaches have emerged for cellular-resolution functional brain imaging in small organisms such as larval zebrafish, but remain fundamentally limited in speed. Here, we have developed SPED light sheet microscopy, which combines large volumetric field-of-view via an extended depth of field with the optical sectioning of light sheet microscopy, thereby eliminating the need to physically scan detection objectives for volumetric imaging. SPED enables scanning of thousands of volumes-per-second, limited only by camera acquisition rate, through the harnessing of optical mechanisms that normally result in unwanted spherical aberrations. We demonstrate capabilities of SPED microscopy by performing fast sub-cellular resolution imaging of CLARITY mouse brains and cellular-resolution volumetric Ca(2+) imaging of entire zebrafish nervous systems. Together, SPED light sheet methods enable high-speed cellular-resolution volumetric mapping of biological system structure and function.

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Ancestral Circuits for the Coordinated Modulation of Brain State

Lovett-Barron¹,

Andalman²,

Allen³

et al. 2017

Cell

152

144

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SUMMARY Internal states of the brain profoundly influence behavior. Fluctuating states such as alertness can be governed by neuromodulation, but the underlying mechanisms and cell types involved are not fully understood. We developed a method to globally screen for cell types involved in behavior by integrating brain-wide activity imaging with high-content molecular phenotyping and volume registration at cellular resolution. We used this method (MultiMAP) to record from 22 neuromodulatory cell types in behaving zebrafish during a reaction-time task that reports alertness. We identified multiple monoaminergic, cholinergic, and peptidergic cell types linked to alertness and found that activity in these cell types was mutually correlated during heightened alertness. We next recorded from and controlled homologous neuromodulatory cells in mice; alertness-related cell-type dynamics exhibited striking evolutionary conservation and modulated behavior similarly. These experiments establish a method for unbiased discovery of cellular elements underlying behavior and reveal an evolutionarily conserved set of diverse neuromodulatory systems that collectively govern internal state.

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Iterative In Situ Click Chemistry Creates Antibody‐like Protein‐Capture Agents

et al. 2009

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Special agents for protein capture: Iterative in situ click chemistry (see scheme for the tertiary ligand screen) and the one‐bead–one‐compound method for the creation of a peptide library enable the fragment‐based assembly of selective high‐affinity protein‐capture agents. The resulting ligands are water‐soluble and stable chemically, biochemically, and thermally. They can be produced in gram quantities through copper(I)‐catalyzed cycloaddition.

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Iterative In Situ Click Chemistry Creates Antibody‐like Protein‐Capture Agents

et al. 2009

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Auf Proteinfang: Iterative Klick‐Reaktionen (siehe Schema des dritten Liganden‐Screenings) und eine Methode zum Aufbau von Bibliotheken mit einer Verbindung pro Kügelchen ermöglichten die Synthese von selektiven, hoch affinen Proteineinfangagentien aus einzelnen Fragmenten. Die resultierenden Liganden sind wasserlöslich und (bio)chemisch sowie thermisch stabil. Durch Kupfer(I)‐katalysierte Cycloadditionen sind sie im Gramm‐Maßstab zugänglich.

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Vanessa M. Burns

Neuronal Dynamics Regulating Brain and Behavioral State Transitions

SPED Light Sheet Microscopy: Fast Mapping of Biological System Structure and Function

Ancestral Circuits for the Coordinated Modulation of Brain State

Iterative In Situ Click Chemistry Creates Antibody‐like Protein‐Capture Agents

Iterative In Situ Click Chemistry Creates Antibody‐like Protein‐Capture Agents

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