Chapter 27 & 28 Metabolic pathway & Energy production

Chemistry B11 Chapter 27 & 28 Metabolic pathway & Energy production

Metabolism Chemical reactions in cells that break down or build molecules. It produces energy and provide substances to cell growth. Catabolic reactions: Complex molecules  Simple molecules + Energy Anabolic reactions: Simple molecules + Energy (in cell) Complex molecules

Metabolism in cell Mitochondria Urea NH4+ Proteins Amino acids e Citric Acid cycle Glucose Fructose Galactose Carbohydrates Polysaccharides e Glucose Pyruvate Acetyl CoA CO2 & H2O Glycerol Lipids Fatty acids Stage 3: Oxidation to CO2, H2O and energy Stage 2: Degradation and some oxidation Stage 1: Digestion and hydrolysis (Formation of Acetyl CoA)

Cell Structure Nucleus Membrane Mitochondria Cytoplasm (Cytosol)

Cell Structure Nucleus: consists the genes that control DNA replication and protein synthesis of the cell. Cytoplasm: consists all the materials between nucleus and cell membrane. Cytosol: fluid part of the cytoplasm (electrolytes and enzymes). Mitochondria: energy producing factories. Enzymes in matrix catalyze the oxidation of carbohydrates, fats , and amino acids. Produce CO2, H2O, and energy.

3 Phosphates Ribose ATP and Energy • Adenosine triphosphate (ATP) is produced from the oxidation of food. • Has a high energy. • Can be hydrolyzed and produce energy.

Pi (adenosine triphosphate) (adenosine diphosphate) (inorganic phosphate) ATP and Energy - We use this energy for muscle contraction, synthesis an enzyme, send nerve signal, and transport of substances across the cell membrane. - 1-2 million ATP molecules may be hydrolysis in one second (1 gram in our cells). - When we eat food, catabolic reactions provide energy to recreate ATP. ADP + Pi + 7.3 kcal/mol  ATP

Stage 1: Digestion Convert large molecules to smaller ones that can be absorbed by the body. Carbohydrates Lipids (fat) Proteins

Digestion: Carbohydrates Salivary amylase Dextrins + Mouth Polysaccharides + Maltose Glucose Stomach pH = 2 (acidic) Small intestine pH = 8 Dextrins α-amylase(pancreas) Glucose Glucose Maltase + Maltose Galactose Glucose Lactase + Lactose Fructose Glucose Sucrase + Sucrose Bloodstream Liver (convert all to glucose)

Digestion: Lipids (fat) Fatty acid H2C OH H2C lipase (pancreas) HC Fatty acid + 2H2O HC Fatty acid + 2 Fatty acids Small intestine H2C Fatty acid H2C OH Triacylglycerol Monoacylglycerol Intestinal wall Monoacylglycerols + 2 Fatty acids → Triacylglycerols Protein Lipoproteins Chylomicrons Lymphatic system Bloodstream Enzymes hydrolyzes Glycerol + 3 Fatty acids Cells liver Glucose

Digestion: Proteins HCl Pepsinogen Pepsin Stomach Proteins Polypeptides denaturation + hydrolysis Small intestine Trypsin Chymotrypsin Polypeptides Amino acids hydrolysis Intestinal wall Bloodstream Cells

Some important coenzymes oxidation Coenzyme + Substrate Coenzyme(+2H) + Substrate(-2H) Reduced Oxidized 2 H atoms 2H+ + 2e- NAD+ Coenzymes FAD Coenzyme A

ADP NAD+ Nicotinamide adenine dinucleotide (vitamin) (Vitamin B3) Ribose

+ NAD+ • Is an oxidizing agent. • Participates in reactions that produce (C=O) such as oxidation of alcohols to aldehydes and ketones. O CH3-CH2-OH + NAD+ CH3-C-H + NADH + H+ NAD+ + 2H+ + 2e- NADH + H+

FAD Flavin adenine dinucleotide (Vitamin B2) (sugar alcohol) ADP

H H R-C-C-R + FAD R-C=C-H + FADH2 H H H H FAD • Is an oxidizing agent. • Participates in reaction that produce (C=C) such as dehydrogenation of alkanes.

Coenzyme A (CoA) Coenzyme A Aminoethanethiol ( vitamin B5)

Coenzyme A (CoA) O O - It activates acyl groups (RC-), particularly the Acetyl group (CH3C-). O O CH3-C- + HS-CoA CH3-C-S-CoA Acetyl group Coenzyme A Acetyl CoA

Stage 2: Formation of Acetyl CoA Glycolysis: Oxidation of glucose • We obtain most of our energy from glucose. • Glucose is produced when we digest the carbohydrates in our food. • We do not need oxygen in glycolysis (anaerobic process). 2 ATP 2 ADP + 2Pi O C6H12O6 + 2 NAD+ 2CH3-C-COO- + 2 NADH + 4H+ Glucose Pyruvate Inside of cell (Cytoplasm)

Pathways for pyruvate - Pyruvate can produce more energy. Aerobic conditions: if we have enough oxygen. Anaerobic conditions: if we do not have enough oxygen.

Aerobic conditions • Pyruvate is oxidized and a C atom remove (CO2). • Acetyl is attached to coenzyme A (CoA). • Coenzyme NAD+ is required for oxidation. O O O CH3-C-C-O- + HS-CoA + NAD+ CH3-C-S-CoA + CO2 + NADH pyruvate Coenzyme A Acetyl CoA Important intermediate product in metabolism.

NAD+ O O NADH + H+ HO O CH3-C-C-O- CH3-C-C-O- H pyruvate Lactate Reduced Anaerobic conditions • When we exercise, the O2 stored in our muscle cells is used. • Pyruvate is reduced to lactate. • Accumulation of lactate causes the muscles to tire and sore. • Then we breathe rapidly to repay the O2. • Most lactate is transported to liver to convert back into pyruvate.

Glycogen • If we get excess glucose (from our diet), glucose convert to glycogen. • It is stored in muscle and liver. • We can use it later to convert into glucose and then energy. • When glycogen stores are full, glucose is converted to triacylglycerols and stored as body fat.

Step 3: Citric Acid Cycle • Is a central pathway in metabolism. • Uses acetyl CoA from the degradation of carbohydrates, lipids, and proteins. • Two CO2 are given off. • There are four oxidation steps in the cycle provide H+ and electrons to reduce FAD and NAD+ (FADH2 and NADH). 8 reactions

Reaction 1 Formation of Citrate O CH3-C-S-CoA Acetyl CoA + COO- CH2 COO- H2O HO COO- + CoA-SH C C=O Oxaloacetate CH2 CH2 COO- COO- Coenzyme A Citrate

Reaction 2 Isomerisation to Isocitrate • Because the tertiary –OH cannot be oxidized. (convert to secondary –OH) COO- COO- CH2 CH2 Isomerisation HO H COO- COO- C C H HO CH2 C COO- COO- Isocitrate Citrate

Reaction 3 First oxidative decarboxylation (CO2) • Oxidation (-OH converts to C=O). • NAD+ is reduced to NADH. • A carboxylate group (-COO-) is removed (CO2). COO- COO- COO- CH2 CH2 CH2 H H COO- COO- C C CH2 CO2 H HO O O C C C COO- COO- COO- Isocitrate α-Ketoglutrate

Reaction 4 Second oxidative decarboxylation (CO2) • Coenzyme A convert to succinyl CoA. • NAD+ is reduced to NADH. • A second carboxylate group (-COO-) is removed (CO2). COO- COO- CH2 CH2 CH2 CH2 + CO2 O O C C COO- S-CoA α-Ketoglutrate Succinyl CoA

Reaction 5 Hydrolysis of Succinyl CoA • Energy from hydrolysis of succinyl CoA is used to add a phosphate group (Pi) to GDP (guanosine diphosphate). • The hydrolysis of GTP is used to add a Pi to ADP to produce ATP. GTP + ADP → GDP+ ATP COO- COO- CH2 CH2 + H2O + GDP + Pi + GTP + CoA-SH CH2 CH2 O C COO- S-CoA Succinate Succinyl CoA

Reaction 6 Dehydrogenation of Succinate • H is removed from two carbon atoms. • Double bond is produced. • FAD is reduced to FADH2. COO- COO- CH2 CH CH2 CH COO- COO- Fumarate Succinate

Reaction 7 Hydration • Water adds to double bond of fumarate to produce malate. COO- COO- H2O CH H HO C CH CH2 COO- COO- Fumarate Malate

Reaction 8 Dehydrogenation forms oxaloacetate • -OH group in malate is oxidized to oxaloacetate. • Coenzyme NAD+ is reduced to NADH + H+. COO- COO- + H+ H HO C C=O CH2 CH2 COO- COO- Oxaloacetate Malate

Summary The catabolism of proteins, carbohydrates, and fatty acids all feed into the citric acid cycle at one or more points: Citric Acid Cycle

Summary

Summary The main function of the citric acid cycle is to produce reduced coenzymes (NADH and FADH2). These molecules enter the electron transport chain (Stage 4) and ultimately produce ATP. Feedback Mechanism The rate of the citric acid cycle depends on the body’s need for energy. When energy demands are high and ATP is low → the cycle is activated. When energy demands are low and NADH is high → the cycle is inhibited.

Stage 4: Electron Transport & Oxidative Phosphorylation • Most of energy generated during this stage. • It is an aerobic respiration (O2 is required). 1. Electron Transport Chain (Respiratory Chain) 2. Oxidative Phosphorylation

Electron Transport H+ and electrons from NADH and FADH2 are carried by an electron carrier until they combine with oxygen to form H2O. FMN (Flavin Mononucleotide) Fe-S clusters Electron carriers Coenzyme Q (CoQ) Cytochrome (cyt)

(Vitamin B2) (sugar alcohol) - FMN (Flavin Mononucleotide) H 2H+ + 2e- H - FMN + 2H+ + 2e-→ FMNH2 Reduced

Fe-S Clusters S S Cys S Cys Cys S Cys + 1 e- Fe3+ Fe2+ S S S S Cys Cys Cys Cys Fe3+ + 1e-Fe2+ Reduced

Coenzyme Q (CoQ) OH 2H+ + 2e- OH Reduced Coenzyme Q (QH2) Coenzyme Q Q + 2H+ + 2e-→ QH2 Reduced

Cytochromes (cyt) • They contain an iron ion (Fe3+) in a heme group. • They accept an electron and reduce to (Fe2+). • They pass the electron to the next cytochrome and they are oxidized back to Fe3+. Fe3+ + 1e- Fe2+ Oxidized Reduced cyt b, cyt c1, cyt c, cyt a, cyt a3

Electron Transfer Mitochondria

Electron Transfer Complex I NADH + H+ + FMN → NAD+ + FMNH2 FMNH2+ Q → QH2 + FMN NADH + H+ + Q → QH2 + NAD+ Complex II FADH2 + Q → FAD + QH2

Electron Transfer Complex III QH2 + 2 cyt b (Fe3+) → Q + 2 cyt b (Fe2+) + 2H+ Complex IV Aerobic 4H+ + 4e- + O2→ 2H2O From reduced coenzymes or the matrix From inhaled air From the electron transport chain

Oxidative Phosphorylation Transport of electrons produce energy to convert ADP to ATP. ADP + Pi + energy → ATP + H2O

Chemiosmotic model • H+ make inner mitochondria acidic. • Produces different proton gradient. • H+ pass through ATP synthase (a protein complex). ATP synthase

Total ATP Glycolysis: 7 ATP Oxidation of Pyruvate: 5 ATP Citric acid cycle: 20 ATP Oxidation of glucose 32 ATP C6H12O6 + 6O2 + 32 ADP + 32 Pi→ 6CO2 + 6H2O + 32 ATP

Chapter 27 & 28 Metabolic pathway & Energy production