Biochemistry

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Course Number: CHEM450 Download Course Syllabus

This course provides you with a comprehensive overview of the fundamental principles of biochemistry. Concepts from the structure and function of biomolecules to the regulation of cellular metabolism are discussed.

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Course Objectives

After completing the course, students will be able to:

  • Identify weak interactions in aqueous systems, ionizations of water, and buffers against pH changes in biological systems.
  • Contrast primary, secondary, tertiary, and quaternary structures of proteins and their effects on binding and interactions.
  • Sort monosaccharides, disaccharides, polysaccharides, and glycoconjugates.
  • Understand nucleic acid structure and chemistry.
  • Contrast the functions and features of lipids when acting as signals, cofactors, and pigments.
  • Understand the relationship of membrane dynamics with their composition and architecture.
  • Explain how the G Protein, gated ion channels, regulation of transcription and cell cycle achieve biochemical signaling.
  • Identify the effects of bioenergetics and thermodynamics on metabolism.
  • Explain the role of glycogen and glycolysis in metabolic pathways.
  • Articulate the citric acid cycle.
  • Understand the digestion, mobilization, and transport of fats.
  • Articulate the role of ATP in oxidative phosphorylation.
  • Explain the biosynthesis of fatty acids, triacylglycerols and membrane phospholipids.
  • Understand the role of hormone regulation on metabolism.
  • Articulate how genes, chromosomes, DNA, RNA, and other proteins are used as information pathways.

Topics

Topic

Subtopics

Objectives

1

The Foundations of Biochemistry
  • Cellular Foundations
  • Chemical Foundations
  • Physical Foundations
  • Genetic Foundations
  • Evolutionary Foundations
  • Describe an organism at the cellular level.
  • Explain how cell size and function are connected.
  • Relate biomolecule composition, structure, and function.
  • Describe the dynamic steady state maintained by a living organism.
  • Construct a description of the thermodynamic basis for a reaction.
  • Relate the origins of life to biochemical processes that occur today.
  • Explain how cellular systems and processes can be studied.
  • Describe the flow of information from linear DNA to three-dimensional proteins.
  • Describe how genetic changes can alter gene function.

2

Water, the Solvent of Life
  • Weak Interactions in Aqueous Systems
  • Ionization of Water, Weak Acids, and Weak Bases
  • Buffering against pH Changes in Biological Systems
  • Explain how weak interactions between biomolecules confer stability in aqueous solutions.
  • Explain the importance of entropy to biological systems.
  • Explain why biological systems must regulate osmotic pressure.
  • Apply concepts of acid-base equilibria to a system.
  • Determine the concentration or amount of a substance present by titration.
  • Explain the importance of buffers to biological systems.

3

Amino Acids, Peptides, and Proteins
  • Amino Acids
  • Peptides and Proteins
  • Working with Proteins
  • The Structure of Proteins: Primary Structure
  • Determine the identity of an amino acid from experimental data.
  • Determine the structure of an amino acid from the pH of its solvent.
  • Determine the composition of a polypeptide or protein from experimental data.
  • Analyze the effectiveness of a purification strategy used to separate a mixture of proteins or amino acids.
  • Determine the components of a mixture from electrophoresis data.
  • Determine the primary structure of polypeptide or protein from experimental data.
  • Analyze an evolutionary relationship from the sequence of amino acids in a protein or polypeptide.
  • Relate the absorbance, concentration, molar extinction coefficient, and pathlength for a sample analyzed by spectrophotometry.

4

The Three-Dimensional Structure of Proteins
  • Overview of Protein Structure
  • Protein Secondary Structure
  • Protein Tertiary and Quaternary Structures
  • Protein Denaturation and Folding
  • Determination of Protein and Biomolecular Structures
  • Explain how chemical and physical interactions govern protein structure and stability.
  • Relate the structure and biological function of a protein.
  • Explain the relationship between disruptions in proteostasis and disease.
  • Describe how a protein adopts its native conformation.
  • Analyze protein three-dimensional structure using amino acid sequences, experimental data, and models.

5

Protein Function
  • Reversible Binding of a Protein to a Ligand: Oxygen-Binding Proteins
  • Complementary Interactions between Proteins and Ligands: The Immune System and Immunoglobulins
  • Protein Interactions Modulated by Chemical Energy: Actin, Myosin, and Molecular Motors
  • Construct a quantitative description of the interaction between a protein and ligand using experimental data.
  • Describe the allosteric interactions governing a protein and ligand pair using experimental data.
  • Predict how changes in the solvent or structure of a globin protein will affect its ability to store and transport oxygen in the body.
  • Explain the significance of the antibody-antigen interaction.
  • Explain how conformational changes at the molecular level produce muscle movement.

6

Enzymes
  • An Introduction to Enzymes
  • How Enzymes Work
  • Enzyme Kinetics as an Approach to Understanding Mechanism
  • Examples of Enzymatic Reactions
  • Regulatory Enzymes
  • Construct a general description of an enzyme from experimental data.
  • Describe the energetic basis of enzyme-mediated catalysis.
  • Propose the mechanism by which an enzyme catalyzes a reaction.
  • Construct a kinetic description of the reaction catalyzed by an enzyme that obeys Michaelis-Menten kinetics.
  • Propose a mechanism for inhibition of a non-allosteric enzyme based on experimental data.
  • Explain how chymotrypsin cleaves a substrate.
  • Propose a mechanism of allosteric regulation for an enzyme based on experimental data.
  • Propose a mechanism of regulatory modification for an enzyme based on experimental data.
  • Explain the importance of enzyme regulation in blood coagulation.

7

Carbohydrates and Glycobiology
  • Monosaccharides and Disaccharides
  • Polysaccharides
  • Glycoconjugates: Proteoglycans, Glycoproteins, and Glycolipids
  • Carbohydrates as Informational Molecules: The Sugar Code
  • Working with Carbohydrates
  • Construct a description of a carbohydrate.
  • Relate the structure, composition, chemical properties, and biological function of a monosaccharide.
  • Explain how blood glucose concentration and health are connected.
  • Relate the structure, composition, properties, and function of a carbohydrate polymer.
  • Explain how glycoconjugate synthesis, function, and destruction relate to health.
  • Explain the importance of lectin:carbohydrate interactions.
  • Propose a scheme for analyzing a glycoconjugate.

8

Nucleotides and Nucleic Acids
  • Some Basic Definitions and Conventions
  • Nucleic Acid Structure
  • Nucleic Acid Chemistry
  • Other Functions of Nucleotides
  • Relate the name, structure, and symbolic representation of a nucleic acid.
  • Explain how DNA studies lead to the model for DNA structure
  • Explain the significance of B-form DNA structure.
  • Relate the number of bases, rise per base, or number of helical turns to the length of a nucleic acid.
  • Relate the sequence, structure, and activities of unusual DNA structures.
  • Relate the sequence, structure, and activities of RNA molecules.
  • Relate the structure of a nucleic acid to its properties.
  • Explain the importance of nucleic acid modifications to life.
  • Interpret the results of a polymerase chain reaction (PCR) experiment.
  • Determine the sequence of nucleotides in a molecule of nucleic acid.
  • Explain the significance of nucleic acids and their derivatives to life.

9

Lipids
  • Storage Lipids
  • Structural Lipids in Membranes
  • Lipids as Signals, Cofactors, and Pigments
  • Working with Lipids
  • Relate the structure, physical properties, and function of storage lipids.
  • Relate the general structure, composition, and properties of a membrane lipid.
  • Explain the importance of membrane lipid structure to health.
  • Describe the roles of lipids outside of storage and structure.
  • Determine the structure and composition of a lipid from experimental data.

10

Biological Membranes and Transport
  • The Composition and Architecture of Membranes
  • Membrane Dynamics
  • Solute Transport across Membranes
  • Explain the importance of diversity in membrane composition and structure to life.
  • Classify membrane proteins based on their structure, function, and properties.
  • Explain how membrane function is connected to the organization and dynamics of lipids within membranes.
  • Explain why membrane fusion, fission, and curvature are important for homeostasis.
  • Connect mechanisms of substance transfer in and out of cells with cellular function.
  • Propose a scheme for studying a plasma membrane component.
  • Construct a quantitative description of transporter-mediated solute transport.
  • Connect the distribution and activities of glucose transporters in humans with the needs of different tissues.

11

Biochemical Signaling
  • General Features of Signal Transduction
  • G Protein–Coupled Receptors and Second Messengers
  • GPCRs in Vision, Olfaction, and Gustation
  • Receptor Tyrosine Kinases
  • Multivalent Adaptor Proteins and Membrane Rafts
  • Gated Ion Channels
  • Regulation of Transcription by Nuclear Hormone Receptors
  • Regulation of the Cell Cycle by Protein Kinases
  • Oncogenes, Tumor Suppressor Genes, and Programmed Cell Death
  • Explain how signals are communicated and integrated through G protein-coupled receptor (GPCR) signaling pathways.
  • Predict the effects of altering cyclic AMP (cAMP) function in the cell.
  • Predict the effects of an intervention or mutation on signaling through G protein-coupled receptors (GPCRs).
  • Predict the effects of an intervention or mutation on signaling through receptor tyrosine kinases (RTKs).
  • Describe the versatility in signaling pathways afforded by the variety of pathway components.
  • Predict the effects of an intervention or mutation on signaling through gated-ion channels.
  • Predict the effect of an intervention or mutation on signaling through a nuclear hormone receptor.
  • Describe the roles of protein kinases in cell cycle regulation.
  • Explain how defects in regulation of the cell cycle can lead to disease.
  • Describe the function of a signaling pathway based on experimental data.

12

Introduction to Metabolism
  • Bioenergetics and Thermodynamics
  • Chemical Logic and Common Biochemical Reactions
  • Phosphoryl Group Transfers and ATP
  • Biological Oxidation-Reduction Reactions
  • Regulation of Metabolic Pathways
  • Explain a biochemical reaction by providing the curved-arrow mechanism.
  • Explain how the removal of phosphate groups from phosphorylated compounds is used to power reactions in the cell.
  • Construct a quantitative description of a biological oxidation-reduction reaction.
  • Use experimental data to monitor the flow of electrons through a series of biochemical reactions.
  • Explain how multiple mechanisms of regulation can collaborate to maintain the dynamic steady state of a cell.

13

Glycolysis, Gluconeogenesis, and the Pentose Phosphate Pathway
  • Glycolysis
  • Feeder Pathways for Glycolysis
  • Fates of Pyruvate
  • Gluconeogenesis
  • Coordinated Regulation of Glycolysis and Gluconeogenesis
  • Pentose Phosphate Pathway of Glucose Oxidation
  • Explain how organisms produce energy through glycolysis.
  • Explain how glycolysis can be used to metabolize starting materials other than glucose.
  • Explain how pyruvate will be metabolized under given conditions.
  • Determine the free energy released by catabolism of a carbohydrate under given conditions.
  • Explain the importance of carbohydrate metabolism to health.
  • Explain how organisms use gluconeogenesis to produce glucose from precursor molecules.
  • Explain why gluconeogenesis is essential even though it is energetically expensive.
  • Predict the path of molecules through glycolysis and gluconeogenesis based on given conditions.
  • Explain how the pentose phosphate pathway is used as an alternative method for metabolizing glucose.

14

The Metabolism of Glycogen in Animals
  • The Structure and Function of Glycogen
  • Breakdown and Synthesis of Glycogen
  • Coordinated Regulation of Glycogen Breakdown and Synthesis
  • Relate the structure and function of glycogen polymers and granules.
  • Explain how animals release glucose from glycogen stores.
  • Explain how animals store excess glucose as glycogen.
  • Explain how the body coordinates glycogen metabolism based on its energy supply and demand.

15

The Citric Acid Cycle
  • Production of Acetyl-CoA (Activated Acetate)
  • Reactions of the Citric Acid Cycle
  • The Hub of Intermediary Metabolism
  • Regulation of the Citric Acid Cycle
  • Explain how pyruvate is activated to produce acetyl-CoA.
  • Explain how the citric acid cycle oxidizes acetyl-CoA to carbon dioxide.
  • Determine the amount of energy released by the aerobic metabolism of a carbohydrate.
  • Explain how the citric acid cycle serves as the central hub of intermediary metabolism.
  • Predict how a change will affect the rate of citric acid cycle metabolism.

16

Fatty Acid Catabolism
  • Digestion, Mobilization, and Transport of Fats
  • Oxidation of Fatty Acids
  • Ketone Bodies
  • Describe the path of dietary lipids in vertebrates.
  • Explain how fatty acids are prepared for oxidation.
  • Explain how a fatty acid can be completely metabolized.
  • Relate the amount and type of fatty acids burned with body weight.
  • Predict how the metabolism of fatty acids will change depending on the supply of energy in the body.
  • Relate the formation of ketone bodies with alterations in fatty acid metabolism.

17

Oxidative Phosphorylation
  • The Mitochondrial Respiratory Chain
  • ATP Synthesis
  • Regulation of Oxidative Phosphorylation
  • Describe the role of mitochondria in eukaryotic aerobic metabolism.
  • Describe the composition of the mitochondrial respiratory chain.
  • Explain how electrons enter the mitochondrial respiratory chain.
  • Explain how the mitochondrial respiratory chain shuttles electrons to molecular oxygen.
  • Explain how the mitochondrial respiratory chain produces ATP.
  • Explain how oxidative phosphorylation can be regulated.
  • Describe additional roles for mitochondria other than the generation of ATP.
  • Describe the implications and consequences of mitochondria possessing their own genome.

18

Lipid Biosynthesis
  • Biosynthesis of Fatty Acids and Eicosanoids
  • Biosynthesis of Triacylglycerols
  • Biosynthesis of Membrane Phospholipids
  • Cholesterol, Steroids, and Isoprenoids: Biosynthesis, Regulation, and Transport
  • Explain how organisms synthesize palmitate.
  • Explain how organisms coordinate fatty acid synthesis with other metabolic processes.
  • Explain how organisms elongate fatty acids.
  • Explain how organisms generate complex fatty acids.
  • Explain how organisms synthesize triacylglycerols.
  • Explain how adipose tissue produces glycerol 3-phosphate.
  • Explain how organisms use fatty acids to synthesize membrane lipids.
  • Explain how organisms synthesize cholesterol.
  • Explain how lipids and cholesterol are transported throughout the body.
  • Explain how cholesterol metabolism is regulated.
  • Describe how cholesterol and its synthetic pathway intermediates can be used in the body outside of lipid metabolism.
  • Explain the importance of regulating cholesterol metabolism.

19

Biosynthesis of Amino Acids, Nucleotides, and Related Molecules
  • Overview of Nitrogen Metabolism
  • Biosynthesis of Amino Acids
  • Molecules Derived from Amino Acids
  • Biosynthesis and Degradation of Nucleotides
  • Explain how a complex web of reactions converts atmospheric nitrogen to biologically useful forms and maintains a global balance between them.
  • Explain how reactive forms of nitrogen are incorporated into biological systems through glutamate and glutamine.
  • Explain how organisms synthesize the 20 common amino acids.
  • Explain the regulation of amino acid synthesis.
  • Explain how amino acids serve as precursors of many specialized biomolecules.
  • Contrast the two pathways for nucleotide synthesis.
  • Detail the processes of de novo purine nucleotide synthesis.
  • Detail the processes of de novo pyrimidine nucleotide synthesis.
  • Explain how deoxyribonucleic acids are formed.
  • Explain how salvage pathways recycle purine and pyrimidine bases.
  • Explain the regulation of nucleotide biosynthesis.
  • Explain the importance of nucleic acid metabolism to health.

20

Hormonal Regulation and Integration of Mammalian Metabolism
  • Hormone Structure and Action
  • Tissue-Specific Metabolism
  • Hormonal Regulation of Fuel Metabolism
  • Obesity and the Regulation of Body Mass
  • Diabetes Mellitus
  • Explain how mammals coordinate activities between different tissues and organs.
  • Describe insulin production, storage, and release.
  • Describe the role of the liver in the metabolism of nutrients.
  • Compare the function of white adipose tissue (WAT) and brown adipose tissue (BAT).
  • Describe the specialized metabolism of muscle cells.
  • Describe the energy needs of the brain.
  • Relate the function of blood with the function of other tissues.
  • Compare the hormonal regulation of fuel metabolism immediately after and several hours after intake of dietary carbohydrates.
  • Explain how the body responds to prolonged fasting or starvation.
  • Describe an animal's hormonal response to a stressful situation.
  • Explain the importance of maintaining body mass within an optimal range.
  • Explain how leptin helps maintain body-mass homeostasis.
  • Explain how adiponectin helps maintain body-mass homeostasis.
  • Explain how diet regulates the expression of genes central to maintaining body-mass homeostasis.
  • Explain how endocrine cells in the intestinal lining affect eating behavior.
  • Explain how the microbiome in the gut contributes to body-mass homeostasis.
  • Differentiate between the two major clinical classes of diabetes mellitus.

21

Genes and Chromosomes
  • Chromosomal Elements
  • DNA Supercoiling
  • The Structure of Chromosomes
  • Compare viral, bacterial, and eukaryotic genomes.
  • Explain how supercoiling helps cells or viruses compact large DNA molecules into a small space.
  • Explain the biological importance of regulating DNA supercoiling.
  • Describe how the organization of chromatin influences gene expression.

22

DNA Metabolism
  • DNA Replication
  • DNA Repair
  • DNA Recombination
  • Explain how cells enzymatically degrade and synthesize DNA.
  • Explain the biological importance of repairing DNA damage.
  • Explain the biological importance of DNA recombination in bacteria.
  • Explain the biological importance of DNA recombination in eukaryotes.
  • Explain how a mammal can produce millions of different immunoglobulins (antibodies) with distinct binding specificities.

23

RNA Metabolism
  • DNA-Dependent Synthesis of RNA
  • RNA Processing
  • RNA-Dependent Synthesis of RNA and DNA
  • Catalytic RNAs and the RNA World Hypothesis
  • Explain how transcription is dependent on DNA.
  • Explain how transcription is regulated at several levels.
  • Describe RNA processing.
  • Explain the importance of mRNA splicing and end modifications.
  • Explain the importance of rRNA, tRNA, and special-function noncoding RNAs.
  • Explain how RNA synthesis and degradation regulate gene expression.
  • Explain why the existence of RNA replication requires an elaboration of the central dogma of biology.
  • Explain the role of reverse transcription in eukaryotes.
  • Explain how RNA can act as a catalyst.

24

Protein Metabolism
  • The Genetic Code
  • Protein Synthesis
  • Protein Targeting and Degradation
  • Describe the key features of the genetic code.
  • Relate the sequence of an amino acids in a protein with the mRNA sequence it is encoded by.
  • Explain how tRNAs serve as adaptor molecules during translation.
  • Describe the key features of the ribosome.
  • Describe the steps in ribosome synthesis.
  • Compare translation initiation in bacteria and eukaryotes.
  • Explain how ribosomes catalyze polypeptide synthesis.
  • Explain how translation is terminated.
  • Explain how exogenous substances such as antibiotics and toxins can be used to study translation.
  • Explain how posttranslational modifications contribute to the thermodynamic cost of protein synthesis.
  • Explain how cells target newly-synthesized proteins to locations in and out of the cell.
  • Explain how eukaryotic cells import substances from the surrounding medium.
  • Explain how RNA editing can be used to alter the meaning of an mRNA transcript.

25

Regulation of Gene Expression
  • The Proteins and RNAs of Gene Regulation
  • Regulation of Gene Expression in Bacteria
  • Regulation of Gene Expression in Eukaryotes
  • Explain how changing the interaction between RNA polymerase and DNA regulates transcription.
  • Explain the role of various gene products in the regulation of transcription initiation.
  • Explain how combinatorial control is used to modulate the expression of eukaryotic genes.
  • Explain how bacteria regulate expression of the lac operon.
  • Explain how bacteria regulate expression of the trp operon.
  • Explain how the SOS repair mechanism can lead to evolution in bacteria.
  • Explain how bacteria coordinate the synthesis of ribosomal components.
  • Explain how small RNAs (sRNAs) regulate the function of some mRNAs.
  • Explain how eukaryotic cells turn on genes.
  • Explain how eukaryotes regulate gene expression at the level of translation.
  • Explain the importance of gene regulation in early development.
  • Describe uses for stem cells in medical research.

26

Final Exam

Completion of Organic Chemistry I & II or their equivalent is strongly encouraged, though not required.

The required eTextbook for this course is included with your course purchase at no additional cost. More information on StraighterLine eTextbooks

Prefer the hard copy? Simply purchase from your favorite textbook retailer; you will still get the eTextbook for free.

This course does not require a text.

Your score provides a percentage score and letter grade for each course. A passing percentage is 70% or higher.

There are a total of 1000 points in the course:

6

Graded Exam 1

125

1, 2

12

Graded Exam 2

125

3-8
12

Midterm Exam

200

1-8

18

Graded Exam 3

125

9-13

25

Graded Exam 4

125

14, 15
26

Final Exam

300

1-15
Total

1000

Topic

Assessment

Points

LOs

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Course Objectives

After completing the course, students will be able to:

  • Identify weak interactions in aqueous systems, ionizations of water, and buffers against pH changes in biological systems.
  • Contrast primary, secondary, tertiary, and quaternary structures of proteins and their effects on binding and interactions.
  • Sort monosaccharides, disaccharides, polysaccharides, and glycoconjugates.
  • Understand nucleic acid structure and chemistry.
  • Contrast the functions and features of lipids when acting as signals, cofactors, and pigments.
  • Understand the relationship of membrane dynamics with their composition and architecture.
  • Explain how the G Protein, gated ion channels, regulation of transcription and cell cycle achieve biochemical signaling.
  • Identify the effects of bioenergetics and thermodynamics on metabolism.
  • Explain the role of glycogen and glycolysis in metabolic pathways.
  • Articulate the citric acid cycle.
  • Understand the digestion, mobilization, and transport of fats.
  • Articulate the role of ATP in oxidative phosphorylation.
  • Explain the biosynthesis of fatty acids, triacylglycerols and membrane phospholipids.
  • Understand the role of hormone regulation on metabolism.
  • Articulate how genes, chromosomes, DNA, RNA, and other proteins are used as information pathways.

Topics

Topic

Subtopics

Objectives

1

The Foundations of Biochemistry
  • Cellular Foundations
  • Chemical Foundations
  • Physical Foundations
  • Genetic Foundations
  • Evolutionary Foundations
  • Describe an organism at the cellular level.
  • Explain how cell size and function are connected.
  • Relate biomolecule composition, structure, and function.
  • Describe the dynamic steady state maintained by a living organism.
  • Construct a description of the thermodynamic basis for a reaction.
  • Relate the origins of life to biochemical processes that occur today.
  • Explain how cellular systems and processes can be studied.
  • Describe the flow of information from linear DNA to three-dimensional proteins.
  • Describe how genetic changes can alter gene function.

2

Water, the Solvent of Life
  • Weak Interactions in Aqueous Systems
  • Ionization of Water, Weak Acids, and Weak Bases
  • Buffering against pH Changes in Biological Systems
  • Explain how weak interactions between biomolecules confer stability in aqueous solutions.
  • Explain the importance of entropy to biological systems.
  • Explain why biological systems must regulate osmotic pressure.
  • Apply concepts of acid-base equilibria to a system.
  • Determine the concentration or amount of a substance present by titration.
  • Explain the importance of buffers to biological systems.

3

Amino Acids, Peptides, and Proteins
  • Amino Acids
  • Peptides and Proteins
  • Working with Proteins
  • The Structure of Proteins: Primary Structure
  • Determine the identity of an amino acid from experimental data.
  • Determine the structure of an amino acid from the pH of its solvent.
  • Determine the composition of a polypeptide or protein from experimental data.
  • Analyze the effectiveness of a purification strategy used to separate a mixture of proteins or amino acids.
  • Determine the components of a mixture from electrophoresis data.
  • Determine the primary structure of polypeptide or protein from experimental data.
  • Analyze an evolutionary relationship from the sequence of amino acids in a protein or polypeptide.
  • Relate the absorbance, concentration, molar extinction coefficient, and pathlength for a sample analyzed by spectrophotometry.

4

The Three-Dimensional Structure of Proteins
  • Overview of Protein Structure
  • Protein Secondary Structure
  • Protein Tertiary and Quaternary Structures
  • Protein Denaturation and Folding
  • Determination of Protein and Biomolecular Structures
  • Explain how chemical and physical interactions govern protein structure and stability.
  • Relate the structure and biological function of a protein.
  • Explain the relationship between disruptions in proteostasis and disease.
  • Describe how a protein adopts its native conformation.
  • Analyze protein three-dimensional structure using amino acid sequences, experimental data, and models.

5

Protein Function
  • Reversible Binding of a Protein to a Ligand: Oxygen-Binding Proteins
  • Complementary Interactions between Proteins and Ligands: The Immune System and Immunoglobulins
  • Protein Interactions Modulated by Chemical Energy: Actin, Myosin, and Molecular Motors
  • Construct a quantitative description of the interaction between a protein and ligand using experimental data.
  • Describe the allosteric interactions governing a protein and ligand pair using experimental data.
  • Predict how changes in the solvent or structure of a globin protein will affect its ability to store and transport oxygen in the body.
  • Explain the significance of the antibody-antigen interaction.
  • Explain how conformational changes at the molecular level produce muscle movement.

6

Enzymes
  • An Introduction to Enzymes
  • How Enzymes Work
  • Enzyme Kinetics as an Approach to Understanding Mechanism
  • Examples of Enzymatic Reactions
  • Regulatory Enzymes
  • Construct a general description of an enzyme from experimental data.
  • Describe the energetic basis of enzyme-mediated catalysis.
  • Propose the mechanism by which an enzyme catalyzes a reaction.
  • Construct a kinetic description of the reaction catalyzed by an enzyme that obeys Michaelis-Menten kinetics.
  • Propose a mechanism for inhibition of a non-allosteric enzyme based on experimental data.
  • Explain how chymotrypsin cleaves a substrate.
  • Propose a mechanism of allosteric regulation for an enzyme based on experimental data.
  • Propose a mechanism of regulatory modification for an enzyme based on experimental data.
  • Explain the importance of enzyme regulation in blood coagulation.

7

Carbohydrates and Glycobiology
  • Monosaccharides and Disaccharides
  • Polysaccharides
  • Glycoconjugates: Proteoglycans, Glycoproteins, and Glycolipids
  • Carbohydrates as Informational Molecules: The Sugar Code
  • Working with Carbohydrates
  • Construct a description of a carbohydrate.
  • Relate the structure, composition, chemical properties, and biological function of a monosaccharide.
  • Explain how blood glucose concentration and health are connected.
  • Relate the structure, composition, properties, and function of a carbohydrate polymer.
  • Explain how glycoconjugate synthesis, function, and destruction relate to health.
  • Explain the importance of lectin:carbohydrate interactions.
  • Propose a scheme for analyzing a glycoconjugate.

8

Nucleotides and Nucleic Acids
  • Some Basic Definitions and Conventions
  • Nucleic Acid Structure
  • Nucleic Acid Chemistry
  • Other Functions of Nucleotides
  • Relate the name, structure, and symbolic representation of a nucleic acid.
  • Explain how DNA studies lead to the model for DNA structure
  • Explain the significance of B-form DNA structure.
  • Relate the number of bases, rise per base, or number of helical turns to the length of a nucleic acid.
  • Relate the sequence, structure, and activities of unusual DNA structures.
  • Relate the sequence, structure, and activities of RNA molecules.
  • Relate the structure of a nucleic acid to its properties.
  • Explain the importance of nucleic acid modifications to life.
  • Interpret the results of a polymerase chain reaction (PCR) experiment.
  • Determine the sequence of nucleotides in a molecule of nucleic acid.
  • Explain the significance of nucleic acids and their derivatives to life.

9

Lipids
  • Storage Lipids
  • Structural Lipids in Membranes
  • Lipids as Signals, Cofactors, and Pigments
  • Working with Lipids
  • Relate the structure, physical properties, and function of storage lipids.
  • Relate the general structure, composition, and properties of a membrane lipid.
  • Explain the importance of membrane lipid structure to health.
  • Describe the roles of lipids outside of storage and structure.
  • Determine the structure and composition of a lipid from experimental data.

10

Biological Membranes and Transport
  • The Composition and Architecture of Membranes
  • Membrane Dynamics
  • Solute Transport across Membranes
  • Explain the importance of diversity in membrane composition and structure to life.
  • Classify membrane proteins based on their structure, function, and properties.
  • Explain how membrane function is connected to the organization and dynamics of lipids within membranes.
  • Explain why membrane fusion, fission, and curvature are important for homeostasis.
  • Connect mechanisms of substance transfer in and out of cells with cellular function.
  • Propose a scheme for studying a plasma membrane component.
  • Construct a quantitative description of transporter-mediated solute transport.
  • Connect the distribution and activities of glucose transporters in humans with the needs of different tissues.

11

Biochemical Signaling
  • General Features of Signal Transduction
  • G Protein–Coupled Receptors and Second Messengers
  • GPCRs in Vision, Olfaction, and Gustation
  • Receptor Tyrosine Kinases
  • Multivalent Adaptor Proteins and Membrane Rafts
  • Gated Ion Channels
  • Regulation of Transcription by Nuclear Hormone Receptors
  • Regulation of the Cell Cycle by Protein Kinases
  • Oncogenes, Tumor Suppressor Genes, and Programmed Cell Death
  • Explain how signals are communicated and integrated through G protein-coupled receptor (GPCR) signaling pathways.
  • Predict the effects of altering cyclic AMP (cAMP) function in the cell.
  • Predict the effects of an intervention or mutation on signaling through G protein-coupled receptors (GPCRs).
  • Predict the effects of an intervention or mutation on signaling through receptor tyrosine kinases (RTKs).
  • Describe the versatility in signaling pathways afforded by the variety of pathway components.
  • Predict the effects of an intervention or mutation on signaling through gated-ion channels.
  • Predict the effect of an intervention or mutation on signaling through a nuclear hormone receptor.
  • Describe the roles of protein kinases in cell cycle regulation.
  • Explain how defects in regulation of the cell cycle can lead to disease.
  • Describe the function of a signaling pathway based on experimental data.

12

Introduction to Metabolism
  • Bioenergetics and Thermodynamics
  • Chemical Logic and Common Biochemical Reactions
  • Phosphoryl Group Transfers and ATP
  • Biological Oxidation-Reduction Reactions
  • Regulation of Metabolic Pathways
  • Explain a biochemical reaction by providing the curved-arrow mechanism.
  • Explain how the removal of phosphate groups from phosphorylated compounds is used to power reactions in the cell.
  • Construct a quantitative description of a biological oxidation-reduction reaction.
  • Use experimental data to monitor the flow of electrons through a series of biochemical reactions.
  • Explain how multiple mechanisms of regulation can collaborate to maintain the dynamic steady state of a cell.

13

Glycolysis, Gluconeogenesis, and the Pentose Phosphate Pathway
  • Glycolysis
  • Feeder Pathways for Glycolysis
  • Fates of Pyruvate
  • Gluconeogenesis
  • Coordinated Regulation of Glycolysis and Gluconeogenesis
  • Pentose Phosphate Pathway of Glucose Oxidation
  • Explain how organisms produce energy through glycolysis.
  • Explain how glycolysis can be used to metabolize starting materials other than glucose.
  • Explain how pyruvate will be metabolized under given conditions.
  • Determine the free energy released by catabolism of a carbohydrate under given conditions.
  • Explain the importance of carbohydrate metabolism to health.
  • Explain how organisms use gluconeogenesis to produce glucose from precursor molecules.
  • Explain why gluconeogenesis is essential even though it is energetically expensive.
  • Predict the path of molecules through glycolysis and gluconeogenesis based on given conditions.
  • Explain how the pentose phosphate pathway is used as an alternative method for metabolizing glucose.

14

The Metabolism of Glycogen in Animals
  • The Structure and Function of Glycogen
  • Breakdown and Synthesis of Glycogen
  • Coordinated Regulation of Glycogen Breakdown and Synthesis
  • Relate the structure and function of glycogen polymers and granules.
  • Explain how animals release glucose from glycogen stores.
  • Explain how animals store excess glucose as glycogen.
  • Explain how the body coordinates glycogen metabolism based on its energy supply and demand.

15

The Citric Acid Cycle
  • Production of Acetyl-CoA (Activated Acetate)
  • Reactions of the Citric Acid Cycle
  • The Hub of Intermediary Metabolism
  • Regulation of the Citric Acid Cycle
  • Explain how pyruvate is activated to produce acetyl-CoA.
  • Explain how the citric acid cycle oxidizes acetyl-CoA to carbon dioxide.
  • Determine the amount of energy released by the aerobic metabolism of a carbohydrate.
  • Explain how the citric acid cycle serves as the central hub of intermediary metabolism.
  • Predict how a change will affect the rate of citric acid cycle metabolism.

16

Fatty Acid Catabolism
  • Digestion, Mobilization, and Transport of Fats
  • Oxidation of Fatty Acids
  • Ketone Bodies
  • Describe the path of dietary lipids in vertebrates.
  • Explain how fatty acids are prepared for oxidation.
  • Explain how a fatty acid can be completely metabolized.
  • Relate the amount and type of fatty acids burned with body weight.
  • Predict how the metabolism of fatty acids will change depending on the supply of energy in the body.
  • Relate the formation of ketone bodies with alterations in fatty acid metabolism.

17

Oxidative Phosphorylation
  • The Mitochondrial Respiratory Chain
  • ATP Synthesis
  • Regulation of Oxidative Phosphorylation
  • Describe the role of mitochondria in eukaryotic aerobic metabolism.
  • Describe the composition of the mitochondrial respiratory chain.
  • Explain how electrons enter the mitochondrial respiratory chain.
  • Explain how the mitochondrial respiratory chain shuttles electrons to molecular oxygen.
  • Explain how the mitochondrial respiratory chain produces ATP.
  • Explain how oxidative phosphorylation can be regulated.
  • Describe additional roles for mitochondria other than the generation of ATP.
  • Describe the implications and consequences of mitochondria possessing their own genome.

18

Lipid Biosynthesis
  • Biosynthesis of Fatty Acids and Eicosanoids
  • Biosynthesis of Triacylglycerols
  • Biosynthesis of Membrane Phospholipids
  • Cholesterol, Steroids, and Isoprenoids: Biosynthesis, Regulation, and Transport
  • Explain how organisms synthesize palmitate.
  • Explain how organisms coordinate fatty acid synthesis with other metabolic processes.
  • Explain how organisms elongate fatty acids.
  • Explain how organisms generate complex fatty acids.
  • Explain how organisms synthesize triacylglycerols.
  • Explain how adipose tissue produces glycerol 3-phosphate.
  • Explain how organisms use fatty acids to synthesize membrane lipids.
  • Explain how organisms synthesize cholesterol.
  • Explain how lipids and cholesterol are transported throughout the body.
  • Explain how cholesterol metabolism is regulated.
  • Describe how cholesterol and its synthetic pathway intermediates can be used in the body outside of lipid metabolism.
  • Explain the importance of regulating cholesterol metabolism.

19

Biosynthesis of Amino Acids, Nucleotides, and Related Molecules
  • Overview of Nitrogen Metabolism
  • Biosynthesis of Amino Acids
  • Molecules Derived from Amino Acids
  • Biosynthesis and Degradation of Nucleotides
  • Explain how a complex web of reactions converts atmospheric nitrogen to biologically useful forms and maintains a global balance between them.
  • Explain how reactive forms of nitrogen are incorporated into biological systems through glutamate and glutamine.
  • Explain how organisms synthesize the 20 common amino acids.
  • Explain the regulation of amino acid synthesis.
  • Explain how amino acids serve as precursors of many specialized biomolecules.
  • Contrast the two pathways for nucleotide synthesis.
  • Detail the processes of de novo purine nucleotide synthesis.
  • Detail the processes of de novo pyrimidine nucleotide synthesis.
  • Explain how deoxyribonucleic acids are formed.
  • Explain how salvage pathways recycle purine and pyrimidine bases.
  • Explain the regulation of nucleotide biosynthesis.
  • Explain the importance of nucleic acid metabolism to health.

20

Hormonal Regulation and Integration of Mammalian Metabolism
  • Hormone Structure and Action
  • Tissue-Specific Metabolism
  • Hormonal Regulation of Fuel Metabolism
  • Obesity and the Regulation of Body Mass
  • Diabetes Mellitus
  • Explain how mammals coordinate activities between different tissues and organs.
  • Describe insulin production, storage, and release.
  • Describe the role of the liver in the metabolism of nutrients.
  • Compare the function of white adipose tissue (WAT) and brown adipose tissue (BAT).
  • Describe the specialized metabolism of muscle cells.
  • Describe the energy needs of the brain.
  • Relate the function of blood with the function of other tissues.
  • Compare the hormonal regulation of fuel metabolism immediately after and several hours after intake of dietary carbohydrates.
  • Explain how the body responds to prolonged fasting or starvation.
  • Describe an animal's hormonal response to a stressful situation.
  • Explain the importance of maintaining body mass within an optimal range.
  • Explain how leptin helps maintain body-mass homeostasis.
  • Explain how adiponectin helps maintain body-mass homeostasis.
  • Explain how diet regulates the expression of genes central to maintaining body-mass homeostasis.
  • Explain how endocrine cells in the intestinal lining affect eating behavior.
  • Explain how the microbiome in the gut contributes to body-mass homeostasis.
  • Differentiate between the two major clinical classes of diabetes mellitus.

21

Genes and Chromosomes
  • Chromosomal Elements
  • DNA Supercoiling
  • The Structure of Chromosomes
  • Compare viral, bacterial, and eukaryotic genomes.
  • Explain how supercoiling helps cells or viruses compact large DNA molecules into a small space.
  • Explain the biological importance of regulating DNA supercoiling.
  • Describe how the organization of chromatin influences gene expression.

22

DNA Metabolism
  • DNA Replication
  • DNA Repair
  • DNA Recombination
  • Explain how cells enzymatically degrade and synthesize DNA.
  • Explain the biological importance of repairing DNA damage.
  • Explain the biological importance of DNA recombination in bacteria.
  • Explain the biological importance of DNA recombination in eukaryotes.
  • Explain how a mammal can produce millions of different immunoglobulins (antibodies) with distinct binding specificities.

23

RNA Metabolism
  • DNA-Dependent Synthesis of RNA
  • RNA Processing
  • RNA-Dependent Synthesis of RNA and DNA
  • Catalytic RNAs and the RNA World Hypothesis
  • Explain how transcription is dependent on DNA.
  • Explain how transcription is regulated at several levels.
  • Describe RNA processing.
  • Explain the importance of mRNA splicing and end modifications.
  • Explain the importance of rRNA, tRNA, and special-function noncoding RNAs.
  • Explain how RNA synthesis and degradation regulate gene expression.
  • Explain why the existence of RNA replication requires an elaboration of the central dogma of biology.
  • Explain the role of reverse transcription in eukaryotes.
  • Explain how RNA can act as a catalyst.

24

Protein Metabolism
  • The Genetic Code
  • Protein Synthesis
  • Protein Targeting and Degradation
  • Describe the key features of the genetic code.
  • Relate the sequence of an amino acids in a protein with the mRNA sequence it is encoded by.
  • Explain how tRNAs serve as adaptor molecules during translation.
  • Describe the key features of the ribosome.
  • Describe the steps in ribosome synthesis.
  • Compare translation initiation in bacteria and eukaryotes.
  • Explain how ribosomes catalyze polypeptide synthesis.
  • Explain how translation is terminated.
  • Explain how exogenous substances such as antibiotics and toxins can be used to study translation.
  • Explain how posttranslational modifications contribute to the thermodynamic cost of protein synthesis.
  • Explain how cells target newly-synthesized proteins to locations in and out of the cell.
  • Explain how eukaryotic cells import substances from the surrounding medium.
  • Explain how RNA editing can be used to alter the meaning of an mRNA transcript.

25

Regulation of Gene Expression
  • The Proteins and RNAs of Gene Regulation
  • Regulation of Gene Expression in Bacteria
  • Regulation of Gene Expression in Eukaryotes
  • Explain how changing the interaction between RNA polymerase and DNA regulates transcription.
  • Explain the role of various gene products in the regulation of transcription initiation.
  • Explain how combinatorial control is used to modulate the expression of eukaryotic genes.
  • Explain how bacteria regulate expression of the lac operon.
  • Explain how bacteria regulate expression of the trp operon.
  • Explain how the SOS repair mechanism can lead to evolution in bacteria.
  • Explain how bacteria coordinate the synthesis of ribosomal components.
  • Explain how small RNAs (sRNAs) regulate the function of some mRNAs.
  • Explain how eukaryotic cells turn on genes.
  • Explain how eukaryotes regulate gene expression at the level of translation.
  • Explain the importance of gene regulation in early development.
  • Describe uses for stem cells in medical research.

26

Final Exam

Completion of Organic Chemistry I & II or their equivalent is strongly encouraged, though not required.

The required eTextbook for this course is included with your course purchase at no additional cost. More information on StraighterLine eTextbooks

Prefer the hard copy? Simply purchase from your favorite textbook retailer; you will still get the eTextbook for free.

This course does not require a text.

Your score provides a percentage score and letter grade for each course. A passing percentage is 70% or higher.

There are a total of 1000 points in the course:

6

Graded Exam 1

125

1, 2

12

Graded Exam 2

125

3-8
12

Midterm Exam

200

1-8

18

Graded Exam 3

125

9-13

25

Graded Exam 4

125

14, 15
26

Final Exam

300

1-15
Total

1000

Topic

Assessment

Points

LOs

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