ATP
ATP is a nucleic acid similar to RNA. It has a ribose sugar attached to the nitrogenous
base adenine. However, instead of the single phosphate group typical of RNA nucleotides,
ATP has three phosphate groups. Each of the ATP phosphate groups carries a negative charge.
In order to hold the three negative charges in such proximity, the bonds holding the
phosphate groups have to be quite powerful. If one or two of the bonds are broken and
the additional phosphates are freed, the energy stored in the bonds is released and can
be used to fuel other chemical reactions. When the cell needs energy, it removes phosphates
from ATP by hydrolysis, creating energy and either adenosine diphosphate (ADP),
which has two phosphates, or adenosine monophosphate (AMP), which has one phosphate.
Respiration is the process of making ATP rather than breaking it down. To make ATP,
the cell burns glucose and adds new phosphate groups to AMP or ADP, creating new power
molecules.
There are actually two general types of respiration, aerobic and anaerobic.
Aerobic respiration occurs in the presence of oxygen, while anaerobic respiration does
not use oxygen. Both types of cell respiration begin with the process of glycolysis,
after which the two diverge. We’ll first discuss aerobic respiration and then move
to anaerobic.
Aerobic Cell Respiration
Aerobic respiration is more efficient and more complicated than anaerobic respiration.
Aerobic respiration uses oxygen and glucose to produce carbon dioxide, water, and ATP.
More precisely, this process involves six oxygen molecules for every sugar molecule:
6O
2 + C
6H
12O
6
6CO
2+ 6H
2O + ATP energy
This general equation for aerobic respiration (which you should know for the test) is
actually the product of three separate stages: glycolysis, the Krebs cycle, and the electron
transport chain. Typically, the SAT II Biology only asks questions about the starting and
ending products of each stage and the location where each takes place. Understanding the internal
details of stages will help you remember these key facts and prepare you in case the testers throw
in a more difficult question,but the details of all the complex reactions will probably not be
tested by the SAT II.
Glycolysis
Glycolysis is the first stage of aerobic (and anaerobic) respiration. It takes place in
the cytoplasm of the cell. In glycolysis (“glucose breaking”), ATP is used to split glucose
molecules into a three-carbon compound called pyruvate. This splitting produces energy that
is stored in ATP and a molecule called NADH. The chemical formula for glycolysis is:
C
6H
12O
6 + 2ATP + 2NAD
+2pyruvate+ 4ATP + 2NADH
As the formula indicates, the cell must invest 2 ATP molecules in order to get
glycolysis going. But by the time glycolysis is complete, the cell has produced 4
new ATP, creating a net gain of 2 ATP. The 2 NADH molecules travel to the mitochondria,
where, in the next two stages of aerobic respiration, the energy stored in them is converted to ATP.
The most important things to remember about glycolysis are:
- Glycolysis is part of both aerobic and anaerobic respiration.
- Glycolysis splits glucose, a six-carbon compound, into two pyruvate molecules,each of which has three carbons.
- In glycolysis, a 2 ATP investment results in a 4 ATP payoff.
- Unlike the rest of aerobic respiration, which takes place in the mitochondria, glycolysis takes place in the cytoplasm of the cell.
- Unlike the rest of aerobic respiration, glycolysis does not require oxygen.
The Krebs Cycle
After glycolysis, the pyruvate sugars are transported to the mitochondria.
During this transport, the three-carbon pyruvate is converted into the two-carbon
molecule called acetate. The extra carbon from the pyruvate is released as carbon
dioxide, producing another NADH molecule that heads off to the electron transport
chain to help create more ATP. The acetate attaches to a coenzyme called coenzyme
A to form the compound acetyl-CoA. The acetyl-CoA then enters the Krebs cycle. The
Krebs cycle is called a cycle because one of the molecules it starts with, the
four-carbon oxaloacetate, is regenerated by the end of the cycle to start the cycle
over again.
The Krebs cycle begins when acetyl-CoA and oxaloacetate interact to form the six-carbon
compound citric acid. (The Krebs cycle is also sometimes called the citric acid cycle.)
This citric acid molecule then undergoes a series of eight chemical reactions that strip
carbons to produce a new oxaloacetate molecule. The extra carbon atoms are expelled as CO2
(the Krebs cycle is the source of the carbon dioxide you exhale). In the process of breaking
up citric acid, energy is produced. It is stored in ATP, NADH, and FADH2. The NADH and FADH2
proceed on to the electron transport chain.
The entire Krebs cycle is shown in the figure below. For the SAT II Biology, you
don’t have to know the intricacies of this figure, but you should be able to recognize
that it shows the Krebs cycle.
It is also important to remember that each glucose molecule that enters glycolysis
is split into two pyruvate molecules, which are then converted into the acetyl-CoA that
moves through the Krebs cycle. This means that for every glucose molecule that enters
glycolysis, the Krebs cycle runs twice. Therefore, for one glucose molecule running
through aerobic cell respiration, the equation for the Krebs cycle is:
2acetyl-CoA + 2oxaloacetate
4CO
2 + 6NADH + 2FADH
2 + 2ATP + 2oxaloacetate
For the SAT II Biology, the most important things to remember about the Krebs cycle are:
- The Krebs cycle results in 2 ATP molecules for each glucose molecule run through glycolysis.
- The Krebs cycle sends energy-laden NADH and FADH2 molecules on to the next step in respiration,
the electron transport chain. It does not export carbon molecules for further processing.
- The Krebs cycle takes place in the mitochondrial matrix, the innermost compartment of the mitochondria.
- Though the Krebs cycle does not directly require oxygen, it can only take place when oxygen is present because it relies on by-products from the electron
transport chain, which requires oxygen. The Krebs cycle is therefore an aerobic process.
The Electron Transport Chain
A great deal of energy is stored in the NADH and FADH2 molecules formed in glycolysis
and the Krebs cycle. This energy is converted to ATP in the final phase of respiration,
the electron transport chain:
10NADH + 2FADH
234ATP
The electron transport chain consists of a set of three protein pumps embedded in the inner membrane
of the mitochondria. FADH2 and NADH are used to power these pumps. Using the energy in NADH and FADH2,
these pumps move positive hydrogen ions (H+) from the mitochondrial matrix to the intermembrane space.
This creates a concentration gradient over the membrane.
In a process called oxidative phosphorylation, H+ ions flow back into the matrix through
a membrane protein called an ATP synthase. This channel is the opposite of the standard membrane
pumps that burns ATP to transport molecules against their concentration gradient: ATP synthase
uses the natural movement of ions along their concentration gradient to make ATP. All told, the
flow of ions through this channel produces 34 ATP molecules. The waste products from the powering
of the electron transport chain protein pumps combine with oxygen to produce water molecules. By
accepting these waste products, oxygen frees NAD+ and FAD to play their roles in the Krebs cycle
and the electron transport chain. Without oxygen, these vital energy carrier molecules would not
perform their roles and the processes of aerobic respiration could not occur.
For the SAT II Biology, the most important things to remember about the electron transport
chain and oxidative phosphorylation are:
- Four ATP molecules are produced by glycolysis and the Krebs cycle combined.
The electron transport chain produces 34 ATP.
- The electron transport chain occurs across the inner membrane of the mitochondria.
- The electron transport chain requires oxygen.
Anaerobic Respiration
Aerobic respiration requires oxygen. However, some organisms live in places where
oxygen is not always present. Similarly, under extreme exertion, muscle cells may run
out of oxygen.Anaerobic respiration is a form of respiration that can function without oxygen.
In the absence of oxygen, organisms continue to carry out glycolysis, since
glycolysis does not use oxygen in its chemical process. But glycolysis does
require NAD+. In aerobic respiration, the electron transport
chain turns NADH back to NAD+ with
the aid of oxygen, thereby averting any NAD+
shortage and allowing glycolysis to take place. In anaerobic respiration, cells
must find another way to turn NADH back to NAD+
.
This “other way” is called fermentation. Fermentation’s goal is not to produce additional
energy, but merely to replenish NAD+supplies so that glycolysis can continue churning
out its slow but steady stream of ATP. Because pyruvates are not needed in anaerobic respiration,
fermentation uses them to help regenerate NAD+.While employing the pyruvates in this way
does allow glycolysis to continue, it also results in the loss of the considerable energy contained
in the pyruvate sugars.
There are two principle forms of fermentation, lactic acid fermentation and alcoholic
fermentation. For the here, remember that no matter what kind of fermentation occurs,
anaerobic respiration only produces 2 net ATP in glycolysis.
Lactic Acid Fermentation
In lactic acid fermentation, pyruvate is converted to a three-carbon compound called lactic acid:
pyruvate + NADH
lactic acid + NAD+
In this reaction, the hydrogen from the NADH molecule is transferred to the pyruvate molecule.
Lactic acid fermentation is common in fungi and bacteria. Lactic acid fermentation also takes place
in human muscle cells when strenuous exercise causes temporary oxygen shortages. Since lactic
acid is a toxic substance, its buildup in the muscles produces fatigue and soreness.
Alcoholic Fermentation
Another route to NAD+ produces alcohol (ethanol) as a by-product:
pyruvate + NADH
ethyl alcohol + NAD+ + CO2
Alcoholic fermentation is the source of ethyl alcohol present in wines and liquors.
It also accounts for the bubbles in bread. When yeast in bread dough runs out of oxygen,
it goes through alcoholic fermentation, producing carbon dioxide. These carbon dioxide
bubbles create spaces in the dough and cause it to rise.Like lactic acid, the ethanol
produced by alcoholic fermentation is toxic. When ethanol levels rise to about 12 percent,
the yeast dies.
Next to display next topic in the chapter.
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