Following your nose (Part 2)

By K Meechan

This is the final part of a 2-part post: part 1 gave a brief introduction to the first two layers of the fly olfactory system (ORNs and PNs). Part 2 moves on to look at higher order processing.

While we know a lot about the first layers of the olfactory system, the processing in the Lateral Horn (LH), Mushroom Body (MB) and beyond is less well understood. Many open questions remain as to exactly how odour information is processed by these centres, and how this results in appropriate behavioural responses.

The Lateral Horn

The LH is thought to be involved in mediating innate responses to odours. This is suggested by various experiments that lesion or inactivate the MB – when the MB is not functional, associative learning is impaired, but innate responses to odours are preserved. This suggests that transfer of olfactory information through the LH alone is sufficient for innate responses.

Front view of the fly brain showing the location of the Lateral Horn (red) 
 Image Credit

Consistent with its role in innate behaviour, the areas of the LH that olfactory PNs target are consistent and stereotyped. Different classes of PN target different zones of the LH, allowing different regions to respond to different sets of odours. For example, the posterior-dorsal LH is mainly targeted by PNs that respond to fruit odours, whereas the anterior-ventral LH is mostly targeted by pheromone responsive PNs. Each PN class has a stereotyped axonic branching pattern, allowing it to target the same regions from animal to animal.

Comparison of DA1 PN axon morphology in the LH from a light level study (left) vs an electron microscopy reconstruction (right)
Image Credit: Left – Chiang et al., 2011; Costa et al., 2016 Meshes – Link

Various Lateral Horn Neurons (LHNs) receive input from PNs in the LH. Some of these have broad odour tuning, receiving input from a variety of PN classes, while others are more selective, receiving input from fewer PN types. The number of classes of LHNs, what they respond to, and their role in processing odours is not fully understood.

The Mushroom Body

The MB is a massively parallel processing structure important for associative learning and memory.  Its major component are Kenyon Cells (KCs), whose axons form the different ‘lobes’ of the MB. These approximately 2000 KCs are split into three different classes which form the γ, α′/β′, and α/β lobes.

Diagram showing the position and structure of the Mushroom Body. A – front view of the fly brain showing the position of the Mushroom Bodies (MB) [AL – Antennal Lobe; LH – Lateral Horn; PN – Projection Neuron] B – Subregions of the MB (normal positions shown in A) [dAC – dorsal accessory calyx; vAC – ventral accessory calyx] 
Image Credit: Figure from Aso Y, Hattori D, Yu Y, et al. The neuronal architecture of the mushroom body provides a logic for associative learning. Elife. 2014;3:e04577. doi:10.7554/eLife.04577 released under CC BY 4.0
PNs connect to KCs in a globular structure known as the Mushroom Body Calyx, made up of the dendrites of these ~2000 KCs. Connectivity between PNs and KCs does not appear to be stereotyped, with seemingly random connectivity between specific types of PNs and individual KCs (at least within each class). This is consistent with the MB’s role in learning and memory; these circuits must change their response with experience and therefore cannot be expected to be entirely consistent between different individuals.

Each KC receives on average ~6 inputs from a random selection of PNs. This allows different odours to activate sparse subpopulations of the KCs in the MB – only around 5-20% of all KCs will respond to a given odour.

The major outputs of the MB are the Mushroom Body Output Neurons (MBONs) – a group of only 34 neurons per hemisphere, representing 21 cell types. MBONs receive KC input in specific, segregated domains of the lobes referred to as ‘compartments’. Different MBON types localise their dendrites to different compartments, collectively tiling the MB lobes with little overlap. Different MBON types then project to different regions of the fly brain to eventually mediate a behavioural response (e.g. approach or avoidance of an odour).

The final major contributors to the MB are the dopaminergic neurons (DANs) – over 100 DANs (of 20 types) target their axons to the MB. Like the MBONs, DANs innervate specific compartments of the MB, collectively tiling the MB but overlapping minimally. Therefore, different types of MBON (with dendrites occupying specific compartments) are modulated by the action of different DANs.

Schematic of MB showing key components / information flow to the MB. On the leftmost edge, ORNs expressing the same odorant receptor converge to the same glomerulus of the AL.  There, they synapse to PNs which project to the Mushroom Body calyx. PNs connect to KCs which form the lobes of the MB. KCs connect to MBONs whose dendrites (alongside the axons of specific DANs) occupy specific compartments or subdomains.
Image Credit: Figure from Aso Y, Hattori D, Yu Y, et al. The neuronal architecture of the mushroom body provides a logic for associative learning. Elife. 2014;3:e04577. doi:10.7554/eLife.04577 released under CC BY 4.0

DANs are thought to be key to plasticity in the MB – they release dopamine to signal behavioural significance (e.g. a positive (appetitive) response like from a sugar reward, or a negative (aversive) response like from an electric shock). For example, a number of experiments have shown that direct activation of DANs can substitute for the presence of stimuli like sugar reward / electric shock to induce approach or avoidance in response to an associated odour. The nature of the memory formed (aversive or appetitive) depends on the type of DAN activated.

Simplified schematic of appetitive vs aversive responses to an odour. Left – an appetitive response can be induced by presenting an odour along with a sugar reward. DANs respond to the reward and weaken KC-MBON synapses, weakening the response of aversive MBONs. Right – an aversive response can be induced by presenting an odour along with an electric shock. DANs respond to the shock and weaken KC-MBON synapses, weakening the response of attractive MBONs.

Dopamine acts by modifying the properties of synapses between KCs and MBONs. This therefore allows the response of the MB to change with experience – i.e. learning! While it was generally assumed that associative learning would strengthen KC-MBON connections, it has surprisingly been found to weaken them. Dopamine release in a particular compartment generally results in long-term depression of the KC-MBON synapses there, and therefore an attenuation of the response of the MBON in that compartment. Attenuation of an MBON that mediates attractive responses will bias towards aversion; while attenuation of an MBON that mediates aversive responses will bias towards attraction.

The details of how the MB mediates learning are complex, and much work still remains to be done – the roles of the different compartments and the various MBONs & DANs that target them are not yet fully understood.

Open Questions?

Using a connectomic approach, our lab aims to reconstruct olfactory circuits at synaptic resolution (i.e. down to individual neuron morphologies and synaptic connections).

Front view of the fly brain showing neuron reconstructions that our group has worked on – created from an electron microscopy volume of an entire female fly brain. (Zheng Z, Scott Lauritzen J, Perlman E, et al. A complete electron microscopy volume of the brain of adult Drosophila. 2017. doi:10.1101/140905.)

These detailed reconstructions will allow us to address a wide range of open questions:

e.g.

  • How do neurons in the LH interpret odour information and inform appropriate behavioural responses?
  • How do the MB and LH interact to allow experience to change the fly’s response to innately attractive or aversive odours?
  • What are the targets of MBONs and how do these ultimately govern motor behaviour?

And many more!

Ultimately, we want to gain a full understanding of how olfactory information is processed in the fly brain. As the vertebrate olfactory system (including that of humans) has a very similar structure, this should give valuable insights relevant to a range of organisms. More broadly, it offers a great opportunity to dig into the details of exactly how a sensory system is wired – at the scale of individual connections – and how this interacts with other systems in the brain.

 

 

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Image Credit: Adult brain and segmented neuropils – Template brain created by Arnim Jenett (Janelia Research Campus), Kazunori Shinomiya and Kei Ito (Tokyo University) [Ito et al., 2014] Then transformed to the EM template FAFB [Zheng et al., 2017]