Kim “Avrama” Blackwell George Mason University

1. Modelling Calcium Concentration Kim “Avrama” BlackwellGeorge Mason University

2. Importance of Calcium • Calcium influences channel behaviour, and thereby spike dynamics • Short term influences on calcium dependent potassium channels • Long term influences such as potentiation and depression via kinases • Electrical activity influences calcium concentration via ICa • Phosphorylation influences calcium concentration via kinetics of calcium permeable channels

3. _ _ _ _ _ + + + + + Feedback Loops of Calcium Dynamics Calcium Slow Kinases Fast Ca2+ SK, BK channels Membrane Potential Potassium, Sodium channels Synaptic channels, Calcium channels

4. Control of Calcium Dynamics

5. Control of Calcium Dynamics • Calcium Sources • Calcium Currents • Multiple types of voltage dependence calcium channels (L, N, P, Q, R, T) • Calcium permeable synaptic channels (NMDA) • Release from Intracellular Stores (smooth endoplasmic reticulum) • IP3 Receptor Channel (IP3R) • Ryanodine Receptor Channel (RyR)

6. Control of Calcium Dynamics • Calcium Sinks • Pumps • Smooth Endoplasmic Calcium ATPase (SERCA) • Plasma Membrane Calcium ATPase (PMCA) • Sodium-Calcium exchanger • Source or Sink • Buffers - bind calcium when concentration is high, releases calcium as concentration decreases • Calmodulin – active • Calbindin - inactive • Diffusion – moves calcium from high concentration to low concentration regions

7. Calcium Currents • L type (CaL1.x) • High threshold, Long lasting, no voltage dependent inactivation • T type (CaL3.x) • Low threshold, Transient, prominent voltage dependent inactivation Vm Vm

8. Calcium Currents N type (Cal2.x) High threshold (but lower than L type), moderate voltage dependent inactivation (Neither long lasting nor transient) P/Q type (Cal2.x) P type found in cerebellar Purkinje cells Properties similar to L type channel R type (Cal2.x) Used to be “Residual” current Now subunit identified

10. •Flux has units of moles per unit time, converted to concentration using rxnpool, Ca_concen, diffshell, or pool object

11. Calcium Release through Receptor Channels

12. Calcium Release • Calcium Release Receptor Channels are modelled as multi-state molecules • One state is the conducting state • For IP3 receptor state transitions depend on calcium concentration and IP3 concentration • For Ryanodine receptor, state transitions depend on calcium concentration

13. Dynamics of Release Channels • Both IP3R and RyR have two calcium binding sites: • Binding to one site is fast, causes fast channel opening • Binding to other site is slower, causes slow channel closing • IP3R has an additional binding site for IP3

14. IP3 Receptor • 8 state model of DeYoung and Keizer, 1992 • Figure from Li and Rinzel, 1994

17. Dynamics of Release Channels • Dynamics similar to sodium channel: • IP3 with low calcium produces small channel opening • Channel opening increases calcium concentration • Higher concentration causes larger channel opening • Positive feed back produces calcium spike

18. Dynamics of Release Channels • High calcium causes slower channel closing • Slow negative feedback • Channel inactivates • Inactivation analogous to sodium channel inactivation • SERCA pumps calcium back into ER • Calcium concentration returns to basal level

21. Calcium Extrusion Mechanisms • Plasma Membrane Calcium ATPase (PMCA) pump and sodium calcium exchanger (NCX) are the primary mechanism for re-equilibrating calcium in spines and thin dendrites (Scheuss et al. 2006) • These mechanisms depress with high activity or calcium concentration • Decay of calcium transient is slower • Positive feedback elevates calcium in small compartments

22. Calcium ATPase Pumps • Plasma membrane (PMCA) • Extrudes calcium to extracellular space • Binds one calcium ion for each ATP • Affinity ~300 -600 nM • Smooth Endoplasmic Reticulum (SERCA) • Sequesters calcium in SER • Binds two calcium ions for each ATP • Affinity ~100 nM

25. Sodium Calcium Exchange (NCX) • Stoichiometry • 3 sodium exchanged for 1 calcium • Charge transfer • Unequal => electrogenic • One proton flows in for each transport cycle • Small current produces small depolarization • Theoretical capacity ~50x greater than PMCA

26. Sodium Calcium Exchange (NCX) • Depolarization may reverse pump direction • Ion concentration change may reverse direction • Increase in Naint or decrease in Naext • Increase in internal sodium may explain activity dependent depression • Increase in Caext or decrease in Caint

27. Other formulations in Campbell et al. 1988 J Physiol., DiFrancesco and Noble 1985 Philos Trans R Soc Lond B, Weber et al. 2001 J Gen Physiol

28. Calcium Buffers • Calmodulin is a major calcium binding protein • Binds 4 calcium ions per molecule • High affinity for target enzymes • Calcium-Calmodulin Dependent Protein Kinase (CaMKII, CaMKIV) • Phosphodiesterase (PDE) • Adenylyl Cyclase (AC) • Protein Phosphatase 2B (PP2B = calcineurin) • KD1 = 1.5 uM, KD2 = 10 uM, • Recent estimates in Faas, Raghavachari, Lisman, Mody (2011) Nat Neurosci.

29. Calcium Buffers • Calbindin • Binds 4 calcium ions per molecule • Not physiologically active • 40 M in CA1 pyramidal neurons (Muller et al. 2006) • Diffusion coefficient = 20 m2/s • KD = 700 nM, kon = 2.7 x107 /M-sec • Parvalbumin • In fast spiking interneurons

31. Diffusion • Calcium decay in spines exhibits fast and slow components (Majewska et al. 2000) • Fast component due to • Buffered diffusion of calcium from spine to dendrite, which depends on spine neck geometry • Pumps, which are independent of spine neck geometry • Slow component matches dendritic calcium decay • Solely controlled by calcium extrusion mechanisms in the dendrite

32. Radial and Axial Diffusion Methods in Neuronal Modeling, Koch and Segev Chapter 6 by DeSchutter and Smolen

33. Derivation of Diffusion Equation • Diffusion in a cylinder • Derive equation by looking at fluxes in and out of a slice of width Dx Boundary Value Problems, Powers

34. Derivation of Diffusion Equation • Flux into left side of slice is q(x,t) • Flux out of right side is q(x+Dx,t) • Fluxes may be negative if flow is in direction opposite to arrows • Area for diffusional flux is A Boundary Value Problems, Powers

40. Control of Calcium Dynamics

42. Genesis Calcium Objects • Ca_concen • Simplest implementation of calcium • Fields • Time constant of decay • Minimum calcium • B = 1 / (z F vol): volume to produce 'reasonable' calcium concentration • Inputs • Calcium current

43. Genesis Calcium Objects • Code of all the following is in src/concen • Concpool • Calcium concentration without diffusion • Fields: Shape and size • Inputs: • Buffer rate constants, bound and free • MMpump coefficients • Influx and outflux of stores

44. Genesis Calcium Objects • difshell • concentration shell. Has ionic current flow, one-dimensional diffusion, first order buffering and pumps, store influx • Calculates volume and surface areas from diameter (dia), thick (length) and shape_mode (either slab or shell) • Combines rxnpool, reaction and diffusion into one object, thus must define kb, kf, diffusion constant • To store buffer concentrations, use • fixbuffer • Non-diffusible buffer (use with difshell) • difbuffer • Diffusible buffer (use with difshell)

45. Chemesis Calcium Objects • Calcium buffers implemented using • rxnpool • conservepool • Reaction • Kinetikit: • Pools • reac

46. Morphology of Model Cell

47. Calcium Dynamics in Model Cell Ca2+

48. Calcium Buffers • CalTut.txt explains all tutorials step-by-step • Cal1-SI.g • Creates pools of buffer, calcium and calcium bound buffer • Creates bimolecular reaction for buffering

49. Chemesis Calcium Objects • Diffusion • Parameters (Fields) • Diffusion constant, D • Units: 1 for SI, 1e-3 for mMole, etc. • Dunits: 1 for meters, 1e-3 for mm, etc. • Messages (Inputs) • Length, concentration, surface area from two reaction pools • Calculates • Flux from one pool to another • D SA Conc / len

50. Calcium Buffers and Diffusion • Cal2-SI.g • Two compartments: soma and dendrite • Calcium binding to buffer is implemented in function • Diffusion between soma and dendrite • Cal2difshell.g • Same system, using difshell and difbuffer • Computationally more efficient