Neural circuits

1. Neural circuits Lecture 3

2. Cellular neuroscience • Nerve cells with ion channels and synapses • How do neurons interact? • How is activity patterned? • How is appropriate activity selected? • How is sensory input used? • How is motor output coordinated and generated?

3. Why Crayfish? • Why escape behaviour? • Simple behaviour • Short duration startle response • simple nervous system • Abdominal ganglia with about 400 neurons

4. 2 Escape behaviours

5. 2 Escape behaviours • Anterior tap • Goes back • All segments bend • Tail tap • Goes up • Segments 1-3 bend • Differences in physiology match differences in adaptive behaviour

6. Abdominal tap • Ventral nerve cord • Contains lateral giant • LG Stimulated by tap • LG • Causes motoneurons • Then muscles to be active

7. Neural response

8. Neural circuit – anatomy

9. Neural circuit - schematic

10. Tactile hairs activated by water movement Sense organs

11. Excite Sensory interneuron Direct path (a) Bi-synaptic path (b) Multiplicity – lowers threshold But with safety factor Sense organs

12. Abdominal ganglia MG Transverse section LG neurite neuropil somata

13. LG to MoG • Electrical synapse

14. LG  Motoneuron path • Indirect • Chemical • Motoneuron filed with procion yellow

15. LG →SG →MN • Segmentalgiant • Prevents LG  MG interaction by rectifying electrical synapse between LG and SG • SG provides chemical excitation of flexor motor neurons • SG acts as amplifier

16. FF Motoneuron • 9 Fast Flexor motor neurons • Individually identifiable • All excited by LG via SG • Rectifying synapse • MG and LG separated

17. LG & motoneurons

18. Summary so far • Excitatory pathwaysense cell to musclecontraction

19. Preventing second escape • Turn off hair cell afferents • CDI neurons produce delay and postsynaptic inhibition of the SI

20. Preventing second escape • Turn off hair cell afferents • CDI neurons produce delay and postsynaptic inhibition of the SI • CDI neurons produce delay and also presynaptic inhibition of the receptors

21. Inhibition of Posture • MRO normally excites extensor motoneuron and flexor inhibitor • MRO turned off twice • Accessory cell • Fast extensor

22. End of escape • Inhibition of the flexion system LG spike FI FFMN

23. Major features of net • Need sensory coincidence to fire LG • Ensures safety if single cell accidentally fires • Lowers behavioural threshold below single neuron threshold (law of averages) • Fast • Multiple, parallel pathways • Combination of electrical feed-forward and chemical excitation • Chemical allows amplification of signal • Chemical allows modulation of pathway

24. Other systems • Locust & Drosophila jump • Cockroach running • Fish C-start

25. Drosophila

26. Rapid activation of GF

27. Photoactivation of GF • Flies cannot see http://www.sciencedirect.com/science/MiamiMultiMediaURL/B6WSN-4FWM4P4-J/B6WSN-4FWM4P4-J-4/7051/d542b7199c07d3f274131cb29e173241/Movie_S2..mov

28. Cockroach • Arthropod – escapes from toads, etc • Responds to air movement

29. Air movement hairs give directionality Escape correct way! Giant fibres Cockroach

30. Teleost fish • Mauthner cell • Large hindbrain, descending cell • Responds acoustically

31. Feed forward pathway • Receptor – interneuron or • Receptor – Mauthner ?

32. C-start startle response • But note Mauthner cell only used in some fast starts, • other homologous cells exist in other neuromeres

33. Conclusions • Apparently simple behaviour has complex neural circuit • Giant fibers for fast response • Feed-forward pathways • Safety features so only escape when needed • Chemical systems • Amplification • Modulation • Inhibition