Cell Respiration
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Overview of Cellular Respiration
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Welcome class! Today, we're starting our deep dive into cellular respiration. Can anyone tell me what cellular respiration is?
Isn't it how cells convert sugar into energy?
Exactly! It's the process by which cells convert biochemical energy from nutrients into ATP. There are two main types: aerobic respiration, which requires oxygen, and anaerobic respiration, which does not.
Whatβs the energy currency you mentioned?
That's ATP, or adenosine triphosphate. Itβs what our cells use for energy. Can anyone think of a simple analogy for how cellular respiration works?
It's like a power plant transforming fuel into usable electricity!
Great analogy! Just as a power plant uses fuel to generate electricity, our cells use glucose and oxygen to produce ATP. Letβs move on to glycolysis!
Glycolysis
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So, glycolysis takes place in the cytosol. Can anyone explain what glycolysis does?
It breaks down glucose into pyruvate, right?
Correct! And it produces a net gain of 2 ATP and 2 NADH. What is the first enzyme involved in glycolysis that traps glucose inside the cell?
That's hexokinase, isn't it?
Yes! Hexokinase phosphorylates glucose to glucose-6-phosphate. Itβs critical for keeping glucose inside the cell. Remember, processing glucose creates energy, much like preparing materials for use in production.
Does glycolysis only create ATP?
Good question! Glycolysis also produces NADH, which later can contribute to energy production in the electron transport chain. Let's summarize this session: glycolysis breaks glucose down, yields 2 ATP and 2 NADH, and is catalyzed by several important enzymes.
Citric Acid Cycle
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Now, letβs discuss the Citric Acid Cycle. Who can describe where this cycle happens and what it produces?
It happens in the mitochondrial matrix and produces NADH and FADHβ, right?
Precisely! Each acetyl-CoA that enters the cycle yields 3 NADH, 1 FADHβ, and 1 ATP or GTP per turn. Can anyone tell me the importance of this cycle in the overall process?
It keeps generating electron carriers that feed into the electron transport chain?
Exactly! The NADH and FADHβ produced here are vital for the next step. Also, what regulates this cycle?
I think enzymes like isocitrate dehydrogenase have regulatory roles?
Thatβs correct! Specific enzymes regulate the cycle based on energy status. Let's wrap up this session: the Citric Acid Cycle generates key electron carriers and ATP while being regulated by important enzymes.
Electron Transport Chain and Oxidative Phosphorylation
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Now weβre at the exciting part: the Electron Transport Chain! Who can summarize how that works?
It uses the NADH and FADHβ to transport electrons through a series of proteins, eventually leading to the production of ATP!
Great summary! As electrons pass through, protons are pumped across the mitochondrial membrane, creating a gradient. Can anyone recall how ATP is synthesized?
By ATP synthase as protons flow back across the membrane, right?
Exactly! This processβchemiosmosisβis responsible for a significant portion of ATP produced, typically around 30-32 ATP per glucose molecule. Letβs summarize: the ETC uses NADH and FADHβ to produce ATP via a proton gradient.
Anaerobic Respiration and Regulation
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In instances where oxygen is limited, how do cells generate energy?
They switch to anaerobic respiration or fermentation.
Correct! Fermentation regenerates NADβΊ but only yields 2 ATP, which is not as efficient as aerobic methods. Now, what factors regulate cellular respiration?
I remember that ATP levels and key enzymesβ activity are significant regulators.
Spot on! High levels of ATP will inhibit certain enzymes, slowing down the metabolism process. To conclude, we learned about anaerobic processes and the regulation of cellular respiration to match energy demands.
Introduction & Overview
Read summaries of the section's main ideas at different levels of detail.
Quick Overview
Standard
Cellular respiration involves the conversion of biochemical energy from nutrients into ATP, primarily in the presence of oxygen (aerobic respiration) or, when oxygen is absent, through anaerobic processes. This section outlines glycolysis, mitochondrial oxidation steps, the citric acid cycle, anaerobic respiration, and regulation of cellular respiration.
Detailed
Detailed Summary of Cellular Respiration
Cellular respiration is a critical biological process through which cells extract energy from glucose and convert it into adenosine triphosphate (ATP), the energy currency of the cell. This can occur through
aerobic respiration, which does not require oxygen, or aerobic respiration, which utilizes oxygen as the terminal electron acceptor.
1. Overview of Cellular Respiration
Cellular respiration encompasses a series of metabolic reactions that capture energy from organic molecules.
2. Aerobic Respiration Pathway
The pathway includes several key stages:
- Glycolysis happens in the cytosol, yielding pyruvate and a net gain of 2 ATP and 2 NADH. Important regulatory steps include the actions of enzymes like PFK-1.
- Link Reaction: Here, pyruvate enters the mitochondria and is converted to acetyl-CoA, generating NADH and releasing COβ.
- Citric Acid Cycle (Krebs Cycle): Acetyl-CoA enters the cycle, and through a series of enzyme-catalyzed steps, it generates NADH, FADHβ, GTP (or ATP), and releases COβ, with several key regulatory enzymes managing the process.
- Electron Transport Chain (ETC) and Oxidative Phosphorylation: Occurring in the inner mitochondrial membrane, this stage involves the transfer of electrons from NADH and FADHβ through protein complexes leading to ATP production via ATP synthase, driven by a proton gradient. The expected ATP yield is approximately 30-32 ATP per glucose molecule.
3. Anaerobic Respiration and Fermentation: In the absence of oxygen, cells rely on fermentation processes to regenerate NADβΊ, enabling glycolysis to continue albeit with a significantly lower ATP yield.
4. Regulation of Cellular Respiration: Cellular respiration is tightly regulated under varying conditions based on ATP levels and substrate availability, accommodating the energy needs of the cell.
Audio Book
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Overview of Cellular Respiration
Chapter 1 of 7
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Chapter Content
Cellular respiration is the process by which cells extract chemical energy (from organic molecules like glucose) and convert it into adenosine triphosphate (ATP), the cellβs energy currency. This process can be aerobic (using oxygen as the terminal electron acceptor) or anaerobic (using alternative electron acceptors or substrate-level phosphorylation).
Detailed Explanation
Cellular respiration is essentially how our cells convert food into energy. Think of food like fuel that your body burns to get energy. This process can occur in two main ways: aerobic respiration, which requires oxygen, and anaerobic respiration, which occurs without oxygen. When you eat, your body breaks down carbohydrates (like glucose), and through cellular respiration, it produces ATP, the energy currency of the cell, similar to how cash is used to pay for goods. Without ATP, cells can't perform the necessary functions to keep you alive.
Examples & Analogies
Imagine you have a car that can run on two types of fuel: gasoline (aerobic respiration) and battery power (anaerobic respiration). Gasoline is more efficient and allows the car to travel long distances, just like aerobic respiration produces more ATP with oxygen. On the other hand, when you're in a situation where you can't refill your gas tank (like being in a power outage), the car can still run for a short time on battery power, similar to how some cells operate with anaerobic respiration when oxygen is low.
Aerobic Respiration Pathway
Chapter 2 of 7
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Chapter Content
- Glycolysis (Cytosol)
- Glucose Uptake and Activation:
- Hexokinase/Glucokinase (muscle/liver): Phosphorylates glucose β glucose-6-phosphate (G6P), trapping it inside the cell. Consumes 1 ATP.
- Phosphoglucose Isomerase: Converts G6P β fructose-6-phosphate (F6P).
- Phosphofructokinase-1 (PFK-1): Phosphorylates F6P β fructose-1,6-bisphosphate (FBP). Major regulatory step (activated by AMP, ADP, fructose-2,6-bisphosphate; inhibited by ATP, citrate). Consumes 1 ATP.
- Cleavage and Oxidation:
- Aldolase: Splits FBP into glyceraldehyde-3-phosphate (G3P) and dihydroxyacetone phosphate (DHAP).
- Triose Phosphate Isomerase: Reversibly converts DHAP β G3P. Only G3P continues.
- Glyceraldehyde-3-Phosphate Dehydrogenase (GAPDH): Oxidizes G3P β 1,3-bisphosphoglycerate; reduces NADβΊ β NADH + HβΊ.
- ATP Generation (Substrate-Level Phosphorylation):
- Phosphoglycerate Kinase (PGK): Transfers phosphate from 1,3-bisphosphoglycerate β ADP β ATP (net gain: 2 ATP per glucose). Produces 3-phosphoglycerate.
- Phosphoglycerate Mutase: Converts 3-phosphoglycerate β 2-phosphoglycerate.
- Enolase: Dehydrates 2-phosphoglycerate β phosphoenolpyruvate (PEP), releasing HβO.
- Pyruvate Kinase: Transfers phosphate from PEP β ADP β ATP (net gain: 2 ATP per glucose), producing pyruvate. Allosteric regulation: activated by fructose-1,6-bisphosphate; inhibited by ATP and alanine.
- Net Glycolysis Yield (per glucose):
- 2 Pyruvate
- 2 NADH (in cytosol)
- 2 ATP (net)
Detailed Explanation
Glycolysis is the first step of cellular respiration and happens in the cytosol of cells. It begins with glucose entering the cell and being modified through a series of reactions, which eventually breaks it down into two molecules of pyruvate, generating a net gain of 2 ATP (energy) and 2 NADH (used in later steps of respiration). This process also involves several enzymes, each playing a crucial role in each step, altering glucose until it's broken down.
Examples & Analogies
Think of glycolysis like preparing a large meal. It starts with getting all your ingredients (glucose) together. You chop, peel, and mix them (the enzymatic reactions) until you finally have two finished dishes (pyruvate). The cooking process is efficient but doesn't yield a lot of foodβsince you only manage to serve a couple of plates (2 ATP), but what you make can still be used for a bigger meal later on.
Mitochondrial Oxidation
Chapter 3 of 7
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Chapter Content
- Pyruvate Transport: Shuttled into mitochondria via the mitochondrial pyruvate carrier (MPC).
- Link Reaction:
- Pyruvate Dehydrogenase Complex (PDC):
- E1 (Pyruvate Dehydrogenase): Decarboxylates pyruvate (Cβ) hydroxyethylβTPP (thiamine pyrophosphate cofactor) + COβ.
- E2 (Dihydrolipoamide Transacetylase): Transfers acetyl group from hydroxyethyl-TPP to lipoamide acetylβdihydrolipoamide. Then CoA binds to liberate acetylβCoA.
- E3 (Dihydrolipoamide Dehydrogenase): Regenerates oxidized lipoamide by transferring electrons to FAD β FADHβ, then to NADβΊ β NADH + HβΊ.
- Pyruvate Dehydrogenase Complex (PDC):
- Regulation:
- Allosteric: NADH, acetylβCoA inhibit; NADβΊ, CoA, ADP activate.
- Covalent: PDC kinase phosphorylates (inactivates) PDC when ATP, NADH, acetylβCoA are high; PDC phosphatase dephosphorylates (activates) PDC when CaΒ²βΊ (in muscle) or insulin (in liver) is present.
Detailed Explanation
After glycolysis, the pyruvate produced enters the mitochondria. Here, it undergoes the Link Reaction where it's converted into acetyl-CoA, which is a crucial molecule for the next step, the Citric Acid Cycle (also known as Krebs Cycle). This conversion releases carbon dioxide (as a waste product) and produces NADH, which carries electrons that will be used later for ATP production. The Pyruvate Dehydrogenase Complex (PDC) is tightly regulated to ensure there are enough resources for energy production.
Examples & Analogies
Think of this Link Reaction like getting your ingredients prepped for a grilling session. You've got your fresh vegetables (pyruvate) from the farmer's market, and before you can grill them (enter the Citric Acid Cycle), you need to marinate them (convert to acetyl-CoA) which adds flavor (energy) and tenderness (electrons for ATP production), and during this process, some excess moisture (COβ) is released.
Citric Acid Cycle
Chapter 4 of 7
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Chapter Content
- Citric Acid Cycle (Krebs Cycle, TCA Cycle) (mitochondrial matrix):
- Eight enzyme-catalyzed steps fully oxidize acetylβCoA to COβ, generating three NADH, one FADHβ, and one GTP (or ATP) per acetylβCoA.
- Key regulatory enzyme: isocitrate dehydrogenase (activated by ADP, inhibited by ATP and NADH), Ξ±βketoglutarate dehydrogenase.
Detailed Explanation
The Citric Acid Cycle continues the process of energy extraction from acetyl-CoA. It takes place in the mitochondria and involves a series of reactions that ultimately break down acetyl-CoA into carbon dioxide while transferring electrons to NADH and FADHβ, which will later be used in the electron transport chain to produce ATP. The cycle also produces GTP or ATP directly as an energy currency.
Examples & Analogies
Imagine this cycle like a factory assembly line where the acetyl-CoA enters the line and gets processed into several byproducts (COβ, NADH, FADHβ). Each part of the process adds energy to the factory's output in a systematic wayβjust like in the factory, energy is accumulated through every stage until it reaches the final product (ATP) at the end.
Electron Transport Chain (ETC) & Oxidative Phosphorylation
Chapter 5 of 7
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Chapter Content
- Electron Transport Chain (ETC) & Oxidative Phosphorylation: (inner mitochondrial membrane)
- Electrons from NADH and FADHβ are transferred through complexes IβIV in the inner mitochondrial membrane. The flow of electrons to oxygen (forming HβO) creates a proton (HβΊ) gradient across the inner membrane.
- ATP Synthase (Complex V) utilizes the proton-motive force to drive synthesis of ATP from ADP + Pi.
- Overall yield per glucose typically ~30β32 ATP (varies depending on shuttle systems and leakiness of the membrane).
Detailed Explanation
The Electron Transport Chain (ETC) is the final stage of cellular respiration where the energy stored in NADH and FADHβ is converted into ATP. In this chain, electrons move through a series of proteins embedded in the inner mitochondrial membrane, releasing energy that pumps protons into the intermembrane space, creating a gradient. This gradient drives the production of ATP as protons flow back through ATP synthase, much like water flowing through a dam generates electricity.
Examples & Analogies
You can think of the ETC like a dam on a river. The water (protons) builds up behind the dam, creating pressure. When the gates of the dam open (when protons flow back through ATP synthase), that pressure is released, and it drives a turbine to generate electricity (ATP). The more water from the river (more protons from NADH and FADHβ) you have building up behind the dam, the more energy you can produce.
Anaerobic Respiration and Fermentation
Chapter 6 of 7
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Chapter Content
- Anaerobic Respiration and Fermentation
- In the absence of oxygen (or in organisms lacking an oxygen-based ETC), cells regenerate NADβΊ from NADH by alternative pathways.
- Lactic Acid Fermentation (e.g., in muscle, some bacteria): Pyruvate + NADH β lactate + NADβΊ, catalyzed by lactate dehydrogenase. Allows glycolysis to continue but yields only 2 ATP per glucose.
- Alcoholic Fermentation (e.g., in yeast):
- Pyruvate Decarboxylase: Pyruvate β acetaldehyde + COβ.
- Alcohol Dehydrogenase: Acetaldehyde + NADH β ethanol + NADβΊ.
Detailed Explanation
When oxygen isn't available, some cells can still generate energy through fermentation. This process regenerates NADβΊ so glycolysis can continue, but it is less efficient than aerobic respiration, only yielding 2 ATP per glucose instead of 30β32. In muscle cells, this results in lactic acid production, which can cause fatigue. Yeast cells perform alcoholic fermentation, producing ethanol and carbon dioxide instead.
Examples & Analogies
Imagine you're in a room running out of oxygen (like in certain intense workouts), so you have to switch to a backup plan. Instead of using efficient power (aerobic process), you run off a small backup battery (fermentation). For muscles, this can feel like muscle fatigue from lactic acid build-up; for yeast, it's like making beer or bread, using sugar to produce COβ and alcohol, which is not as efficient but gets the job done.
Regulation of Cellular Respiration
Chapter 7 of 7
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Chapter Content
- Regulation of Cellular Respiration
- High ATP/Low ADP or NADH Levels: Inhibit key enzymes (phosphofructokinase, pyruvate dehydrogenase, isocitrate dehydrogenase), slowing flux.
- High ADP/AMP, NADβΊ, CaΒ²βΊ (in muscle): Activate PFK, PDH, isocitrate dehydrogenase, enhancing respiration.
- Oxygen Availability: When Oβ is limited, the ETC slows or backs up, NADH accumulates, inhibiting dehydrogenases, reducing aerobic flux, shifting to anaerobic pathways.
Detailed Explanation
Cellular respiration is not a constant process; itβs tightly regulated based on energy demand. When there is a lot of ATP available, it signals that the cell has enough energy and that respiration can slow down. Conversely, when ATP levels drop and ADP increases (like during muscle activity), it signals that the cell needs to ramp up energy production. The availability of oxygen also controls how the process works. If oxygen is scarce, cells might flip to anaerobic processes which produce less energy.
Examples & Analogies
Think of this regulation like a traffic light system. When traffic is heavy (high ATP), the lights turn yellow (process slows down), but as cars start moving again (low ATP, rising ADP), it turns green, allowing more cars to pass (increased energy production). If the lights are out (low oxygen), you might have to drive through a busy intersection slowly or take another route (shift to anaerobic processes) to get to your destination.
Key Concepts
-
Aerobic Respiration: A metabolic process that requires oxygen to convert glucose into ATP.
-
Anaerobic Respiration: A method of ATP generation that occurs without oxygen, producing less energy.
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Glycolysis: The initial metabolic pathway of cellular respiration, converting glucose to pyruvate. This occurs in the cytosol and yields 2 ATP and 2 NADH.
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Citric Acid Cycle: The cycle occurring in the mitochondria yielding key electron carriers while releasing COβ.
-
Electron Transport Chain: A series of protein complexes that create a proton gradient to produce ATP, utilizing electrons from NADH and FADHβ.
Examples & Applications
In muscle cells during intense exertion, when oxygen is limited, lactic acid fermentation occurs, allowing for a quick energy supply but only yielding 2 ATP.
The citric acid cycle entails a sequence of reactions that oxidizes acetyl-CoA, yielding 3 NADH, 1 FADHβ, and 1 GTP/ATP.
Memory Aids
Interactive tools to help you remember key concepts
Rhymes
Glycolysis splits glucose in a dash,
Stories
Imagine a factory that uses sugar as an energy source, and every time it processes a batch, it generates money (ATP) to keep everything running smoothly.
Memory Tools
For the Citric Acid Cycle, remember 'CATS' β Citrate, Isocitrate, Ξ±-Ketoglutarate, Succinyl-CoA, Succinate, Fumarate, Malate, Oxaloacetate.
Acronyms
Use 'GAP' to remember glycolysis
Glucose
ATP
Pyruvate.
Flash Cards
Glossary
- Cellular Respiration
The process by which cells convert glucose and other organic molecules into ATP, either in the presence of oxygen (aerobic) or in its absence (anaerobic).
- ATP (Adenosine Triphosphate)
The main energy currency of the cell, required for many cellular processes.
- Glycolysis
The first stage of cellular respiration that occurs in the cytosol, where glucose is converted into pyruvate.
- Citric Acid Cycle
A series of chemical reactions in the mitochondrial matrix that convert acetyl-CoA into carbon dioxide and provide high-energy electron carriers.
- Electron Transport Chain (ETC)
A series of protein complexes in the mitochondrial inner membrane that transfer electrons from NADH and FADHβ, driving ATP synthesis.
- Anaerobic Respiration
A process by which cells generate ATP without oxygen by using alternative pathways like fermentation.
- NADH
Nicotinamide adenine dinucleotide (reduced form) that acts as an electron carrier in cellular respiration.
- FADHβ
Flavin adenine dinucleotide (reduced form) that serves as an electron carrier in the citric acid cycle.
Reference links
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