Acetyl-CoA and the Citric Acid Cycle

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Acetyl-CoA and the Citric Acid Cycle Dr. Kevin Ahern

Respiration Conversion of nutrients into useful energy for the cell Carbohydrates - Sugars Proteins - Amino Acids Fats - Fatty Acids & Glycerol

Acetyl-CoA

Pyruvate Dehydrogenase Ethanol Mitochondrial Enzyme Very large multimeric complex Three subunits - E1, E2, E3 NAD+ No O2 CO2 NADH Pyruvate Acetaldehyde NAD+ O2 Animals Bacteria & Yeast NAD+ NADH NADH + CO2 Acetyl-CoA E1 Subunit of Pyruvate Dehydrogenase

NAD+ NADH Acetaldehyde Ethanol Alcohol Dehydrogenase

Pyruvate Dehydrogenase CO2 TPP-Acetaldehyde Bacteria / Yeast Acetaldehyde (Mostly in low O2) Electron transfer to lipoamide-S-S E2 Pyruvate Dehydrogenase Acetyl-Lipoamide FAD FADH2 E3 NAD+ NADH Acetyl-CoA

E2 E1 E3 Acetyl-Lipoamide Acetyl-CoA TPP-Acetaldehyde Pyruvate Electron transfer to lipoamide-S-S Pyruvate E3 Acetyl-CoA

Lipoamide Oxidized/Reduced

(Favor Dephosphorylation) These ions Activate PD = Pyruvate Dehydrogenase Phosphorylation Inactivates Dephosphorylation Activates PD Kinase Puts Phosphate on PD Phosphatase Takes Phosphate off (Favor Dephosphorylation) These ions Activate Be careful not to confuse PD with the PD Phosphatase or the PD Kinase These Hormones Inactivate PD (Favor Phosphorylation)

Acetyl-CoA

+ Very Negative ΔG°’ Citrate Synthase H +

Aconitase

First oxidative decarboxylation + NAD+ Isocitrate Dehydrogenase + NADH + CO2 First oxidative decarboxylation

+ + + + NAD+ CoASH NADH CO2 Second oxidative decarboxylation α-ketoglutarate dehydrogenase + + NADH CO2 Second oxidative decarboxylation

Phosphorylation in Cycle + GDP + Pi Succinyl-CoA Synthetase + GTP + CoASH Symmetrical Product Only Substrate Level Phosphorylation in Cycle

Succinyl-CoA Synthetase Mechanism

Third Oxidation of Cycle + FAD Succinate Dehydrogenase Third Oxidation of Cycle + FADH2

Succinate Dehydrogenase Enzyme is embedded in inner mitochondrial membrane Only enzyme of Citric Acid Cycle not found in matrix

Electron Movement Reaction

+ H2O Fumarase

citrate synthase reaction + NAD+ Malate Dehydrogenase Very positive ΔG°’ Reaction pulled by citrate synthase reaction Fourth and final oxidation of cycle + NADH

Citric Acid Cycle Summary Input 2 Carbons (1 Acetyl CoA) Release 2 CO2 Molecules Four Oxidations 3 NADH, 1 FADH2, 1 GTP Per Turn of Cycle

Each Citric Acid Cycle Intermediate Functions in Other Pathways Citrate - Glyoxylate Cycle, Allosteric Effector, Shuttle System Isocitrate - Glyoxylate Cycle a-Ketoglutarate - Amino Acid/Nitrogen Metabolism Succinyl-CoA - Heme Synthesis, Amino Acid Metabolism Succinate - Glyoxylate Metabolism, Odd Chain Fatty Acid Metabolism Fumarate - Nucleotide Metabolism Malate - Shuttle System Oxaloacetate - Gluconeogenesis, Amino Acid Metabolism

Anaplerotic / Cataplerotic

Arnon-Buchanan Cycle

Two per turn of cycle

Isocitrate Lyase Isocitrate Succinate + Glyoxylate +

Malate Synthase Acetyl-CoA + Glyoxylate L-Malate +

Glyoxylate Cycle Summary Input 4 Carbons (2-Acetyl CoA) Releases 0 CO2 Molecules Produces One Extra Oxaloacetate Two Oxidations 1 NADH, 1 FADH2 1(extra ) Oxaloacetate Per Turn of Cycle Net Synthesis of Glucose from Acetyl-CoA Citric Acid Cycle Summary Input 2 Carbons (1 Acetyl CoA) Releases 2 CO2 Molecules Four Oxidations 3 NADH, 1 FADH2, 1 GTP Per Turn of Cycle No Net Synthesis of Glucose from Acetyl-CoA

The Animals’ Dilemma No net glucose synthesis from fat

Ketone Body Metabolism