Dendritic signal integration in a Drosophila Mushroom Body Output Neuron (MBON) essential for learning and memory

The ability to associate neutral stimuli with either positive or negative valence forms the basis for most forms of decision making. Long-term memory formation then enables manifestation of these associations to guide behavioral responses over prolonged periods of time. Despite recent advances in the understanding of the neuronal circuits and cellular mechanisms controlling memory formation, the computational principles at the level of individual information processing modules remain largely unknown. Here we use the Drosophila mushroom body (MB), the learning and memory center of the fly, as a model system to elucidate the cellular basis of memory computation. Recent studies resolved the precise synaptic connectome of the MB and identified the synaptic connections between Kenyon cells (KCs) and mushroom body output neurons (MBONs) as the sites of sensory association. We build a realistic computational model of the MBON-α3 neuron including precise synaptic connectivity to the 948 upstream KCs innervating the αβ MB lobes. To model membrane properties reflecting in vivo parameters we performed patch-clamp recording of MBON-α3. Based on the in vivo data we model synaptic input of individual cholinergic KC-MBON synapses by local conductance changes at the dendritic sections defined by the electron microscopic reconstruction. Modelling of activation of all individual synapses confirms prior results demonstrating that MBON-α3 is electrotonically compact. As a likely consequence of this compactness, activation pattern of individual KCs with identical numbers of synaptic connection but innervating different sections of the MBON-α3 dendritic tree result in highly similar depolarization voltages. Furthermore, we show that KC input patterns reflecting physiological activation by individual odors in vivo are sufficient to robustly drive MBON spiking. Our data suggest that the sparse innervation by KCs can control or modulate MBON activity in an efficient manner, with minimal requirements on the specificity of synaptic localization. This KC-MBON architecture therefore provides a suitable module to incorporate different olfactory associative memories based on stochastically encoded odor-specificity of KCs.

[1]  Liang Liang,et al.  The Q System: A Repressible Binary System for Transgene Expression, Lineage Tracing, and Mosaic Analysis , 2010, Cell.

[2]  Burak Tepe,et al.  Drosophila Voltage-Gated Sodium Channels Are Only Expressed in Active Neurons and Are Localized to Distal Axonal Initial Segment-like Domains , 2020, The Journal of Neuroscience.

[3]  Alexander Borst,et al.  Optogenetic and Pharmacologic Dissection of Feedforward Inhibition in Drosophila Motion Vision , 2014, The Journal of Neuroscience.

[4]  Glenn C. Turner,et al.  Olfactory representations by Drosophila mushroom body neurons. , 2008, Journal of neurophysiology.

[5]  Omar A. Hafez,et al.  Integration of Odor-Induced Activity of Kenyon Cells in an Electrotonically Compact Drosophila Mushroom Body Output Neuron (MBON) , 2019, bioRxiv.

[6]  Yoshinori Aso,et al.  Dopaminergic neurons write and update memories with cell-type-specific rules , 2016, eLife.

[7]  Ernst Niebur Electrical properties of cell membranes , 2008, Scholarpedia.

[8]  Scott Waddell,et al.  Sweet Taste and Nutrient Value Subdivide Rewarding Dopaminergic Neurons in Drosophila , 2015, Current Biology.

[9]  Raphael Cohn,et al.  Coordinated and Compartmentalized Neuromodulation Shapes Sensory Processing in Drosophila , 2015, Cell.

[10]  G. Rubin,et al.  The neuronal architecture of the mushroom body provides a logic for associative learning , 2014, eLife.

[11]  Alexander Borst,et al.  The intrinsic electrophysiological characteristics of fly lobula plate tangential cells: I. Passive membrane properties , 1996, Journal of Computational Neuroscience.

[12]  Ernst Niebur,et al.  Neuronal cable theory , 2008, Scholarpedia.

[13]  Ann-Shyn Chiang,et al.  A Map of Olfactory Representation in the Drosophila Mushroom Body , 2007, Cell.

[14]  Thomas Preat,et al.  Two independent mushroom body output circuits retrieve the six discrete components of Drosophila aversive memory. , 2015, Cell reports.

[15]  Nathan W. Gouwens,et al.  Signal Propagation in Drosophila Central Neurons , 2009, The Journal of Neuroscience.

[16]  Benjamin Escribano,et al.  Selective suppression and recall of long-term memories in Drosophila , 2019, PLoS biology.

[17]  Bart R. H. Geurten,et al.  Visualization of a Distributed Synaptic Memory Code in the Drosophila Brain , 2020, Neuron.

[18]  M Heisenberg,et al.  Associative odor learning in Drosophila abolished by chemical ablation of mushroom bodies. , 1994, Science.

[19]  Julie H. Simpson,et al.  A GAL4-driver line resource for Drosophila neurobiology. , 2012, Cell reports.

[20]  G. Rubin,et al.  Refinement of Tools for Targeted Gene Expression in Drosophila , 2010, Genetics.

[21]  Raphael Cohn,et al.  Distinct Dopamine Receptor Pathways Underlie the Temporal Sensitivity of Associative Learning , 2019, Cell.

[22]  Paola Cognigni,et al.  Do the right thing: neural network mechanisms of memory formation, expression and update in Drosophila , 2018, Current Opinion in Neurobiology.

[23]  K. Broadie,et al.  Targeted expression of tetanus toxin light chain in Drosophila specifically eliminates synaptic transmission and causes behavioral defects , 1995, Neuron.

[24]  Gerald M. Rubin,et al.  Heterosynaptic Plasticity Underlies Aversive Olfactory Learning in Drosophila , 2015, Neuron.

[25]  Johannes Felsenberg,et al.  Activity of Defined Mushroom Body Output Neurons Underlies Learned Olfactory Behavior in Drosophila , 2015, Neuron.

[26]  Louis K. Scheffer,et al.  A connectome of a learning and memory center in the adult Drosophila brain , 2017, eLife.

[27]  Kei Ito,et al.  Neuronal assemblies of the Drosophila mushroom body , 2008, The Journal of comparative neurology.

[28]  Sen-Lin Lai,et al.  Genetic mosaic with dual binary transcriptional systems in Drosophila , 2006, Nature Neuroscience.

[29]  Kristin Scott,et al.  Limited taste discrimination in Drosophila , 2010, Proceedings of the National Academy of Sciences.

[30]  Stefan R. Pulver,et al.  Independent Optical Excitation of Distinct Neural Populations , 2014, Nature Methods.

[31]  Scott Waddell,et al.  Light, heat, action: neural control of fruit fly behaviour , 2015, Philosophical Transactions of the Royal Society B: Biological Sciences.

[32]  Nicholas T. Carnevale,et al.  The NEURON Simulation Environment , 1997, Neural Computation.

[33]  Jay Hirsh,et al.  Targeted gene expression in Drosophila dopaminergic cells using regulatory sequences from tyrosine hydroxylase. , 2003, Journal of neurobiology.

[34]  Gerald M. Rubin,et al.  Plasticity-driven individualization of olfactory coding in mushroom body output neurons , 2015, Nature.

[35]  Robert A. A. Campbell,et al.  Cellular-Resolution Population Imaging Reveals Robust Sparse Coding in the Drosophila Mushroom Body , 2011, The Journal of Neuroscience.

[36]  G. Rubin,et al.  Mushroom body efferent neurons responsible for aversive olfactory memory retrieval in Drosophila , 2011, Nature Neuroscience.

[37]  D. O'Dowd,et al.  Fast Synaptic Currents in Drosophila Mushroom Body Kenyon Cells Are Mediated by α-Bungarotoxin-Sensitive Nicotinic Acetylcholine Receptors and Picrotoxin-Sensitive GABA Receptors , 2003, The Journal of Neuroscience.

[38]  Oliver Barnstedt,et al.  Aversive Learning and Appetitive Motivation Toggle Feed-Forward Inhibition in the Drosophila Mushroom Body , 2016, Neuron.

[39]  Scott Waddell,et al.  Olfactory learning skews mushroom body output pathways to steer behavioral choice in Drosophila , 2015, Current Opinion in Neurobiology.

[40]  Kristin Scott,et al.  Gustatory Learning and Processing in the Drosophila Mushroom Bodies , 2015, The Journal of Neuroscience.

[41]  Sharon Crook,et al.  Modeling the Influence of Ion Channels on Neuron Dynamics in Drosophila , 2015, Front. Comput. Neurosci..

[42]  K. Siwicki,et al.  Mushroom Body Ablation Impairs Short-Term Memory and Long-Term Memory of Courtship Conditioning in Drosophila melanogaster , 1999, Neuron.

[43]  Eric T. Trautman,et al.  A Complete Electron Microscopy Volume of the Brain of Adult Drosophila melanogaster , 2017, Cell.

[44]  G. Rubin,et al.  Mushroom body output neurons encode valence and guide memory-based action selection in Drosophila , 2014, eLife.

[45]  B. Dickson,et al.  A genome-wide transgenic RNAi library for conditional gene inactivation in Drosophila , 2007, Nature.

[46]  G. Rubin,et al.  Shared mushroom body circuits underlie visual and olfactory memories in Drosophila , 2014, eLife.

[47]  C. Morris,et al.  Stretch-activation and stretch-inactivation of Shaker-IR, a voltage-gated K+ channel. , 2001, Biophysical journal.

[48]  Chi-Hon Lee,et al.  Dynamic labelling of neural connections in multiple colours by trans-synaptic fluorescence complementation , 2015, Nature Communications.

[49]  G. Laurent,et al.  Hebbian STDP in mushroom bodies facilitates the synchronous flow of olfactory information in locusts , 2007, Nature.

[50]  W. Quinn,et al.  Classical conditioning and retention in normal and mutantDrosophila melanogaster , 1985, Journal of Comparative Physiology A.

[51]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[52]  Gilles Laurent,et al.  Transformation of Olfactory Representations in the Drosophila Antennal Lobe , 2004, Science.

[53]  Wanhe Li,et al.  Imaging a Population Code for Odor Identity in the Drosophila Mushroom Body , 2013, The Journal of Neuroscience.

[54]  Chia-Lin Wu,et al.  Electrical synapses between mushroom body neurons are critical for consolidated memory retrieval in Drosophila , 2019, PLoS genetics.

[55]  Hiromu Tanimoto,et al.  Two pairs of mushroom body efferent neurons are required for appetitive long-term memory retrieval in Drosophila. , 2013, Cell reports.

[56]  Paul Tchenio,et al.  In vivo large-scale analysis of Drosophila neuronal calcium traces by automated tracking of single somata , 2020, Scientific Reports.

[57]  Daryl M. Gohl,et al.  Layered reward signaling through octopamine and dopamine in Drosophila , 2012, Nature.

[58]  Sreekanth H. Chalasani,et al.  Imaging neural activity in worms, flies and mice with improved GCaMP calcium indicators , 2009, Nature Methods.