Lecture Notes for

Chapter 12/13/14/15/16/17 Metabolism

Essential Biochemistry

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Overview of Metabolism

Breaking down molecules

Building up molecules

Free energy comes from hydrolysis of ATP

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Cells take up the products of digestion.

•  Human diet consists of four types of biomolecules –  Proteins –  Nucleic acids –  Polysaccharides –  Fats (particularly triacylglycerols)

•  Digestion reduces biomolecules to monomers –  Amino acids –  Nucleotides –  Monosaccharides –  Fatty acid

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Starchy foods are hydrolyzed by amylases.

Bond broken

Amylases are found in the salivary glands

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Proteins are hydrolyzed by proteases.

Proteases are secreted in the stomach and pancreas.

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Fatty acids are hydrolyzed by lipases.

Remember: Fatty acids are technically not

polymers.

Lipases are made in the

pancreas and secreted in the

small intestines.

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Monomers are stored as polymers.

Fatty acids are stored

in the form of triacylglycerols (large globules) in adipocytes.

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Some tissues use monosaccharides to produce glycogen.

Glycogen Structure

Electron Micrograph of a Liver Cell

Glycogen Granules

(pink)

Fat Globule (yellow)

Mitochondria (green)

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Glycogen breakdown occurs via phosphorolysis.

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Some major metabolic pathways share a few common intermediates.

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Some major metabolic pathways share a few common intermediates.

Glucose Catabolism

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Many metabolic pathways include oxidation-reduction reactions.

•  Catabolism of amino acids, monosaccharides, and fatty acids involves oxidizing carbon.

•  Anabolism of amino acids, monosaccharides, and fatty acids involves reducing carbon.

Carbon in methane is most highly reduced.

Carbon in CO2 is most highly

oxidized.

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Carbons in fatty acids and carbohydrates are oxidized to CO2.

Fatty acids have many methylene

carbons that undergo

oxidation.

Carbohydrates have (CH2O) carbons that

undergo oxidation.

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Overview of Metabolism

•  Monomers are formed.

•  Intermediates with two or three carbons are formed.

•  Carbons are fully oxidized to CO2.

•  Electron carriers gain electrons.

•  Electron carriers are recycled via electron loss.

•  ATP and H2O are produced.

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Humans do not synthesize vitamins.

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ATP is often involved in coupled processes.

Cleavage of phosphoanhydride

bonds yields energy to drive

unfavorable reactions.

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Consider the following reactions.

A highly favorable reaction

A highly unfavorable reaction © 2014 John Wiley & Sons, Inc. All rights reserved.

What’s so special about ATP?

•  ATP hydrolysis drives many unfavorable reactions to completion.

•  As a result, ATP acts as “energy currency”.

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Glucose Metabolism

•  Glycogen breakdown

•  Glycolysis

•  Gluconeogenesis

•  Glycogen synthesis

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Glycolysis Overview

•  Glycolysis occurs in 10 steps. – Steps 1-5 = energy investment – Steps 6-10 = energy payoff

•  Glucose (a six-carbon molecule) is broken

down into two 3-carbon molecules.

•  Electron carriers are reduced.

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First 5 Steps of Glycolysis

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Last 5 Steps of Glycolysis

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What happens to pyruvate?

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Pyruvate is a precursor of oxaloacetate.

•  Oxaloacetate is a metabolite used in: – The citric acid cycle – Gluconeogenesis

•  Oxaloacetate is also an intermediate in amino acid synthesis.

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Overview of Gluconeogenesis •  Many glycolytic

enzymes are used.

•  Four new enzymes –  Pyruvate carboxylase

–  Phosphoenolpyruvate carboxykinase

–  Fructose bisphosphatase

–  Glucose-6-phosphatase

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If glycolysis and gluconeogenesis occurred simultaneously, there

would be a net consumption of ATP!

•  Goal of producing ATP would be futile!

•  Instead, glycolysis and gluconeogenesis are regulated based on the cell’s needs.

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Glycogen synthesis consumes the free

energy of UTP.

•  Hydrolysis of inorganic pyrophosphatase drives the reaction.

•  UDP-glucose is the major intermediate.

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Glycogen synthase adds glucose to extend the glycogen polymer.

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Glycogenolysis

•  Glycogen breakdown occurs via different reactions. –  Linear chains are broken down via phosphorolysis. –  Branched chains of glycogen are broken down via

hydrolysis.

•  Glucose-6-phosphate can enter glycolysis at Step 2. –  One less ATP is consumed compared to glucose from the

bloodstream. –  Net gain of ATP is higher!

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Oxidative reactions of the pentose phosphate pathway produce NADPH.

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Net Reaction for the Pentose Phosphate Pathway

•  Ribose derivative is produced.

•  2 NADPH molecules are formed.

•  Pathway is active in rapidly dividing cells.

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Summary of Glucose

Metabolism

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Overview of the Citric Acid Cycle

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The citric acid cycle is an

energy-generating cycle.

•  1 NADH = 2.5 ATP •  1 QH2 = 1.5 ATP

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Overview in Context

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Recap on Oxidation-Reduction

•  One reactant is in its oxidized state while the other is in its reduced state.

•  Loss of electrons = oxidation •  Gain of electrons = reduction

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Electron transport takes place in the mitochondrion.

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Amino Acid Metabolism

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Transamination moves amino groups between compounds.

•  Transaminase = aminotransferase •  A transaminase catalyzes the transfer of an amino group

to an α-keto acid. •  Transamination is reversible.

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Nitrogen Metabolism in Context

•  Amino acids are synthesized from intermediates of glycolysis and the citric acid cycle.

•  Nonessential amino acids can be synthesized.

•  Essential amino acids must be obtained from food.

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Amino acids can be classified in terms of their catabolism.

•  Glucogenic – giving rise to gluconeogenic precursors – Citric acid cycle intermediates, for example

•  Ketogenic – giving rise to acetyl-CoA – Used for ketogenesis or fatty acid synthesis – Not used for gluconeogenesis

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Some amino acids are converted to gluconeogenic substrates via

transamination.

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Some amino acids are converted to gluconeogenic substrates via

transamination.

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Approximately 80% of excess nitrogen is excreted as urea.

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Amino groups can be disposed of via two routes.

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Lipid Metabolism In Context

•  Triacylglycerols contain fatty acids attached to a glycerol backbone.

•  Fatty acids are broken down

into 2C and 3C intermediates that feed into the citric acid cycle.

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Triacylglycerols are the primary source of fatty acids.

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Fatty acids are activated before they are degraded.

•  Activated fatty acids are acylated to CoA.

•  Reaction is

driven by ATP hydrolysis.

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Each round of β oxidation has four reactions.

•  Acyl groups are transferred via carnitine.

•  Acyl-CoA is degraded into acetyl-CoA.

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β Oxidation is a spiral process.

Let’s look at the reactions of β oxidation

more closely.

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β Oxidation results in ATP production.

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