5 Steps to a 5 AP Biology PDF 2024 Review

Summary

This document appears to be exam review material for the AP Biology exam, 2024. It introduces key chemical principles, including organic compounds and their roles in living systems. The review material includes study concepts on elements, molecules, and functional groups.

Full Transcript

CHAPTER
5
Chemistry of Life
Exam Weight: 8–11%
IN THIS CHAPTER
Summary: This chapter introduces the chemical principles that are related to under-
standing the AP Biology topics covered throughout the course.

Key Ideas
KEY IDEA ✪ Organic compounds contain essential elements, including carbon, oxygen, hy-
drogen, nitrogen, and phosphorus.
✪ The structure and function of macromolecules (proteins, carbohydrates, lipids,
and nucleic acids) are key to the organization of living systems.
✪ Water and its properties are instrumental in the organization and survival of all
living organisms and systems.
✪ Hydrolysis and dehydration reactions are vital in the formation and cleavage of
bonds between monomer units.

Introduction
What is the name of the test you are studying for? The AP Biology exam. Then why in
tarnation are we starting your review with a chapter titled Chemistry of Life?!?!? Because it
is important that you have an understanding of the key chemical principles before we dive
into the deeper biological material. We will keep it short, don’t worry.

Elements, Compounds, Atoms, and Ions
By definition, matter is anything that has mass and takes up space; an element is defined as
matter in its simplest form; an atom is the smallest form of an element that still displays its

‹ 47
 48  ❯   STEP 4. Review the Knowledge You Need to Score High

particular properties. (Terms boldfaced in text are listed in the Glossary at the end of the book.)
For example, sodium (Na) is an element mentioned often in this book. The element sodium
can exist as an atom of sodium, in which it is a neutral particle containing an equal number
of protons and electrons. It can also exist as an ion, which is an atom that has a positive or
negative charge. Ions such as sodium that take on a positive charge are called cations, and are
composed of more protons than electrons. Ions with a negative charge are called anions, and
are composed of more electrons than protons.
Elements can be combined to form molecules, for example, an oxygen molecule (O2) or
a hydrogen molecule (H2). Molecules that are composed of more than one type of element
are called compounds, for example H2O. The two major types of compounds you need to
be familiar with are organic and inorganic compounds. Organic compounds contain carbon
and usually hydrogen; inorganic compounds do not. Some of you are probably skeptical, at
this point, as to whether any of what we have said thus far matters for this exam. Bear with
me because it does. You will deal with many important organic compounds later on in this
John (11th book, including carbohydrates, proteins, lipids, and nucleic acids.
grade): Before moving onto the next section, where we discuss these particular organic compounds
“My teacher in more detail, we would like to cover a topic that many find confusing and therefore ignore
wanted me to in preparing for this exam. This is the subject of functional groups. These poorly understood
know these groups are responsible for the chemical properties of organic compounds. They should not
structures... she intimidate you, nor should you spend a million hours trying to memorize them in full detail.
was right!” The following is a list of the functional groups you should study for this exam:

1. Amino group. An amino group has the following formula:

SYI-1 H
Living systems are R N
organized in a hier- H
archy of structural
levels that interact. The symbol R stands for “rest of the compound” to which this NH2 group is attached.
One example of a compound containing an amino group is an amino acid. Compounds
containing amino groups are generally referred to as amines. Amino groups act as bases
and can pick up protons from acids.
2. Carbonyl group. This group contains two structures:

R
O
C O R C
H
R
ketone aldehyde
If the C=O is at the end of a chain, it is an aldehyde. Otherwise, it is a ketone. (Note:
in aldehydes, there is an H at the end; there is no H in the word ketone.) A carbonyl
group makes a compound hydrophilic and polar. Hydrophilic means water-loving,
reacting well with water. A polar molecule is one that has an un­equal distribution of
charge, which creates a positive side and a negative side to the molecule.
3. Carboxyl group. This group has the following formula:
R O
C
OH
 Chemistry of Life   ❮  49

A carboxyl group is a carbonyl group that has a hydroxide in one of the R spots and a
carbon chain in the other. This functional group shows up along with amino groups
in amino acids. Carboxyl groups act as acids because they are able to donate protons
to basic compounds. Compounds containing carboxyl groups are known as carboxylic
acids.
4. Hydroxyl group. This group has the simplest formula of the bunch:
R — OH
A hydroxyl group is present in compounds known as alcohols. Like carbonyl groups,
hydroxyl groups are polar and hydrophilic.
5. Phosphate group. This group has the following formula:
O

R O P O

O–
Phosphate groups are vital components of compounds that serve as cellular energy sources:
ATP, ADP, and GTP. Like carboxyl groups, phosphate groups are acidic molecules.
6. Sulfhydryl group. This group also has a simple formula:
R — SH
This functional group does not show up much on the exam, but you should recognize
it when it does. This group is present in the amino acids methionine and cysteine and
assists in structure stabilization in many proteins.

Water
Water is an inorganic compound consisting of one oxygen molecule covalently bonded to
two hydrogen bonds. The electrons shared between the hydrogen and oxygen molecules are
closer to the oxygen molecule due to its electronegativity, resulting in the oxygen molecule
being negatively charged and the hydrogen molecule being positively charged. Water mol-
ecules are polar because they have a positive and a negative side. Nonpolar molecules have
a neutral charge due to equal sharing of electrons.
Hydrogen bonding is the attraction between a positively charged hydrogen atom and
any other electronegative atom, such as oxygen. These bonds may form between atoms
within the same molecule or between two separate molecules. Water is a molecule that
contains slightly positive charged hydrogens and slightly negative oxygen molecules. This
allows water molecules to form up to two hydrogen bonds with other water molecules,
leading to a variety of properties unique to water (Figure 5.1).
50  ❯   STEP 4. Review the Knowledge You Need to Score High

Properties of Water

Cohesion  Water molecules linking together due to hydrogen bonds
 Surface tension: The surface of water is difficult to break or
stretch.
Adhesion  A water molecule is attracted to another substance due to
KEY IDEA
hydrogen bonds.
 The adhesion of water to plant cell walls by hydrogen bonds
help counter the pull of gravity in plants.
Evaporative cooling  The surface of an object becomes cooler during evaporation
as a result of water absorbing energy in the form of heat.
 Evaporation of sweat from the skin of humans lowers body
temperature.
Surface tension  Surface tension allows water to be resistant to external forces,
due to the cohesive nature of the water molecules to one
another instead of to the surrounding molecules in the air.
Universal solvent  Water dissolves more substances than any other liquid on
Earth.
 In life, wherever water moves, it takes with it the substances
dissolved in it.

Figure 5.1 Structure of a hydrogen bond. a. Hydrogen bond between two water
molecules. b. Hydrogen bond between an organic molecule (n-butanol) and water. H in
n-butanol forms a hydrogen bond with oxygen in water. This kind of hydrogen bond is
possible any time H is bound to a more electronegative atom. (Reproduced with permis-
sion from Raven P, Johnson G, Mason K, Losos J, Duncan T; Biology, 12th ed. New York:
McGraw Hill; 2020)
 Chemistry of Life   ❮  51

Macromolecules
Monomers and Polymers
Macromolecules are made up of single units called monomers that are joined together via
covalent bonds to form large polymers, such as carbohydrates, nucleic acids, and proteins.
Due to their large size, lipids are also classified as macromolecules even though they lack
the repeating monomer subunits seen in the other molecules.
Macromolecules are assembled via dehydration synthesis, a reaction that forms a cova-
lent bond between two monomer units while releasing a water molecule in the process.
Hydrolysis is the process by which the covalent bonds between monomer units are
broken by the addition of water (Figure 5.2).

Figure 5.2 Making and breaking macromolecules. a. Biological macromolecules are
polymers formed by linking monomers together through dehydration reactions. This
process releases a water molecule for every bond formed. b. Breaking the bond between
subunits involves hydrolysis, which reverses the loss of a water molecule by dehydration.
(Reproduced with permission from Raven P, Johnson G, Mason K, Losos J, Duncan T;
Biology, 12th ed. New York: McGraw Hill; 2020)

ENE-1 Lipids
The highly com- Lipids are organic compounds used by cells as long-term energy stores or building blocks.
plex organization Lipids are hydrophobic and insoluble in water because they contain a hydrocarbon tail of
of living systems CH2S that is nonpolar and repellant to water. The most important lipids are fats, oils,
requires constant steroids, and phospholipids.
input of energy and
Fats, which are lipids made by combining glycerol and three fatty acids (Figure 5.3), are
the exchange of
macromolecules used as long-term energy stores in cells. They are not as easily metabolized as carbohydrates, yet

SYI-1
Living systems are H H H H H H
organized in a hier-
archy of structural H C OH O C C C C C C H
levels that interact
H C OH HO H H H H H
H C OH Fatty acid
IST-1
Heritable informa-
H
tion provides for the Glycerol
continuity of life

Figure 5.3 Structure of glycerol and fatty acids.
52  ❯   STEP 4. Review the Knowledge You Need to Score High

H H H H H
H
O C C C C C C H

H C O H H H H H

H H H H H

O C C C C C C H

H C O H H H H H

H H H H H

O C C C C C C H

H C O H H H H H

H

Figure 5.4 Fat structure (glycerol plus three fatty acids).

they are a more effective means of storage; for instance, one gram of fat provides two times
the energy of one gram of carbohydrate. Fats can be saturated or unsaturated. Saturated fat
molecules contain no double bonds. Unsaturated fats contain one (mono-) or more (poly-)
double bonds, which means that they contain fewer hydrogen molecules per carbon than
do saturated fats. Saturated fats are the bad guys and are associated with heart disease and
atherosclerosis. Most of the fat found in animals is saturated, whereas plants tend to contain
unsaturated fats. Fat is formed when three fatty-acid molecules connect to the OH groups of
the glycerol molecule. These connecting bonds are formed by dehydration synthesis reaction
(Figure 5.4).
Steroids are lipids composed of four carbon rings that look like chicken-wire fencing
in pictorial representations. One example of a steroid is cholesterol, an important structural
component of cell membranes that serves as a precursor molecule for another important
class of steroids: the sex hormones (testosterone, progesterone, and estrogen). You should
be able to recognize the structures shown in Figure 5.5 for the AP exam.

Steroids to Recognize!

CH3 OH
CH3
H3C CH3

HO
H
Cholesterol Testosterone

Figure 5.5 Steroid structures.
 Chemistry of Life   ❮  53

H H H H H

H O C C C C C C H

H C O H H H H H

H H H H H

O C C C C C C H

H C O H H H H H

O

H C O P O

H O–

Figure 5.6 Structure of phospholipid.

A phospholipid is a lipid formed by combining a glycerol molecule with two fatty acids
and a phosphate group (Figure 5.6). Phospholipids are amphipathic structures; they have
both a hydrophobic tail (a hydrocarbon chain) and a hydrophilic head (the phosphate group)
(Figure 5.7). They are the major component of cell membranes; the hydrophilic phosphate
group forms the outside portion, and the hydrophobic tail forms the interior of the wall.

Carbohydrates
Carbohydrates can be simple sugars or complex molecules containing multiple sugars.
Carbohydrates are used by the cells of the body in energy-producing reactions and as struc-
tural materials. Carbohydrates have the elements C, H, and O. Hydrogen and oxygen are
present in a 2:1 ratio. The three main types of carbohydrates you need to know are mono-
saccharides, disaccharides, and polysaccharides.

Phospholipid Bilayer – Recognize Me!!!

Hydrophobic tail

Hydrophilic head

Figure 5.7 Bilayered structure of phospholipids.
54  ❯   STEP 4. Review the Knowledge You Need to Score High

CH2OH
O

OH
HO OH
OH

Figure 5.8 Glucose structure.

A monosaccharide, or simple sugar, is the simplest form of a carbohydrate. The most
important monosaccharide is glucose (C6H12O6), which is used in cellular respiration to
provide energy for cells. Monosaccharides with five carbons (C5H10O5) are used in com-
pounds such as genetic molecules (RNA) and high-energy molecules (ATP). The structure
of glucose is shown in Figure 5.8.
A disaccharide is a sugar consisting of two monosaccharides bound together. Com­mon
disaccharides include sucrose, maltose, and lactose. Sucrose, a major energy carbohydrate
in plants, is a combination of fructose and glucose; maltose, a carbohydrate used in the
creation of beer, is a combination of two glucose molecules; and lactose, found in dairy
products, is a combination of galactose and glucose.
A polysaccharide is a carbohydrate containing three or more monosaccharide molecules.
Polysaccharides, usually composed of hundreds or thousands of monosaccharides, act as a
storage form of energy and as structural material in and around cells. The most important
carbohydrates for storing energy are starch and glycogen. Starch, made solely of glucose mol-
ecules linked together, is the storage form of choice for plants. Animals store much of their
carbohydrate energy in the form of glycogen, which is most often found in liver and muscle
cells. Glycogen is formed by linking many glucose molecules together.
Julie (11th grade): Two important structural polysaccharides are cellulose and chitin. Cellulose, a com-
“Remembering pound composed of many glucose molecules, is used by plants in the formation of their
these four came in cell walls. Chitin is an important part of the exoskeletons of arthropods such as insects,
handy on the test!” spiders, and shellfish.

Proteins
A protein is a compound composed of chains of amino acids. Proteins have many func-
tions in the body—they serve as structural components, transport aids, enzymes, and cell
signals, to name only a few. You should be able to identify a protein or an amino acid by
sight if asked to do so on the test.
An amino acid consists of a carbon center surrounded by an amino group, a carboxyl
group, a hydrogen, and an R group (see Figure 5.9). Remember that the R stands for “rest” of

Carboxyl group

R
H O
N C C
H OH
H
Amino group

Figure 5.9 Structure of an amino acid.
 Chemistry of Life   ❮  55

R H R H R

H2N C C N C C N C C O

H O H O H OH

Peptide bonds

Figure 5.10 Amino acid structure exhibiting peptide linkage.

the compound, which provides an amino acid’s unique personal characteristics. For instance,
acidic amino acids have acidic R groups, basic amino acids have basic R groups, and so forth.
Many students preparing for the AP exam wonder if they need to memorize the 20 amino
acids and their structures and whether they are polar, nonpolar, or charged. This is a lot of
effort for perhaps one multiple-choice question that you might encounter on the exam. We
think that this time would be better spent studying other potential exam questions. If this is
of any comfort to you, we have yet to see an AP Biology question that asks something to the
effect of “Which of these 5 amino acids is nonpolar?” (Disclaimer: This does not mean that
it will never happen.) It is more important for you to identify the general structure of an
amino acid and know the process of protein synthesis.
A protein consists of amino acids linked together, as shown in Figure 5.10. They are most
often much larger than that depicted here. Figure 5.10 is included to enable you to identify a
peptide linkage on the exam. Most proteins have many more amino acids in the chain.
The AP exam may expect you to know about the structure of proteins:

Primary structure. The order of the amino acids that make up the protein.
KEY IDEA
Secondary structure. Three-dimensional arrangement of a protein caused by hydrogen
bonding at regular intervals along the polypeptide backbone.
Tertiary structure. Three-dimensional arrangement of a protein caused by inter­action
among the various R groups of the amino acids involved.
Quaternary structure. The arrangement of separate polypeptide “subunits” into a single pro-
tein. Not all proteins have quaternary structure; many consist of a single polypeptide chain.

Proteins with only primary and secondary structure are called fibrous proteins. Pro­teins
with only primary, secondary, and tertiary structures are called globular proteins. Either
fibrous or globular proteins may contain a quaternary structure if there is more than one
polypeptide chain.
56  ❯   STEP 4. Review the Knowledge You Need to Score High

Nucleic Acids
DNA Structure and Function
Deoxyribonucleic acid, known to her peers as DNA, is composed of four nitrogenous bases:
adenine, guanine, cytosine, and thymine. Adenine and guanine are a type of nitrogenous
base called a purine, and contain a double-ring structure. Thymine and cytosine are a type
of nitrogenous base called a pyrimidine, and contain a single-ring structure. Two scientists,
James D. Watson and Francis H.C. Crick, spent a good amount of time devoted to deter-
mining the structure of DNA. Their efforts paid off, and they were the ones given credit
for realizing that DNA was arranged in what they termed a double helix composed of two
strands of nucleotides held together by hydrogen bonds. They noted that adenine always pairs
with thymine (A=T) held together by two hydrogen bonds and that guanine always pairs with
cytosine (C≡G) held together by three hydrogen bonds. Each strand of DNA consists of a
sugar-phosphate backbone that keeps the nucleotides connected with the strand. The sugar is
deoxyribose. (See Figure 5.11 for a rough sketch of what purine–pyrimidine bonds look like.)

Sugar
Phosphate = Purine
Phosphate
Sugar
Sugar
Phosphate
= Pyrimidine
Phosphate

= Hydrogen bond
Sugar
Sugar

Figure 5.11 Purine–pyrimidine bonds.

One last structural note about DNA that can be confusing is that DNA has something
called a 5′ end and a 3′ end (Figure 5.12). The two strands of a DNA molecule run antiparal-
lel to each other; the 5′ end of one molecule is paired with the 3′ end of the other molecule,
and vice versa.

What does this 5′ to 3′ business look like?
5′ – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – 3′
A C T C A A T G C G

T G A G T T A C G C
3′ – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – S – P – 5′

S = Sugar
P = Phosphate
A, C, G, and T = Nitrogenous bases
= Two hydrogen bonds
= Three hydrogen bonds

Figure 5.12 The 5′ and 3′ ends in DNA structure.
 Chemistry of Life   ❮  57

RNA Structure and Function
Ribonucleic acid is known to the world as RNA. There are some similarities between DNA
and RNA. They both have a sugar-phosphate backbone. They both have four different
nucleotides that make up the structure of the molecule. They both have three letters in their
nickname—don’t worry if you don’t see that last similarity right away,... remember that
we have been studying these things for years. These two molecules also have their share of
differences. RNA’s nitrogenous bases are adenine, guanine, cytosine, and uracil. There is
no thymine in RNA; uracil beat out thymine for the job (probably had a better interview
during the hiring process). Another difference between DNA and RNA is that the sugar for
RNA is ribose instead of deoxyribose. While DNA exists as a double strand, RNA has a bit
more of an independent personality and tends to roam the cells as a single-stranded entity.
There are three main types of RNA that you should know about, all of which are formed
from DNA templates in the nucleus of eukaryotic cells: (1) messenger RNA (mRNA),
(2) transfer RNA (tRNA), and (3) ribosomal RNA (rRNA).

pH: Acids and Bases
The pH scale is used to indicate how acidic or basic a solution is. It ranges from 0 to 14;
7 is neutral. Anything less than 7 is acidic; anything greater than 7 is basic. The pH scale
is a logarithmic scale and as a result, a pH of 5 is 10 times more acidic than a pH of 6.
Following the same logic, a pH of 4 is 100 times more acidic than a pH of 6. Remember
that as the pH of a solution decreases, the concentration of hydrogen ions in the solution
increases, and vice versa. For the most part, chemical reactions in humans function at or
near a neutral pH. The exceptions to this rule are the chemical reactions involving some of
the enzymes of the digestive system.
58  ❯   STEP 4. Review the Knowledge You Need to Score High

❯ Review Questions
For questions 1–4, please use the following answer choices:

CH3
H
H O H H H H H N C C O
H
H C O C C C C C C H H OH
(B)
H H H H H

O H H H H H

H C O C C C C C C H

H H H H H O

O H H H H H (C)
H C O C C C C C C H

H H H H H H CH3 CH3 H OH
(A) H2N C C N C C N C C O

H O H O CH2

SH
(D)

1. Which of the structures shown above is a 6. A solution that has a pH of 2 is how many
polypeptide? times more acidic than one with a pH of 5?
2. Which of these structures is a disaccharide? A. 5
B. 10
3. Which of these structures is a fat?
C. 100
4. Which of these structures is an amino acid? D. 1,000
5. Which of the following has both a hydrophobic 7. The structure below contains which functional
portion and a hydrophilic portion? group?
A. Starch O
B. Phospholipids
C. Proteins CH3 CH2 C CH3
D. Steroids

A. Aldehyde
B. Ketone
C. Amino
D. Hydroxyl
 Chemistry of Life   ❮  59

8. Which of the following will least affect the effec- 10. All the following are carbohydrates except
tiveness of an enzyme?
A. starch.
A. Temperature B. glycogen.
B. pH C. chitin.
C. Concentration of enzyme D. glycerol.
D. Original activation energy of system
11. An amino acid contains which of the following
9. Which of the following is similar to the process functional groups?
of competitive inhibition?
A. Carboxyl group and amino group
A. When you arrive at work in the morning, B. Carbonyl group and amino group
you are unable to park your car in your C. Hydroxyl group and amino group
(assigned) parking spot because the car of the D. Carboxyl group and hydroxyl group
person who parks next to you has taken up
just enough space that you cannot fit your
own car in.
B. When you arrive at work in the morning, you
are unable to park your car in your parking
spot because someone with a car exactly like
yours has already taken your spot, leaving you
nowhere to park your car.
C. As you are about to park your car in your
spot at work, a giant bulldozer comes along
and smashes your car away from the spot,
pre­venting you from parking your car in
your spot.
D. When you arrive at work in the morning,
you are unable to park your car in your park­
ing spot because someone has placed a giant
cement block in front of your spot.

❯ Answers and Explanations
1. D ketones and aldehydes. In this case, it is a ketone
because there are carbon chains on either side of
2. C
the carbon double-bonded to the oxygen.
3. A
8. D—The four main factors that affect enzyme
4. B efficiency are pH, temperature, enzyme concen-
tration, and substrate concentration.
5. B—A phospholipid has both a hydrophobic por-
tion and a hydrophilic portion. The hydrocarbon 9. B—Competitive inhibition is the inhibition of an
portion, or tail, of the phospholipid dislikes water, enzyme–substrate reaction in which the inhibi-
and the phosphate portion, the head, is hydro- tor resembles the substrate and physically blocks
philic. the substrate from attaching to the active site.
This parking spot represents the active site, your
6. D—Because the pH scale is logarithmic, 2 is
car is the substrate, and the other car already in
1,000 times more acidic than 5.
the spot is the competitive inhibitor. Examples
7. B—This functional group is a carbonyl group. A and D more closely resemble noncompetitive
The two main types of carbonyl groups are inhibition.
60  ❯   STEP 4. Review the Knowledge You Need to Score High

10. D—Glycerol is not a carbohydrate. It is an alco- 11. A
hol. Starch is a carbohydrate stored in plant cells.
Glycogen is a carbohydrate stored in animal cells. R O Carboxyl group
Chitin is a carbohydrate used by arthropods to
construct their exoskeletons. Cellulose is a carbo- H2N C C OH
hydrate used by plants to construct their cell walls.
Amino group H

❯ Rapid Review
Try to rapidly review the following material:
Organic compounds: contain carbon; examples include lipids, proteins, and carbs
(carbohydrates).
Functional groups: amino (NH2), carbonyl (RCOR), carboxyl (COOH), hydroxyl (OH),
phosphate (PO4), sulfhydryl (SH).
Fat: glycerol + 3 fatty acids.
Saturated fat: bad for you; animals and some plants have it; solidifies at room temperature.
Unsaturated fat: better for you, plants have it; liquifies at room temperature.
Steroids: lipids whose structures resemble chicken-wire fence; include cholesterol and sex
hormones.
Phospholipids: glycerol + 2 fatty acids + 1 phosphate group; make up membrane bilayers
of cells; have hydrophobic interiors and hydrophilic exteriors.
Carbohydrates: used by cells for energy and structure; monosaccharides (glucose), disaccha-
rides (sucrose, maltose, lactose), storage polysaccharides (starch [plants], glycogen [animals]),
structural polysaccharides (chitin [fungi], cellulose [arthropods]).
Proteins: made with the help of ribosomes out of amino acids; serve many functions (e.g.,
transport, enzymes, cell signals, receptor molecules, structural components, and channels).
Enzymes: catalytic proteins that react in an induced-fit fashion with substrates to speed up
the rate of reactions by lowering the activation energy; effectiveness is affected by changes
in pH, temperature, and substrate and enzyme concentrations.
Competitive inhibition: inhibitor resembles substrate and binds to active site.
Noncompetitive inhibition: inhibitor binds elsewhere on enzyme; alters active site so that
substrate cannot bind.
pH: logarithmic scale 7 basic (alkaline); pH 4 is 10 times more acidic
than pH 5.
Reaction types:
Hydrolysis reaction: breaks down compounds by adding water.
Dehydration reaction: two components brought together, producing H2O.
Endergonic reaction: reaction that requires input of energy.
Exergonic reaction: reaction that gives off energy.
Redox reaction: electron transfer reactions.