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How Your Body Uses ATP to Stay Active and Healthy

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How Your Body Uses ATP to Stay Active and Healthy
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Kristen Song

@kristensong_jhzj

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Cellular metabolism and energy transformation processes in living organisms form the foundation of life. ATP hydrolysis energy coupling cellular respiration drives essential biological functions while enzyme role in spontaneous and non-spontaneous reactions ensures efficient metabolic control.

• Metabolic pathways involve complex series of chemical reactions that convert energy between different forms
• Enzymes play crucial roles in catalyzing both spontaneous and non-spontaneous reactions
• ATP serves as the universal energy currency in cells through energy coupling
• Cellular respiration and photosynthesis are key processes for energy transformation
Competitive and non-competitive enzyme inhibition in metabolic pathways helps regulate metabolism

2/9/2023

292

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Enzymes and Metabolic Regulation

This page focuses on the role of enzymes in metabolic pathways and introduces concepts of enzyme regulation and inhibition.

Enzymes are crucial in lowering the activation energy (Ea) of reactions, thereby increasing reaction rates without changing the overall energy change (ΔG) of the reaction. The page illustrates this concept with an energy diagram showing how enzymes reduce the energy barrier.

Vocabulary: Activation energy (Ea) is the energy difference between the reactant state and the transition state, representing the energy barrier that must be overcome for a reaction to proceed.

The document introduces feedback inhibition as a regulatory mechanism in metabolic pathways. This process involves the end product of a pathway inhibiting an earlier enzyme in the same pathway.

Definition: Feedback inhibition is a regulatory mechanism where the final product of a metabolic pathway inhibits one of the earlier enzymes in that pathway, effectively turning off the production when sufficient product has accumulated.

Two types of enzyme inhibition are discussed:

  1. Competitive inhibition: An inhibitor molecule competes with the substrate for the enzyme's active site.
  2. Non-competitive inhibition: The inhibitor binds to an allosteric site, changing the shape of the active site.

Highlight: Competitive and non-competitive enzyme inhibition in metabolic pathways are crucial mechanisms for regulating cellular metabolism and maintaining homeostasis.

The page also touches on the differences between endotherms (mammals and birds) and ectotherms (reptiles and amphibians) in terms of energy use and temperature regulation.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Energy Acquisition and Utilization in Organisms

This page discusses how different organisms obtain and use energy, focusing on the balance between energy acquisition and expenditure.

The document begins by explaining that all organisms need to obtain energy from their environment, either directly from sunlight (producers) or indirectly through consuming other organisms (consumers).

Example: Plants are presented as an example of organisms that typically perform more photosynthesis than cellular respiration during the day, storing excess energy as biomass (starch).

The page outlines various ways organisms use energy:

  1. Growth (cell division through mitosis)
  2. Reproduction (cell division through binary fission or meiosis)
  3. Maintaining homeostasis (active transport, protein synthesis, DNA repair)

Highlight: The balance between energy intake and expenditure is crucial for survival. For instance, losing weight occurs when calorie use exceeds intake, resulting in the breakdown of stored carbohydrates and fats.

The document contrasts endothermy and ectothermy as strategies for regulating body temperature:

  • Endotherms use internal mechanisms like sweating and shivering.
  • Ectotherms rely on external conditions and behavior, such as basking in the sun or seeking shade.

Vocabulary: Endothermy is the ability to regulate body temperature through internal physiological processes, while ectothermy involves using external heat sources and behavioral adaptations for temperature regulation.

The page concludes by discussing energy conservation strategies in organisms, including feedback inhibition of metabolic pathways, regulating gene expression, seasonal reproduction, and entering low metabolic states like hibernation or estivation.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Cellular Respiration Overview

This page provides an introduction to cellular respiration, presenting its overall formula and a basic flow chart of the process.

The general formula for cellular respiration is given as:

Fuel (glucose) + Oxygen + ADP + Pi → CO₂ + H₂O + ATP

Definition: Cellular respiration is the metabolic process by which cells convert the energy stored in nutrients (like glucose) into ATP, the cell's primary energy currency.

The page presents a balanced equation for the complete oxidation of glucose:

C₆H₁₂O₆ + 6O₂ + ADP + Pi → 6CO₂ + 6H₂O + ATP

The document then introduces the initial stage of cellular respiration: glycolysis. This process breaks down glucose into smaller molecules and can occur without oxygen present.

Highlight: Glycolysis is the first step in cellular respiration and can proceed under both aerobic and anaerobic conditions, generating a small amount of ATP.

The role of electron carriers, specifically NAD+ (nicotinamide adenine dinucleotide), is mentioned. NAD+ picks up high-energy electrons, becoming NADH in the process.

Vocabulary: NAD+ (nicotinamide adenine dinucleotide) is an important coenzyme in cellular respiration that acts as an electron carrier, accepting electrons and protons to become NADH.

The page briefly touches on fermentation, which can occur in the absence of oxygen, but does not elaborate on the process.

Example: The transition from NAD+ (empty carrier) to NADH (full carrier) illustrates how electron carriers function in the cellular respiration process.

This overview sets the stage for a more detailed exploration of the cellular respiration pathway in subsequent lessons.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Cellular Respiration Process

This section provides detailed coverage of cellular respiration steps and mechanisms. It includes the complete reaction formula and pathway components.

Definition: Cellular respiration converts glucose and oxygen into CO2, water, and ATP through multiple steps.

Highlight: The process includes glycolysis, Krebs cycle, and electron transport chain.

Vocabulary: NAD+ serves as an electron carrier, converting to NADH when loaded.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Fermentation Pathways

The content explores anaerobic respiration through fermentation, including its mechanisms and cellular implications.

Definition: Fermentation is anaerobic cellular respiration occurring without oxygen.

Highlight: Fermentation produces less ATP than aerobic respiration but allows continued glycolysis.

Example: Some organisms can switch between aerobic and anaerobic pathways based on oxygen availability.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Photosynthesis Mechanisms

This section details photosynthetic processes, including light reactions and carbon fixation.

Definition: Photosynthesis converts carbon dioxide and water into oxygen and glucose using light energy.

Highlight: The process occurs in chloroplasts through light-dependent and light-independent reactions.

Vocabulary: Photolysis is the splitting of water molecules using light energy.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Test Review - Energy Coupling

The section reviews key concepts about energy coupling and cellular respiration.

Definition: Energy coupling links energy-releasing processes to energy-requiring reactions.

Example: Cellular respiration powers ATP synthesis through coupled reactions.

Highlight: Muscle cells undergo fermentation when oxygen is limited.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Metabolic Rates and ATP

This portion covers metabolic rates and ATP's role in cellular processes.

Definition: Basal metabolic rate (BMR) relates inversely to body mass.

Example: Hummingbirds have high caloric requirements due to fast metabolism.

Highlight: ATP's high energy comes from phosphate group repulsion.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

View

Energy Makes Change Possible

This page introduces fundamental concepts of energy in biological systems. It explains how energy transformations drive metabolic processes and the critical roles of ATP and enzymes.

Definition: ATP (adenosine triphosphate) is a high-energy molecule that can make non-spontaneous reactions occur by coupling its exergonic hydrolysis to endergonic processes.

The page details the structure of ATP at the molecular level, showing its adenine, ribose, and triphosphate components. It also illustrates the process of ATP hydrolysis, which releases energy for cellular work.

Highlight: Energy coupling is a key concept, where the exergonic hydrolysis of ATP is linked to power endergonic processes like active transport and motor protein function.

The difference between spontaneous (exergonic) and non-spontaneous (endergonic) reactions is explained using energy diagrams. These diagrams demonstrate how the free energy changes (ΔG) determine the direction of reactions.

Example: Cellular respiration is presented as an exergonic process that can be coupled to endergonic reactions, effectively driving non-spontaneous processes in the cell.

The page concludes by discussing phosphorylation, where ATP transfers a phosphate group to reactants, raising their energy level and potentially making endergonic reactions exergonic.

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How Your Body Uses ATP to Stay Active and Healthy

user profile picture

Kristen Song

@kristensong_jhzj

·

6 Followers

Follow

Cellular metabolism and energy transformation processes in living organisms form the foundation of life. ATP hydrolysis energy coupling cellular respiration drives essential biological functions while enzyme role in spontaneous and non-spontaneous reactions ensures efficient metabolic control.

• Metabolic pathways involve complex series of chemical reactions that convert energy between different forms
• Enzymes play crucial roles in catalyzing both spontaneous and non-spontaneous reactions
• ATP serves as the universal energy currency in cells through energy coupling
• Cellular respiration and photosynthesis are key processes for energy transformation
Competitive and non-competitive enzyme inhibition in metabolic pathways helps regulate metabolism

2/9/2023

292

 

AP Biology

26

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Enzymes and Metabolic Regulation

This page focuses on the role of enzymes in metabolic pathways and introduces concepts of enzyme regulation and inhibition.

Enzymes are crucial in lowering the activation energy (Ea) of reactions, thereby increasing reaction rates without changing the overall energy change (ΔG) of the reaction. The page illustrates this concept with an energy diagram showing how enzymes reduce the energy barrier.

Vocabulary: Activation energy (Ea) is the energy difference between the reactant state and the transition state, representing the energy barrier that must be overcome for a reaction to proceed.

The document introduces feedback inhibition as a regulatory mechanism in metabolic pathways. This process involves the end product of a pathway inhibiting an earlier enzyme in the same pathway.

Definition: Feedback inhibition is a regulatory mechanism where the final product of a metabolic pathway inhibits one of the earlier enzymes in that pathway, effectively turning off the production when sufficient product has accumulated.

Two types of enzyme inhibition are discussed:

  1. Competitive inhibition: An inhibitor molecule competes with the substrate for the enzyme's active site.
  2. Non-competitive inhibition: The inhibitor binds to an allosteric site, changing the shape of the active site.

Highlight: Competitive and non-competitive enzyme inhibition in metabolic pathways are crucial mechanisms for regulating cellular metabolism and maintaining homeostasis.

The page also touches on the differences between endotherms (mammals and birds) and ectotherms (reptiles and amphibians) in terms of energy use and temperature regulation.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Energy Acquisition and Utilization in Organisms

This page discusses how different organisms obtain and use energy, focusing on the balance between energy acquisition and expenditure.

The document begins by explaining that all organisms need to obtain energy from their environment, either directly from sunlight (producers) or indirectly through consuming other organisms (consumers).

Example: Plants are presented as an example of organisms that typically perform more photosynthesis than cellular respiration during the day, storing excess energy as biomass (starch).

The page outlines various ways organisms use energy:

  1. Growth (cell division through mitosis)
  2. Reproduction (cell division through binary fission or meiosis)
  3. Maintaining homeostasis (active transport, protein synthesis, DNA repair)

Highlight: The balance between energy intake and expenditure is crucial for survival. For instance, losing weight occurs when calorie use exceeds intake, resulting in the breakdown of stored carbohydrates and fats.

The document contrasts endothermy and ectothermy as strategies for regulating body temperature:

  • Endotherms use internal mechanisms like sweating and shivering.
  • Ectotherms rely on external conditions and behavior, such as basking in the sun or seeking shade.

Vocabulary: Endothermy is the ability to regulate body temperature through internal physiological processes, while ectothermy involves using external heat sources and behavioral adaptations for temperature regulation.

The page concludes by discussing energy conservation strategies in organisms, including feedback inhibition of metabolic pathways, regulating gene expression, seasonal reproduction, and entering low metabolic states like hibernation or estivation.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Cellular Respiration Overview

This page provides an introduction to cellular respiration, presenting its overall formula and a basic flow chart of the process.

The general formula for cellular respiration is given as:

Fuel (glucose) + Oxygen + ADP + Pi → CO₂ + H₂O + ATP

Definition: Cellular respiration is the metabolic process by which cells convert the energy stored in nutrients (like glucose) into ATP, the cell's primary energy currency.

The page presents a balanced equation for the complete oxidation of glucose:

C₆H₁₂O₆ + 6O₂ + ADP + Pi → 6CO₂ + 6H₂O + ATP

The document then introduces the initial stage of cellular respiration: glycolysis. This process breaks down glucose into smaller molecules and can occur without oxygen present.

Highlight: Glycolysis is the first step in cellular respiration and can proceed under both aerobic and anaerobic conditions, generating a small amount of ATP.

The role of electron carriers, specifically NAD+ (nicotinamide adenine dinucleotide), is mentioned. NAD+ picks up high-energy electrons, becoming NADH in the process.

Vocabulary: NAD+ (nicotinamide adenine dinucleotide) is an important coenzyme in cellular respiration that acts as an electron carrier, accepting electrons and protons to become NADH.

The page briefly touches on fermentation, which can occur in the absence of oxygen, but does not elaborate on the process.

Example: The transition from NAD+ (empty carrier) to NADH (full carrier) illustrates how electron carriers function in the cellular respiration process.

This overview sets the stage for a more detailed exploration of the cellular respiration pathway in subsequent lessons.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Cellular Respiration Process

This section provides detailed coverage of cellular respiration steps and mechanisms. It includes the complete reaction formula and pathway components.

Definition: Cellular respiration converts glucose and oxygen into CO2, water, and ATP through multiple steps.

Highlight: The process includes glycolysis, Krebs cycle, and electron transport chain.

Vocabulary: NAD+ serves as an electron carrier, converting to NADH when loaded.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Fermentation Pathways

The content explores anaerobic respiration through fermentation, including its mechanisms and cellular implications.

Definition: Fermentation is anaerobic cellular respiration occurring without oxygen.

Highlight: Fermentation produces less ATP than aerobic respiration but allows continued glycolysis.

Example: Some organisms can switch between aerobic and anaerobic pathways based on oxygen availability.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Photosynthesis Mechanisms

This section details photosynthetic processes, including light reactions and carbon fixation.

Definition: Photosynthesis converts carbon dioxide and water into oxygen and glucose using light energy.

Highlight: The process occurs in chloroplasts through light-dependent and light-independent reactions.

Vocabulary: Photolysis is the splitting of water molecules using light energy.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Test Review - Energy Coupling

The section reviews key concepts about energy coupling and cellular respiration.

Definition: Energy coupling links energy-releasing processes to energy-requiring reactions.

Example: Cellular respiration powers ATP synthesis through coupled reactions.

Highlight: Muscle cells undergo fermentation when oxygen is limited.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Metabolic Rates and ATP

This portion covers metabolic rates and ATP's role in cellular processes.

Definition: Basal metabolic rate (BMR) relates inversely to body mass.

Example: Hummingbirds have high caloric requirements due to fast metabolism.

Highlight: ATP's high energy comes from phosphate group repulsion.

unit 3: Metabolic Pathways
Lesson 31
energy makes change possible
energy cannot be created or destroyed
any energy conversion produces waste

Energy Makes Change Possible

This page introduces fundamental concepts of energy in biological systems. It explains how energy transformations drive metabolic processes and the critical roles of ATP and enzymes.

Definition: ATP (adenosine triphosphate) is a high-energy molecule that can make non-spontaneous reactions occur by coupling its exergonic hydrolysis to endergonic processes.

The page details the structure of ATP at the molecular level, showing its adenine, ribose, and triphosphate components. It also illustrates the process of ATP hydrolysis, which releases energy for cellular work.

Highlight: Energy coupling is a key concept, where the exergonic hydrolysis of ATP is linked to power endergonic processes like active transport and motor protein function.

The difference between spontaneous (exergonic) and non-spontaneous (endergonic) reactions is explained using energy diagrams. These diagrams demonstrate how the free energy changes (ΔG) determine the direction of reactions.

Example: Cellular respiration is presented as an exergonic process that can be coupled to endergonic reactions, effectively driving non-spontaneous processes in the cell.

The page concludes by discussing phosphorylation, where ATP transfers a phosphate group to reactants, raising their energy level and potentially making endergonic reactions exergonic.

Can't find what you're looking for? Explore other subjects.

Knowunity is the # 1 ranked education app in five European countries

Knowunity was a featured story by Apple and has consistently topped the app store charts within the education category in Germany, Italy, Poland, Switzerland and United Kingdom. Join Knowunity today and help millions of students around the world.

Ranked #1 Education App

Download in

Google Play

Download in

App Store

Knowunity is the # 1 ranked education app in five European countries

4.9+

Average App Rating

15 M

Students use Knowunity

#1

In Education App Charts in 12 Countries

950 K+

Students uploaded study notes

Still not sure? Look at what your fellow peers are saying...

iOS User

I love this app so much [...] I recommend Knowunity to everyone!!! I went from a C to an A with it :D

Stefan S, iOS User

The application is very simple and well designed. So far I have found what I was looking for :D

SuSSan, iOS User

Love this App ❤️, I use it basically all the time whenever I'm studying