C3 - Cellular Respiration (Updated 2024) PDF

Summary

This document describes cellular respiration, an essential biological process that releases energy from glucose. It explains the stages of aerobic respiration, including glycolysis, the Krebs cycle, and the electron transport chain. The document also briefly discusses anaerobic respiration and fermentation.

Full Transcript

C3 - Cellular
Respiration
I can…
Explain, in general terms, how glucose is oxidized during glycolysis and
the Krebs cycle to produce reducing power in the form of NADH and
FADH
Explain how chemiosmosis converts the reducing power of NADH and
FADH to store chemical potential energy in the form of ATP
Describe where in the mitochondria these processes occur
Distinguish between aerobic and anaerobic respiration and fermentation
Summarize and explain the role of ATP in cellular metabolism
Cellular Respiration
Recall: Cellular respiration is the process where plants and animals
break down glucose to release energy
The chemical equation for cellular respiration is:

C6H12O6(s) + 6 O2(g) → 6 CO2(g) + 6 H2O(l) + energy
Cellular Respiration
Cellular respiration takes place in the mitochondria
Releases the energy of glucose molecules
Glucose is oxidized to CO2 while releasing energy and
water
Photosynthesis & Cellular Respiration - Complementary Processes

Photosynthesis Cellular Respiration
Needs light energy Produces energy
Needs water Produces water
Produces glucose Needs glucose
Occurs in the chloroplast Occurs in the mitochondria
Releasing Stored Energy
Cellular respiration uses glucose to synthesize ATP, a form of energy that can be
used by cells
It can take place either with or without oxygen:
○ Aerobic respiration: Carried out by organisms that live in oxic (oxygen
containing) environments
Ex. Fungi, bacteria, plants
○ Anaerobic respiration: Carried out by organisms that live in anoxic
(non-oxygen containing) environments
Ex. Deep ocean producers, nitrogen-fixing bacteria
Fermentation: Modified form of anaerobic respiration
○ Ex. Yeast, bacteria that causes milk to sour
Aerobic vs. Anaerobic
Aerobic Respiration Anaerobic Respiration

Requires oxygen? Yes No

Energy yield High (36 ATP) Low (2 ATP)

Products CO2 and H2O Animals: Lactic acid
Yeast: Ethanol and CO2

Location Cytoplasm and mitochondria Cytoplasm

Stages 1. Glycolysis 1. Glycolysis
2. Kreb’s Cycle 2. Fermentation
3. Electron Transport
System
Glucose
All cells use energy from ATP molecules to to meet their
energy needs
ATP has a relatively low amount of energy per molecule
Carbohydrates are the most usable source of energy
Molecules with a higher energy content are useful
because they provide:
○ Long-term storage of chemical energy
○ Bulk transportation of chemical energy
Glucose: Our “blood sugar’
○ High energy content
○ Relatively small
○ Highly soluble
○ Ideal for transportation within cells
Review
1. What are the characteristics of glucose that make it well-suited as an
energy supply molecule within our bodies?

2. Why is cellular respiration necessary?

3. What are the 3 stages of aerobic respiration?
Aerobic Cellular
Respiration
Aerobic Cellular Respiration
Three main stages:

1. Glycolysis
2. Prep and Kreb’s Cycle
3. Electron Transport Chain
Aerobic Cellular Respiration
An oxidation reaction in which a transfer of electrons occurs from high
energy molecules - glucose and oxygen
Most of the energy in plants, animals, and most eukaryotic (organisms
with a membrane-bound nucleus) cells is produced in process
Process of cellular respiration starts with glycolysis (an anaerobic
reaction in cytoplasm)
1. Glycolysis
Glycolysis is the first step of aerobic and anaerobic cellular respiration
The main purpose of glycolysis is to split glucose into two molecules of
pyruvate through a series of reactions
Doesn’t require oxygen
Occurs outside the mitochondria in the cytoplasm
Produces 4 ATP while consuming 2 ATP - producing a net outcome of 2
ATP
Produces 2 reduced NADH molecules
1. Glycolysis
1. 2 molecules of ATP are required to initiate the reactions. This causes
glucose to be broken down into two molecules of G3P.
2. G3P then reduces NAD+ to NADH. NADH will later be used for the Kreb’s
cycle. Reduction of NAD+ also leads to the generation of 2 molecules of
ATP by each G3P (so 4 ATP produced in total, resulting in a net gain of 2
ATP throughout the entire process of glycolysis).
3. Via the process of reduction described above, G3P becomes pyruvate, a
high energy three-carbon compound which is required for the next stage
of cellular respiration (Kreb’s cycle).
1. Glycolysis
Fate of Pyruvate
There are 2 possible processes that pyruvate can proceed with, depending on
the availability of oxygen:

1. IF AVAILABLE: Pyruvate is transported from cytoplasm into the
mitochondria (aerobic cellular respiration)
2. IF NOT AVAILABLE: Pyruvate will proceed through fermentation process
(anaerobic cellular respiration)
2. Prep
Before pyruvate can enter the Krebs Cycle, it must lose one carbon atom in the
form of carbon dioxide
The remaining two carbon atoms then bond to a molecule called Coenzyme A (CoA)
to become Acetyl Coenzyme A (acetyl CoA).
This reaction also causes another molecule of NAD+ to be reduced to NADH.
Acetyl CoA then enters the mitochondria to initiate the Krebs Cycle
2. Krebs Cycle (in Mitochondria)
Discovered by Sir Hans Adolf Krebs (1900-1981), a
German biochemist
Won Nobel Prize in 1953 in Physiology or Medicine
for the discovery in living organisms of the series of
chemical reactions known as the tricarboxylic acid
cycle, otherwise known as the Kreb’s Cycle
2. Krebs Cycle (in Mitochondria)
The main purpose of the Kreb’s Cycle
is to produce even more high-energy
compounds (NADH & FADH2) for use
in stage 3
Once acetyl CoA enters the
mitochondria, it undergoes a series of
reactions to generate:
○ 3 molecules of NADH from NAD+
○ 1 molecule of ATP from ADP
○ 1 molecule of FADH2 from FAD
○ Multiply all of the above by two
for an entire glucose molecule
CO2 is also released as a by-product
Krebs Cycle
3. Electron Transport Chain
The majority of ATP is produced by the electron transport chain
This takes place across the inner membrane of the mitochondria, and
involves the passing of high-energy electrons (NADH & FADH 2) from
carrier to carrier
3. Electron Transport Chain
As electrons are passed down the chain,
energy is released - this energy is used to
pump hydrogen ions across the membrane
from the matrix to the intermembrane space
The building concentration gradient (high
concentration of hydrogen in the
intermembrane space, low concentration in
the matrix) forces hydrogen ions through
membrane-embedded protein ATP synthase,
generating ATP via the reduction of ADP
Oxygen is the final electron acceptor in the
chain, it accepts both electrons and hydrogen
ions, resulting in a molecule of water which
will be released as a by-product
Summary of Aerobic Cellular Respiration
Aerobic cellular respiration involves 3 stages:
1. Glycolysis
2. Prep and Krebs Cycle
3. Electron Transport Chain
Pyruvate oxidation occurs in the mitochondria
○ 2 NADH and 2 CO2 are formed
Krebs Cycle occurs in the mitochondrial matrix
ETC in the inner mitochondrial membrane transports electrons
○ Produces an electrochemical gradient
Chemiosmosis: Protons (H+) move through ATP complexes embedded in
membrane, free energy released, causes ATP synthesis
Oxygen finally accepts electrons from the ETC
No oxygen? No aerobic cellular respiration!
Summary
Anaerobic
Respiration
Anaerobic Respiration
When oxygen isn’t available (anoxic conditions), the final electron acceptor
is a different chemical
○ Isn’t as efficient as aerobic (produces less ATP)
Organisms that live in these types of environments use inorganic
chemicals - sulfate, nitrate, and CO2 as acceptors
Fermentation
Fermentation is a metabolic pathway to produce ATP when organisms
lack oxygen
○ Pathway only produces ATP during glycolysis (less efficient aerobic
respiration)
Many single-celled organisms carry out fermentation
2 main types:
○ Lactate fermentation
○ Ethanol fermentation
Lactate Fermentation
Cells that are temporarily without oxygen carry out
lactate fermentation
○ Process occurs when energy demands exceed
oxygen supply - creates an oxygen deficit
Cells convert pyruvate molecules formed during
glycolysis to lactate/lactic acid molecule
○ Uses NADH as an energy source
○ Lactate is then started
When oxygen content increases - lactate is converted
to pyruvate which continues in Krebs cycle in aerobic
pathway
This is also the form of fermentation our muscles use
when they have limited access to oxygen; the buildup
of lactic acid is what causes muscle cramps
Ethanol Fermentation
Some organisms can function both aerobically
and anaerobically
When functioning anaerobically, ethanol
fertilization is carried out
Involves 2 steps:
1. After glycolysis produces pyruvate,
pyruvate is converted into 2-carbon
compound by release of CO2
2. 2-carbon molecule is then reduced by
NADH to form ethanol
The by-product of this form of fermentation is
alcohol, this process is used to manufacture
products such as wine and beer.