An optogenetic analogue of second-order reinforcement in Drosophila
C. Konig, A. Khalili, T. Niewalda, S. Gao, and B. Gerber. Biol Lett, 15 (7):
20190084(2019)Konig, Christian
Khalili, Afshin
Niewalda, Thomas
Gao, Shiqiang
Gerber, Bertram
eng
Research Support, Non-U.S. Gov't
England
2019/07/04
Biol Lett. 2019 Jul 26;15(7):20190084. doi: 10.1098/rsbl.2019.0084. Epub 2019 Jul 3..
DOI: 10.1098/rsbl.2019.0084
Abstract
In insects, odours are coded by the combinatorial activation of ascending pathways, including their third-order representation in mushroom body Kenyon cells. Kenyon cells also receive intersecting input from ascending and mostly dopaminergic reinforcement pathways. Indeed, in Drosophila, presenting an odour together with activation of the dopaminergic mushroom body input neuron PPL1-01 leads to a weakening of the synapse between Kenyon cells and the approach-promoting mushroom body output neuron MBON-11. As a result of such weakened approach tendencies, flies avoid the shock-predicting odour in a subsequent choice test. Thus, increased activity in PPL1-01 stands for punishment, whereas reduced activity in MBON-11 stands for predicted punishment. Given that punishment-predictors can themselves serve as punishments of second order, we tested whether presenting an odour together with the optogenetic silencing of MBON-11 would lead to learned odour avoidance, and found this to be the case. In turn, the optogenetic activation of MBON-11 together with odour presentation led to learned odour approach. Thus, manipulating activity in MBON-11 can be an analogue of predicted, second-order reinforcement.
Konig, Christian
Khalili, Afshin
Niewalda, Thomas
Gao, Shiqiang
Gerber, Bertram
eng
Research Support, Non-U.S. Gov't
England
2019/07/04
Biol Lett. 2019 Jul 26;15(7):20190084. doi: 10.1098/rsbl.2019.0084. Epub 2019 Jul 3.
%0 Journal Article
%1 konig2019optogenetic
%A Konig, C.
%A Khalili, A.
%A Niewalda, T.
%A Gao, S.
%A Gerber, B.
%D 2019
%J Biol Lett
%K Animals myOwn
%N 7
%P 20190084
%R 10.1098/rsbl.2019.0084
%T An optogenetic analogue of second-order reinforcement in Drosophila
%U https://www.ncbi.nlm.nih.gov/pubmed/31266421
%V 15
%X In insects, odours are coded by the combinatorial activation of ascending pathways, including their third-order representation in mushroom body Kenyon cells. Kenyon cells also receive intersecting input from ascending and mostly dopaminergic reinforcement pathways. Indeed, in Drosophila, presenting an odour together with activation of the dopaminergic mushroom body input neuron PPL1-01 leads to a weakening of the synapse between Kenyon cells and the approach-promoting mushroom body output neuron MBON-11. As a result of such weakened approach tendencies, flies avoid the shock-predicting odour in a subsequent choice test. Thus, increased activity in PPL1-01 stands for punishment, whereas reduced activity in MBON-11 stands for predicted punishment. Given that punishment-predictors can themselves serve as punishments of second order, we tested whether presenting an odour together with the optogenetic silencing of MBON-11 would lead to learned odour avoidance, and found this to be the case. In turn, the optogenetic activation of MBON-11 together with odour presentation led to learned odour approach. Thus, manipulating activity in MBON-11 can be an analogue of predicted, second-order reinforcement.
@article{konig2019optogenetic,
abstract = {In insects, odours are coded by the combinatorial activation of ascending pathways, including their third-order representation in mushroom body Kenyon cells. Kenyon cells also receive intersecting input from ascending and mostly dopaminergic reinforcement pathways. Indeed, in Drosophila, presenting an odour together with activation of the dopaminergic mushroom body input neuron PPL1-01 leads to a weakening of the synapse between Kenyon cells and the approach-promoting mushroom body output neuron MBON-11. As a result of such weakened approach tendencies, flies avoid the shock-predicting odour in a subsequent choice test. Thus, increased activity in PPL1-01 stands for punishment, whereas reduced activity in MBON-11 stands for predicted punishment. Given that punishment-predictors can themselves serve as punishments of second order, we tested whether presenting an odour together with the optogenetic silencing of MBON-11 would lead to learned odour avoidance, and found this to be the case. In turn, the optogenetic activation of MBON-11 together with odour presentation led to learned odour approach. Thus, manipulating activity in MBON-11 can be an analogue of predicted, second-order reinforcement.},
added-at = {2024-02-15T15:08:22.000+0100},
author = {Konig, C. and Khalili, A. and Niewalda, T. and Gao, S. and Gerber, B.},
biburl = {https://www.bibsonomy.org/bibtex/22fecac9ce8db87e816b88d2a1e10adea/jvsi_all},
doi = {10.1098/rsbl.2019.0084},
interhash = {c120565796a95aef593cfc40883db2c6},
intrahash = {2fecac9ce8db87e816b88d2a1e10adea},
issn = {1744-957X (Electronic)
1744-9561 (Print)
1744-9561 (Linking)},
journal = {Biol Lett},
keywords = {Animals myOwn},
note = {Konig, Christian
Khalili, Afshin
Niewalda, Thomas
Gao, Shiqiang
Gerber, Bertram
eng
Research Support, Non-U.S. Gov't
England
2019/07/04
Biol Lett. 2019 Jul 26;15(7):20190084. doi: 10.1098/rsbl.2019.0084. Epub 2019 Jul 3.},
number = 7,
pages = 20190084,
timestamp = {2024-02-15T15:08:22.000+0100},
title = {An optogenetic analogue of second-order reinforcement in Drosophila},
type = {Journal Article},
url = {https://www.ncbi.nlm.nih.gov/pubmed/31266421},
volume = 15,
year = 2019
}