Associative Learning by Single Cells

1. Associative Learning by Single Cells Dr. Chrisantha Fernando Systems Biology Centre University of Birmingham

2. Questions • How can associative learning be implemented in single cells? • How can we go about trying to find if these implementations exist? • How can we make associative learning devices and what are they good for?

3. Coincidence detectors Pre-Synaptic (Eccles) Post-Synaptic (Hebb)

4. Coincidence Detection and Memory • Pre-synaptic AC coincidence detection • 5-HT (G-protein) + Ca2+/Calmodulin (Eccles) • Post-synaptic NMDA coincidence detection • Ca2+ + Glutamate (Hebbian) • Short and Long Term State Storage • AC --> cAMP [15mins] --> PKA --> Decreased K+conductance • MAPK, Prion like CREB --> CRE gene expression • Increased NMDA localization to membrane,PKC --> AMPA

5. A Model of Pre-Synaptic AC based Learning • Gingrich and Byrne (J. Neurophys. 1987)

6. Paramecia Exhibit Classical Conditioning • Todd Hennessey et al • Shock (UCS) + Vibration (CS) classical conditioning of ‘avoidance response’ in paramecia. UCS = Shock CS = Vibration R = Avoiding Response

7. Sensory Mechanisms in Paramecia • Mechano: Eckert, Naitoh and Friedman. J. Exp. Biol. (1972) Ca2+ current K+ current

8. MACHEMER & ECKERT 1973 Applying depolarization produces reversal

9. Ca2+ channels are on the membrane surrounding the cilia Voltage gated Ca2+ channels are essential Shaving cilia abolishes Ca2+ current, until they grow back.

10. Behaviour of voltage gated Ca2+ channels can be modulated Vibration??

11. Ciliary Ca2+-Calmodulinactivates ciliary AC. Is AC acting as a coincidence detector in classical conditioning in paramecia? How is AC activity influenced by vibration? Is spatial distribution of membrane de/hyper-polorization relevant?

12. Possible Associative Learning Mechanisms in Paramecia • Is learning occurring by a mechanism analogous to pre-synaptic facilitation in Aplysia, i.e. using an AC coincidence detector, and cAMP dependent state changes mediating memory?

13. Gene mediated memory Reduced CDI PKA Ca2+ Ca2+ channel ATP cAMP Vibration AC Ciliary beat reversal Depolorization

14. An Intra-cellular “Hebbian” Learning Mechanism • I propose an abstract organization for an intra-cellular “Hebbian” mechanism, i.e. that depends on the extent of ciliary activity (“post-synaptic” effect) and not just on the coincidence between shock and vibration. • This can be implemented for example using a PK, PKK cascade with positive feedback.

15. mPK*2 mPK mPK*1 mPK PKK + u1 PKKu1 10 V U1* PKK + u2 PKKu2 u1 10 u2 U2* oPKK S 0.005 Cilia feedback signal PKK

16. Existing Components • oPKK activated along with the effecter by at least two iPKs • Two iPKs themselves activated by another mPK only when they are bound to signal molecules or signal molecules themselves are phosp. directly. • The oPKK should bind to signal molecules and specifically activate the appropriate mPK • The mPK should have a very slow equilibrium compared to the other PKs.

17. Kinase Cascades with Positive Feedback

18. NS Phosphatase PK*2 PK A more general mechanism PK*1 PK PKK + u1 PKKu1 10 U1* PKK + u2 PKKu2 u1 10 u2 U2* PKK 0.005 Promotor Gene

19. Constructing an Associative Learning Circuit • Are such components known? • How to go about finding networks in existence? • How to go about making them and seeing if the idea works?

20. Acknowledgements • T. Hennessey • D. Stekel • E. Szathmary • J. Rowe