Dopaminergic modulation of phase reversal in desert locusts
Dopaminergic modulation of phase reversal in desert locusts
Phenotypic plasticity allows animals to modify their behavior, physiology, and morphology to adapt to environmental change. The global pest, the desert locust, shows two extreme phenotypes; a solitarious phase that is relatively harmless and a gregarious phase that forms swarms and causes extensive agricultural and economic damage. In the field, environmental conditions can drive isolated animals into crowded populations and previous studies have identified the biogenic amine serotonin as a key determinant of this transition. Here we take an integrated approach to investigate the neurochemical, physiological, and behavioral correlates defined by a laboratory based paradigm that mimics facets of swarm break down as gregarious locusts become isolated. Following isolation there was an increased propensity of locusts to avoid conspecifics, and show a reduced locomotion. Changes in choice behavior occurred within 1 h of isolation although isolation-related changes progressed with increased isolation time. Isolation was accompanied by changes in the levels of the biogenic amines dopamine, octopamine, and serotonin within the CNS within 1 h. Dopamine levels were higher in isolated animals and we focused on the role played by this transmitter in synaptic changes that may underpin solitarization. Dopamine reduced synaptic efficacy at a key central synapse between campaniform sensilla (CS) and a fast extensor tibiae motor neuron that is involved in limb movement. We also show that dopamine injection into the haemocoel was sufficient to induce solitarious-like behavior in otherwise gregarious locusts. Further, injection of a dopamine antagonist, fluphenazine, into isolated locusts induced gregarious-like behavior. This highlights that dopaminergic modulation plays an important role in the plasticity underpinning phase transition and sets a context to deepen the understanding of the complementary role that distinct neuromodulators play in polyphenism in locusts.
grasshopper, polyphenism, swarming, neural network, plasticity, dopamine
1-15
Alessi, Ahmad M.
3b18d7ec-ec30-4bdf-bed0-1d0b68cc388e
O'Connor, Vincent
8021b06c-01a0-4925-9dde-a61c8fe278ca
Aonuma, Hitoshi
a8b20ebb-d63c-4bd6-8a58-b0773ddaae10
Newland, Philip L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb
7 November 2014
Alessi, Ahmad M.
3b18d7ec-ec30-4bdf-bed0-1d0b68cc388e
O'Connor, Vincent
8021b06c-01a0-4925-9dde-a61c8fe278ca
Aonuma, Hitoshi
a8b20ebb-d63c-4bd6-8a58-b0773ddaae10
Newland, Philip L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb
Alessi, Ahmad M., O'Connor, Vincent, Aonuma, Hitoshi and Newland, Philip L.
(2014)
Dopaminergic modulation of phase reversal in desert locusts.
Frontiers in Behavioral Neuroscience, 8 (371), .
(doi:10.3389/fnbeh.2014.00371).
(PMID:25426037)
Abstract
Phenotypic plasticity allows animals to modify their behavior, physiology, and morphology to adapt to environmental change. The global pest, the desert locust, shows two extreme phenotypes; a solitarious phase that is relatively harmless and a gregarious phase that forms swarms and causes extensive agricultural and economic damage. In the field, environmental conditions can drive isolated animals into crowded populations and previous studies have identified the biogenic amine serotonin as a key determinant of this transition. Here we take an integrated approach to investigate the neurochemical, physiological, and behavioral correlates defined by a laboratory based paradigm that mimics facets of swarm break down as gregarious locusts become isolated. Following isolation there was an increased propensity of locusts to avoid conspecifics, and show a reduced locomotion. Changes in choice behavior occurred within 1 h of isolation although isolation-related changes progressed with increased isolation time. Isolation was accompanied by changes in the levels of the biogenic amines dopamine, octopamine, and serotonin within the CNS within 1 h. Dopamine levels were higher in isolated animals and we focused on the role played by this transmitter in synaptic changes that may underpin solitarization. Dopamine reduced synaptic efficacy at a key central synapse between campaniform sensilla (CS) and a fast extensor tibiae motor neuron that is involved in limb movement. We also show that dopamine injection into the haemocoel was sufficient to induce solitarious-like behavior in otherwise gregarious locusts. Further, injection of a dopamine antagonist, fluphenazine, into isolated locusts induced gregarious-like behavior. This highlights that dopaminergic modulation plays an important role in the plasticity underpinning phase transition and sets a context to deepen the understanding of the complementary role that distinct neuromodulators play in polyphenism in locusts.
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Accepted/In Press date: 17 October 2014
Published date: 7 November 2014
Keywords:
grasshopper, polyphenism, swarming, neural network, plasticity, dopamine
Organisations:
Biomedicine
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Local EPrints ID: 377488
URI: http://eprints.soton.ac.uk/id/eprint/377488
ISSN: 1662-5153
PURE UUID: 08c0e2fd-9b58-4f20-8e8f-9ec98ab7fcba
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Date deposited: 15 Jun 2015 10:53
Last modified: 15 Mar 2024 03:04
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Author:
Ahmad M. Alessi
Author:
Hitoshi Aonuma
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