Name: Enzyme Kinetics
Uploaded: 2023-01-10T08:50:33-05:00
Duration: 1 min 19 s
Description: Enzymes speed up reactions by lowering the activation energy of the reactants. The speed at which the enzyme turns reactants into products is called the rate of reaction.

Chapter 7: Metabolism Back To Chapter

7.11: Enzyme Kinetics

TABLE OF
CONTENTS

X

Chapter 1: Scientific Inquiry

30
1.1: Characteristics of Life
30
1.2: Levels of Organization
30
1.3: The Scientific Method
30
1.4: Inductive Reasoning
30
1.5: Deductive Reasoning
30
1.6: Correlation and Causation
30
1.7: Taxonomy
30
1.8: Phylogeny

Chapter 2: Chemistry of Life

30
2.1: The Periodic Table and Organismal Elements
30
2.2: Atomic Structure
30
2.3: Electron Behavior
30
2.4: Electron Orbital Model
30
2.5: Elements and Compounds
30
2.6: Molecular Shapes
30
2.7: Carbon Skeletons
30
2.8: Chemical Reactions
30
2.9: Isotopes
30
2.10: Covalent Bonds
30
2.11: Ionic Bonds
30
2.12: Hydrogen Bonds
30
2.13: Van der Waals Interactions
30
2.14: States of Water
30
2.15: pH
30
2.16: Solvents
30
2.17: Redox Reactions
30
2.18: Adhesion
30
2.19: Cohesion
30
2.20: Specific Heat
30
2.21: Vaporization

Chapter 3: Macromolecules

30
3.1: What are Proteins?
30
3.2: Protein Organization
30
3.3: Protein Folding
30
3.4: What are Carbohydrates?
30
3.5: Dehydration Synthesis
30
3.6: Hydrolysis
30
3.7: What are Lipids?
30
3.8: Nucleic acids
30
3.9: Phosphodiester Linkages

Chapter 4: Cell Structure and Function

30
4.1: What are Cells?
30
4.2: Cell Size
30
4.3: Eukaryotic Compartmentalization
30
4.4: Prokaryotic Cells
30
4.5: Cytoplasm
30
4.6: The Nucleus
30
4.7: Endoplasmic Reticulum
30
4.8: Ribosomes
30
4.9: Golgi Apparatus
30
4.10: Microtubules
30
4.11: Peroxisomes and Mitochondria
30
4.12: Gap Junctions
30
4.13: The Extracellular Matrix
30
4.14: Tissues
30
4.15: Plant Cell Wall
30
4.16: Plasmodesmata

Chapter 5: Membranes and Cellular Transport

30
5.1: What are Membranes?
30
5.2: Membrane Fluidity
30
5.3: The Fluid Mosaic Model
30
5.4: What is an Electrochemical Gradient?
30
5.5: Diffusion
30
5.6: Osmosis
30
5.7: Tonicity in Animals
30
5.8: Tonicity in Plants
30
5.9: Introduction to Membrane Proteins
30
5.10: Facilitated Transport
30
5.11: Primary Active Transport
30
5.12: Secondary Active Transport
30
5.13: Receptor-mediated Endocytosis
30
5.14: Pinocytosis
30
5.15: Phagocytosis
30
5.16: Exocytosis

Chapter 6: Cell Signaling

30
6.1: What is Cell Signaling?
30
6.2: Bacterial Signaling
30
6.3: Yeast Signaling
30
6.4: Contact-dependent Signaling
30
6.5: Autocrine Signaling
30
6.6: Paracrine Signaling
30
6.7: Synaptic Signaling
30
6.8: G-protein Coupled Receptors
30
6.9: Internal Receptors
30
6.10: Endocrine Signaling
30
6.11: What are Second Messengers?
30
6.12: Intracellular Signaling Cascades
30
6.13: Ion Channels
30
6.14: Enzyme-linked Receptors

Chapter 7: Metabolism

30
7.1: What is Metabolism?
30
7.2: First Law of Thermodynamics
30
7.3: Second Law of Thermodynamics
30
7.4: Kinetic Energy
30
7.5: Potential Energy
30
7.6: Free Energy
30
7.7: Activation Energy
30
7.8: Hydrolysis of ATP
30
7.9: Phosphorylation
30
7.10: Induced-fit Model
30
7.11: Enzyme Kinetics
30
7.12: Enzyme Inhibition
30
7.13: Feedback Inhibition
30
7.14: Allosteric Regulation
30
7.15: Cofactors and Coenzymes

Chapter 8: Cellular Respiration

30
8.1: Introduction to Cellular Respiration
30
8.2: What is Glycolysis?
30
8.3: Energy-requiring Steps of Glycolysis
30
8.4: Energy-releasing Steps of Glycolysis
30
8.5: Outcomes of Glycolysis
30
8.6: Pyruvate Oxidation
30
8.7: The Citric Acid Cycle
30
8.8: Products of the Citric Acid Cycle
30
8.9: Electron Transport Chains
30
8.10: Chemiosmosis
30
8.11: Electron Carriers
30
8.12: ATP Yield
30
8.13: Fermentation
30
8.14: Dietary Connections

Chapter 9: Photosynthesis

30
9.1: What is Photosynthesis?
30
9.2: Light as Energy
30
9.3: Anatomy of Chloroplasts
30
9.4: Photosystem II
30
9.5: Photosystem I
30
9.6: The Calvin Cycle
30
9.7: C4 Pathway and CAM

Chapter 10: Cell Cycle and Division

30
10.1: What is the Cell Cycle?
30
10.2: Genomic DNA in Prokaryotes
30
10.3: Binary Fission
30
10.4: Genomic DNA in Eukaryotes
30
10.5: Interphase
30
10.6: Mitosis and Cytokinesis
30
10.7: Positive Regulator Molecules
30
10.8: Negative Regulator Molecules
30
10.9: Cancer

Chapter 11: Meiosis

30
11.1: What is Meiosis?
30
11.2: Meiosis I
30
11.3: Meiosis II
30
11.4: Crossing Over
30
11.5: Nondisjunction

Chapter 12: Classical and Modern Genetics

30
12.1: Genetic Lingo
30
12.2: Punnett Squares
30
12.3: Monohybrid Crosses
30
12.4: Dihybrid Crosses
30
12.5: Law of Segregation
30
12.6: Law of Independent Assortment
30
12.7: Test Cross
30
12.8: Pedigree Analysis
30
12.9: Probability Laws
30
12.10: Multiple Allele Traits
30
12.11: Chromosomal Theory of Inheritance
30
12.12: Non-nuclear Inheritance
30
12.13: X-linked Traits
30
12.14: Sex-linked Disorders
30
12.15: X-Inactivation
30
12.16: Epistasis
30
12.17: Polygenic Traits
30
12.18: Pleiotropy
30
12.19: Nature and Nurture

Chapter 13: DNA Structure and Function

30
13.1: The DNA Helix
30
13.2: DNA Packaging
30
13.3: Organization of Genes
30
13.4: Karyotyping
30
13.5: Replication in Prokaryotes
30
13.6: Replication in Eukaryotes
30
13.7: Proofreading
30
13.8: Mismatch Repair
30
13.9: Nucleotide Excision Repair
30
13.10: Mutations
30
13.11: Transcription
30
13.12: Translation
30
13.13: Bacterial Transformation

Chapter 14: Gene Expression

30
14.1: What is Gene Expression?
30
14.2: The Central Dogma
30
14.3: Transcription Factors
30
14.4: RNA Structure
30
14.5: RNA Stability
30
14.6: pre-mRNA Processing
30
14.7: Types of RNA
30
14.8: MicroRNAs
30
14.9: RNA Splicing
30
14.10: Epigenetic Regulation
30
14.11: RNA Interference
30
14.12: Operons

Chapter 15: Biotechnology

30
15.1: What is Genetic Engineering?
30
15.2: Antibiotic Selection
30
15.3: Recombinant DNA
30
15.4: Transgenic Organisms
30
15.5: Adult Stem Cells
30
15.6: Embryonic Stem Cells
30
15.7: Induced Pluripotent Stem Cells
30
15.8: In-vitro Mutagenesis
30
15.9: DNA Isolation
30
15.10: Gene Therapy
30
15.11: Reproductive Cloning
30
15.12: CRISPR
30
15.13: Complementary DNA
30
15.14: PCR
30
15.15: Genomics

Chapter 16: Viruses

30
16.1: What are Viruses?
30
16.2: Viral Structure
30
16.3: Lytic Cycle of Bacteriophages
30
16.4: Lysogenic Cycle of Bacteriophages
30
16.5: Retrovirus Life Cycles
30
16.6: Viral Recombination
30
16.7: Viral Mutations

Chapter 17: Nutrition and Digestion

30
17.1: What is Monogastric Digestion?
30
17.2: Anatomy of the Intestines
30
17.3: Accessory Organs
30
17.4: Lipid Digestion
30
17.5: Protein Digestion
30
17.6: Carbohydrate Digestion
30
17.7: Neural Regulation
30
17.8: Hormonal Regulation

Chapter 18: Nervous System

30
18.1: What is a Nervous System?
30
18.2: The Parasympathetic Nervous System
30
18.3: The Sympathetic Nervous System
30
18.4: The Blood-brain Barrier
30
18.5: Neuron Structure
30
18.6: The Synapse
30
18.7: Glial Cells
30
18.8: The Resting Membrane Potential
30
18.9: Action Potentials
30
18.10: Long-term Potentiation
30
18.11: Long-term Depression

Chapter 19: Sensory Systems

30
19.1: What is a Sensory System?
30
19.2: The Tongue and Taste Buds
30
19.3: Gustation
30
19.4: Olfaction
30
19.5: Hearing
30
19.6: Hair Cells
30
19.7: The Cochlea
30
19.8: The Vestibular System
30
19.9: The Retina
30
19.10: Vision
30
19.11: Somatosensation
30
19.12: Thermosensation

Chapter 20: Musculoskeletal System

30
20.1: What is the Skeletal System?
30
20.2: Bone Structure
30
20.3: Joints
30
20.4: Bone Remodeling
30
20.5: Skeletal Muscle Anatomy
30
20.6: Classification of Skeletal Muscle Fibers
30
20.7: Muscle Contraction
30
20.8: Cross-bridge Cycle
30
20.9: Motor Units
30
20.10: The Spinal Cord
30
20.11: Nociception

Chapter 21: Endocrine System

30
21.1: What is the Endocrine System?
30
21.2: Types of Hormones
30
21.3: Intracellular Hormone Receptors
30
21.4: Cell-surface Signaling
30
21.5: Feedback Loops
30
21.6: Hypothalamic-Pituitary Axis

Chapter 22: Circulatory and Pulmonary Systems

30
22.1: The Respiratory System
30
22.2: Breathing
30
22.3: Lung Capacity
30
22.4: Gas Exchange and Transport
30
22.5: Anatomy of the Circulatory System
30
22.6: Anatomy of the Heart
30
22.7: The Cardiac Cycle
30
22.8: Blood Flow

Chapter 23: Osmoregulation and Excretion

30
23.1: What Are Osmoregulation and Excretion?
30
23.2: Kidney Structure
30
23.3: Filtration and Urine Formation
30
23.4: Urea Cycle
30
23.5: Hormonal Regulation
30
23.6: Comparative Excretory Systems
30
23.7: Osmoregulation in Fishes
30
23.8: Osmoregulation in Insects

Chapter 24: Immune System

30
24.1: What is the Immune System?
30
24.2: Cell-mediated Immune Responses
30
24.3: Humoral Immune Responses
30
24.4: Antibody Structure
30
24.5: Affinity and Avidity
30
24.6: Cross-reactivity
30
24.7: Allergic Reactions
30
24.8: Inflammation
30
24.9: Vaccinations

Chapter 25: Reproduction and Development

30
25.1: Spermatogenesis
30
25.2: Oogenesis
30
25.3: Fertilization
30
25.4: Cleavage and Blastulation
30
25.5: Gastrulation
30
25.6: Neurulation
30
25.7: Cell Migration
30
25.8: Determination

Chapter 26: Behavior

30
26.1: What is Behavior?
30
26.2: Imprinting
30
26.3: Communication
30
26.4: Migration
30
26.5: Mate Choice
30
26.6: Fixed Action Patterns
30
26.7: Optimal Foraging
30
26.8: Parental Care
30
26.9: Altruism
30
26.10: Inclusive Fitness

Chapter 27: Ecosystems

30
27.1: What is an Ecosystem?
30
27.2: Trophic Levels
30
27.3: Primary Production
30
27.4: Production Efficiency
30
27.5: Trophic Efficiency
30
27.6: What are Biogeochemical Cycles?
30
27.7: The Water Cycle
30
27.8: The Carbon Cycle
30
27.9: The Nitrogen Cycle
30
27.10: The Phosphorus Cycle
30
27.11: The Sulfur Cycle
30
27.12: Bioremediation

Chapter 28: Population and Community Ecology

30
28.1: What are Populations and Communities?
30
28.2: Distribution and Dispersion
30
28.3: Life Histories
30
28.4: Energy Budgets
30
28.5: Population Growth
30
28.6: Ecological Niches
30
28.7: Ecological Succession
30
28.8: Keystone Species
30
28.9: Symbiosis
30
28.10: Competition
30
28.11: Predator-Prey Interactions
30
28.12: Ecological Disturbance

Chapter 29: Biodiversity and Conservation

30
29.1: What is Biodiversity?
30
29.2: Threats to Biodiversity
30
29.3: Biodiversity and Human Values
30
29.4: What is Conservation Biology?
30
29.5: Sustainable Development
30
29.6: Conservation of Small Populations
30
29.7: What is Weather?
30
29.8: What is Climate?
30
29.9: Global Climate Change
30
29.10: Conservation of Declining Populations
30
29.11: Habitat Fragmentation

Chapter 30: Speciation and Diversity

30
30.1: What is a Species?
30
30.2: Formation of Species
30
30.3: Speciation Rates
30
30.4: Genetics of Speciation
30
30.5: Hybrid Zones

Chapter 31: Natural Selection

30
31.1: What is Natural Selection?
30
31.2: Types of Selection
30
31.3: Frequency-dependent Selection
30
31.4: Limits to Natural Selection

Chapter 32: Population Genetics

30
32.1: What is Population Genetics?
30
32.2: Hardy-Weinberg Principle
30
32.3: Mutation, Gene Flow, and Genetic Drift
30
32.4: Genetic Drift
30
32.5: Gene Flow

Chapter 33: Evolutionary History

30
33.1: Phylogenetic Trees
30
33.2: Conditions on Early Earth
30
33.3: The Colonization of Land
30
33.4: What is Evolutionary History?
30
33.5: The Evidence for Evolution
30
33.6: The Fossil Record
30
33.7: Convergent Evolution

Chapter 34: Plant Structure, Growth, and Nutrition

30
34.1: Introduction to Plant Diversity
30
34.2: Non-vascular Seedless Plants
30
34.3: Seedless Vascular Plants
30
34.4: Introduction to Seed Plants
30
34.5: Basic Plant Anatomy: Roots, Stems, and Leaves
30
34.6: Plant Cells and Tissues
30
34.7: Meristems and Plant Growth
30
34.8: Primary and Secondary Growth in Roots and Shoots
30
34.9: Morphogenesis
30
34.10: Light Acquisition
30
34.11: Water and Mineral Acquisition
30
34.12: Short-distance Transport of Resources
30
34.13: Xylem and Transpiration-driven Transport of Resources
30
34.14: Regulation of Transpiration by Stomata
30
34.15: Adaptations that Reduce Water Loss
30
34.16: Phloem and Sugar Transport
30
34.17: The Soil Ecosystem
30
34.18: Key Elements for Plant Nutrition
30
34.19: The Roles of Bacteria and Fungi in Plant Nutrition
30
34.20: Epiphytes, Parasites, and Carnivores
30
34.21: The Apoplast and Symplast

Chapter 35: Plant Reproduction

30
35.1: Pollination and Flower Structure
30
35.2: The Angiosperm Life Cycle
30
35.3: Seed Structure and Early Development of the Sporophyte
30
35.4: Fruit Development, Structure, and Function
30
35.5: Asexual Reproduction
30
35.6: Plant Tissue Culture
30
35.7: Plant Breeding and Biotechnology

Chapter 36: Plant Responses to the Environment

30
36.1: Plant Hormones
30
36.2: Photoreceptors and Plant Responses to Light
30
36.3: Biological Clocks and Seasonal Responses
30
36.4: Responses to Gravity and Touch
30
36.5: Responses to Drought and Flooding
30
36.6: Responses to Heat and Cold Stress
30
36.7: Responses to Salt Stress
30
36.8: Defenses Against Pathogens and Herbivores

Full Table of Contents

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Enzyme Kinetics

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TRANSCRIPT

Enzyme kinetics studies the rates of enzyme-catalyzed reactions. The rates of repeated experiments at varying substrate concentrations are monitored by measuring the concentration of substrate consumed or product formed over time.

These results can be graphed to show how substrate concentration affects the rate or velocity of a reaction.

The reaction velocity increases linearly with increasing substrate amounts at low concentrations, but it begins to plateau at higher concentrations. The rate approaches a maximum velocity or V_max– the rate where the enzyme is completely saturated with the substrate.

Enzyme affinity measures how strongly or weakly an enzyme binds its substrate and is quantified by K_M, the Michaelis constant. The value of K_M is equal to the substrate concentration when the rate is 50% of the V_max.

A small K_M indicates an enzyme has a high substrate affinity and vice versa. An enzyme with a larger K_M requires higher substrate concentrations to approach its maximum velocity compared to an enzyme with a lower K_M.

7.11: Enzyme Kinetics

Enzymes speed up reactions by lowering the activation energy of the reactants. The speed at which the enzyme turns reactants into products is called the rate of reaction. Several factors impact the rate of reaction, including the number of available reactants. Enzyme kinetics is the study of how an enzyme changes the rate of a reaction.

Scientists typically study enzyme kinetics with a fixed amount of enzyme in the controlled environment of a test tube. When more reactant, or substrate, is added to a fixed amount of enzyme, the rate of the reaction increases as the enzyme can make more product. As a result, when the reaction rate is graphed against substrate concentration, increasing the substrate increases the reaction rate. However, once all the active sites of the enzyme are occupied, the reaction rate plateaus. The concentration of substrate at which the maximum rate of reaction is reached is called V_max. The number of present enzyme molecules limits V_max. If the amount of enzyme is increased, V_max increases, but adding more substrate has no effect.

The graph of rate of reaction versus substrate concentration can reveal other important characteristics of an enzyme’s kinetics. The substrate concentration at which the reaction rate is halfway to V_max (i.e., ½ V_max) is called the Michaelis constant (K_m). K_m is a representation of the affinity between an enzyme and a substrate. Enzymes with a lower K_m require less substrate to reach V_max and therefore have a higher affinity for their substrate. Interestingly, for many enzymes, the value of K_m is very close to the cellular concentration of the substrate. Near K_m, slight changes in substrate concentration can significantly impact the reaction rate, so small changes in cellular substrate availability can impact the function of an entire biological pathway.

Not all enzymes produce the hyperbolic-shaped substrate-rate graph known as Michaelis Menten kinetics. Michaelis Menten kinetics assumes that the enzyme catalyzes a single substrate. Enzymes that are regulated allosterically have multiple active sites and tend to produce a sigmoid-shaped graph when the reaction rate is plotted versus the substrate concentration.

Suggested Reading

Chapter 1: Scientific Inquiry

Chapter 2: Chemistry of Life

Chapter 3: Macromolecules

Chapter 4: Cell Structure and Function

Chapter 5: Membranes and Cellular Transport

Chapter 6: Cell Signaling

Chapter 7: Metabolism

Chapter 8: Cellular Respiration

Chapter 9: Photosynthesis

Chapter 10: Cell Cycle and Division

Chapter 11: Meiosis

Chapter 12: Classical and Modern Genetics

Chapter 13: DNA Structure and Function

Chapter 14: Gene Expression

Chapter 15: Biotechnology

Chapter 16: Viruses

Chapter 17: Nutrition and Digestion

Chapter 18: Nervous System

Chapter 19: Sensory Systems

Chapter 20: Musculoskeletal System

Chapter 21: Endocrine System

Chapter 22: Circulatory and Pulmonary Systems

Chapter 23: Osmoregulation and Excretion

Chapter 24: Immune System

Chapter 25: Reproduction and Development

Chapter 26: Behavior

Chapter 27: Ecosystems

Chapter 28: Population and Community Ecology

Chapter 29: Biodiversity and Conservation

Chapter 30: Speciation and Diversity

Chapter 31: Natural Selection

Chapter 32: Population Genetics

Chapter 33: Evolutionary History

Chapter 34: Plant Structure, Growth, and Nutrition

Chapter 35: Plant Reproduction

Chapter 36: Plant Responses to the Environment

7.11: Enzyme Kinetics

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