Evolutionary History of Ion Channels and Neurotransmitters

1. Evolutionary History of Ion Channels and Neurotransmitters Neuro Journal Club, 06.03.08 Peter HANTZ, Arendt Laboratory

2. Types of Ion Channels Voltage, and voltage/intracellular ligand-gated ion channles K+ VG: fastly and slowly activated, inward rectifier, leak-channels V/ILG: Ca-activated, ATP-activated, cyclic-nucleotide gated Ca+ VG: High voltage activated, Low voltage activated V/ILG: Ca-activated, IP3 activated Na+, Cl-, H+: mostly VG Stretch-activated ion channels Large-conductance MSc Low-conductance MSc Light-gated ion channels

3. Types of Ion Channels/Receptors Neurotransmitter systems Ionotropic receptors: (ligand-gated ion channels) Cys-loop receptors "fast activating" Anionic(inhibitory) Gly, GABA Cationic(excitatory) 5HT, Ach (nicotinic) Glutamate Gated Channels Glutamate, agonists: AMPA, NMDA, kainate G-protein coupled (metabotropic) receptors ACh, Glu (AMPA, KAIN, NMDA), GABA, 5-HT, DA, NE, ... Shortcut pathway, Second Messenger Cascade Other neurotransmitter receptors peptides, NO, CO

4. Precursors of the VG-like ion channels small synthetic peptides: -fold into a-helixes -voltage: inserted into membranes -spontaneously build ion 5-7 mer channels 1-TM ion channels: Influenza M2 tetramer 2-TM ion channels: simplest K+ channels: KcsA, Kir (inwardly rectifier) tetramer Present in all three domains of life No voltage-sensitivity

5. Voltage-sensitive Potassium Channels Gene fusion/duplication: 1.-4. subunits containing six transmembrane crossings S1-S4: voltage gating S4: + charged voltage sensor S5, S6: conserved selectivity filter KvAP

6. 6TM-type channels Voltage and cyclic nucleotide-gated channels: one-domain, 6TM homotetramers Usual structure of Na and Ca channels: α1 subunits = four LINKED DOMAINS Each: six transmembrane elements

7. Possible origins of the 6TM channels Two rounds of gene duplications? -Similarities: domains I and III; domains II and IV -Two-domain channels were identified (TPC) They evolved from one-domain 6TM multimers? Ca or Na-channels are more ancestral? 4-domain Ca-channel: already in yeast 4-domain Na-channel: only in multicellular animals not detected in protozoa, in plants But: There is an ancestral bacterial 6TM homotetrameric Na-channel Note: two types of "inactivation" mechanisms (following activation) "ball and chain" or "inactivation loop" Cl channels: conservative, structurally distinct (10-12 domains)

8. Evolution of the LG-like ion channels Structure (Cys-loop "fast activating" channels): Mostly: pentamers of 1-domain 4-TM proteins N-term extracellular domain: ligand binding site Made of several unrelated proteins? Homologs in bacteria Ancient role: nutrient seeking? osmotic regulation? Now: intercellular communication

9. Evolution of the LG-like ion channels Ancient: ACh, 5HT and GABA Gly derived from GABA despite Gly is "more simple" Root:?

10. Structure of the GPCR Single, 7TM polypeptide 2 extracellular loops: transmitter binding site 2 intracellular loops: activate G-proteins Two major groups: PLC-activating (IP3) cAMP decrease Ev. connection between ionotropic (LGICh) and metabotropic (GPCR) receptors ?

11. Evolution of the GPCR 7-TM architecture in procaryotes: bacteriorhodopsins, no GPC ...linkage to eucaryotic GPCR ? (disputed) GPCR: Present in plants, fungi and animals: common ancestor, 1.2 Gy ago