Hanna Zwaka scite author profile

Olfactory sensory neurons (OSNs) are constantly exposed to pathogens, including viruses. However, serious infection of the brain by the olfactory route rarely occurs. When OSNs detect a virus, they coordinate local antiviral immune responses to stop virus progression into the brain. Despite effective immune control at the olfactory periphery, pathogen-triggered neuronal signals reach the CNS via initial outputs in the olfactory bulb (OB). We hypothesized that neuronal detection of a virus by OSNs initiates neuroimmune responses in the OB that prevent pathogen invasion. Using zebrafish (Danio rerio) as a model, we demonstrate viral-specific neuronal activation of OSNs projecting into the OB, indicating that OSNs are electrically activated by viruses. Further, behavioral changes are seen in both adult and larval zebrafish after viral exposure. By profiling the transcription of single cells in the OB after OSNs are exposed to virus, we found that both microglia and neurons enter a protective state. Cells with microglia and macrophage markers in the OB respond within minutes of nasal viral delivery followed by striking responses in neuronal clusters characterized by decreased expression of neuronal differentiation factors and enrichment of genes in the neuropeptide signaling pathway, especially the known antimicrobial pacap. We confirm that PACAP is antiviral in vitro and that PACAP expression increases in the OB 1 day post-viral treatment. Our work reveals how encounters with viruses in the olfactory periphery shape the vertebrate brain by inducing antimicrobial programs in neurons and by altering host behavior.

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Covert Attention to Obstacles Biases Zebrafish Escape Direction

Zwaka

McGinnis

Pflitsch

et al. 2022

SSRN Journal

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Covert attention to obstacles biases zebrafish escape direction

Zwaka

McGinnis

Pflitsch

et al. 2022

Preprint

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To study the evolutionary origins of object perception, we investigated whether a primitive vertebrate, the larval zebrafish, is sensitive to the presence of obstacles. The zebrafish, which has become a useful model to study brain-wide circuit dynamics, executes fast escape swims when in danger of predation. We posited that collisions with solid objects during escape would be maladaptive to the zebrafish, and therefore the direction of escape swims should be informed by the locations of barriers. To answer this question, we developed a novel closed-loop high-speed imaging rig outfitted with barriers of various qualities. Using this system, we show that when larval zebrafish escape in response to a non-directional vibrational stimulus, they use visual scene information to avoid collisions with obstacles. Our study demonstrates that fish compute absolute distance to obstacles, as distant barriers outside of collision range elicit less bias than nearby collidable barriers that occupy the same visual field. The computation of barrier features is covert, as the fish’s reaction to barriers during routine swimming does not predict that they will avoid barriers when escaping. Finally, through two-photon laser ablations, we reveal a novel excitatory input from the visual system to Mauthner cells in the brainstem escape network that is responsible for escape direction bias. We propose that zebrafish construct “object solidity” via an integrative visual computation that is more complex than retinal occupancy alone, suggesting a primitive understanding of object features and possibly the origins of a structured model of the physical world.

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Hanna Zwaka

Visual object detection biases escape trajectories following acoustic startle in larval zebrafish

Olfactory detection of viruses shapes brain immunity and behavior in zebrafish

Covert Attention to Obstacles Biases Zebrafish Escape Direction

Covert attention to obstacles biases zebrafish escape direction

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