Antennal-lobe Neurons in the Moth Helicoverpa Armigera: Morphological Features of Projection Neurons, Local Interneurons, and Centrifugal Neurons

Overview

Journal J Comp Neurol

Specialty Neurology

Date 2020 Sep 19

PMID 32949023

Citations 6

Authors

Jonas Hansen Kymre

Christoffer Nerland Berge

Xi Chu

Elena Ian

Bente G Berg

Affiliations

Soon will be listed here.

Abstract

The relatively large primary olfactory center of the insect brain, the antennal lobe (AL), contains several heterogeneous neuronal types. These include projection neurons (PNs), providing olfactory information to higher-order neuropils via parallel pathways, and local interneurons (LNs), which provide lateral processing within the AL. In addition, various types of centrifugal neurons (CNs) offer top-down modulation onto the other AL neurons. By performing iontophoretic intracellular staining, we collected a large number of AL neurons in the moth, Helicoverpa armigera, to examine the distinct morphological features of PNs, LNs, and CNs. We characterize 190 AL neurons. These were allocated to 25 distinct neuronal types or sub-types, which were reconstructed and placed into a reference brain. In addition to six PN types comprising 15 sub-types, three LN and seven CN types were identified. High-resolution confocal images allowed us to analyze AL innervations of the various reported neurons, which demonstrated that all PNs innervating ventroposterior glomeruli contact a protocerebral neuropil rarely targeted by other PNs, that is the posteriorlateral protocerebrum. We also discuss the functional roles of the distinct CNs, which included several previously uncharacterized types, likely involved in computations spanning from multisensory processing to olfactory feedback signalization into the AL.

Citing Articles

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Organization of the parallel antennal-lobe tracts in the moth.

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Distinct protocerebral neuropils associated with attractive and aversive female-produced odorants in the male moth brain.

Kymre J, Liu X, Ian E, Berge C, Wang G, Berg B Elife. 2021; 10.

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