Lecture Outline
3.1 The
Molecules of Life—From Structure to Function
A. What Is An Organic Compound?
1. Only living cells can synthesize
carbohydrates, lipids, proteins, and nucleic acids.
2. These molecules are organic compounds
consisting of carbon and one or more additional elements, covalently bonded to
one another.
B. It All Starts With Carbon's Bonding Behavior
1. Oxygen, hydrogen, and carbon are the most
abundant elements in living matter.
2. Much of the H and O are linked as water.
3. Carbon can share pairs of electrons with as
many as four other atoms to form organic molecules of several configurations.
C. Ways of Representing Organic Compounds
1. A ball-and-stick model depicts bonding of
atoms; space-filling models convey a molecule's size and surfaces.
2. Larger molecules are best visualized using
ribbon models, such as those generated by computer programs.
3.2 Overview of
Functional Groups
A. Functional groups are atoms or groups of
atoms covalently bonded to a carbon backbone; they convey distinct properties,
such as solubility and chemical reactivity, to the complete molecule.
B. The common functional groups in biological
molecules are: hydroxyl, methyl, carbonyl, carboxyl, amino, phosphate, and sulfhydryl.
3.3 How Do Cells
Build Organic Compounds?
A. Four Families of Building Blocks
1. Simple sugars, fatty acids, amino acids, and
nucleotides are the four major families of small building blocks.
2. Monomers can be joined to form larger
polymers.
B. Five Categories of Reactions
1. Enzymes are a special class of proteins that
mediate five categories of reactions:
a. functional-group transfer from one molecule to another,
b. electron transfer —stripped from one molecule and given to
another,
c. rearrangement of internal bonds converts one type of
organic molecule to another,
d. condensation of two molecules into one,
e. cleavage
of one molecule into two.
2. In a condensation reaction, one molecule is
stripped of its H+, another is stripped of its OH–; then the two molecule fragments join
to form a new compound and the H+ and OH– form water.
3. Hydrolysis is the reverse: one molecule is
split by the addition of H+ and OH– (from water) to the components.
3.4 Carbohydrates—The
Most Abundant Molecules of Life
A. The Simple Sugars
1. Monosaccharides—one
sugar unit—are the simplest carbohydrates.
2. They are characterized by solubility in
water, sweet taste, and several —OH
groups.
3. Ribose and deoxyribose
(five-carbon backbones) are building blocks for nucleic acids.
4. Glucose and fructose (six-carbon backbones)
are used in assembling larger carbohydrates.
5. Other important molecules derived from sugar
monomers include glycerol and vitamin C.
B. Short-Chain Carbohydrates
1. An oligosaccharide is a short chain of two or
more sugar monomers.
2. Disaccharides—two sugar units—are the
simplest.
a. Lactose (glucose + galactose)
is present in milk.
b. Sucrose (glucose + fructose) is a transport
form of sugar used by plants and harvested by humans for use in food.
c. Maltose (two glucose units) is present in
germinating seeds.
3. Oligosaccharides with three or more sugar
monomers are attached as short side chains to proteins where they participate
in membrane function.
C. Complex Carbohydrates
1. A polysaccharide is a straight or branched
chain of hundreds or thousands of sugar monomers.
2. Starch is a plant storage form of energy,
arranged as unbranched coiled chains, easily
hydrolyzed to glucose units.
3. Cellulose is a fiberlike
structural material—tough, insoluble—used in plant cell walls.
4. Glycogen is a highly-branched chain used by
animals to store energy in muscles and liver.
5. Chitin is a specialized polysaccharide with
nitrogen attached to the glucose units; it is used as a structural material in
arthropod exoskeletons and fungal cell walls.
3.5 Greasy,
Oily—Must Be Lipids
A. Lipids are greasy or oily compounds with
little tendency to dissolve in water.
1. They can be broken down by hydrolysis
reactions.
2. They function in energy storage, membrane
structure, and coatings.
B. Fats and Fatty Acids
1. A fatty acid is a long chain of mostly carbon
and hydrogen atoms with a —COOH group at one end.
2. When they are part of complex lipids, the
fatty acids resemble long, flexible tails.
a. Unsaturated
fats are liquids (oils) at room temperature because one or more double
bonds between the carbons in the fatty acids permits “kinks” in the tails.
b. Saturated
fats (triglycerides) have only single C—C bonds in their fatty acid tails
and are solids at room temperature.
3. Fats are formed by the attachment of one
(mono-), two (di-), or three (tri-) fatty acids to a
glycerol.
a. They are a rich source of energy, yielding
more than twice the energy per weight basis as carbohydrates.
b. They also provide an insulation blanket for
animals that must endure cold, harsh temperatures.
C. Phospholipids
1. These are formed by attachment of two fatty
acids plus a phosphate group to a glycerol.
2. They are the main structural material of
membranes where they arrange in bilayers.
D. Sterols and Their Derivatives
1. Sterols have a backbone of four carbon rings
but no fatty acid tails.
2. Cholesterol is a component of cell membranes
in animals and can be modified to form sex hormones (testosterone and estrogen)
and vitamin D.
E. Waxes
1. They are formed by attachment of long-chain
fatty acids to long-chain alcohols or carbon rings.
2. They serve as coatings for plant parts and as
animal coverings.
3.6 A String of
Amino Acids: Protein Primary Structure
A. Proteins function as enzymes, in cell
movements, as storage and transport agents, as hormones, as antibodies, and as
structural material.
B. Amino Acid Structure
1. Amino acids are small organic molecules with
an amino group, a carboxyl group, and one of twenty varying R groups.
2. All of the parts of an amino acid molecule
are covalently bonded to a central carbon atom.
C. Polypeptide Chain Formation
1. Primary
structure is defined as ordered sequences of amino acids each linked
together by peptide bonds to form polypeptide chains.
2. There are 20 kinds of amino acids available
in nature.
3. The sequence of the amino acids is determined
by DNA and is unique for each kind of protein.
a. Fibrous proteins have polypeptide chains
organized as strands or sheets; they contribute to the shape, internal
organization, and movement of cells.
b. Globular proteins, including most enzymes,
have their chains folded into compact, rounded shapes.
3.7 How Does a
Protein's Final Structure Emerge?
A. Second and Third Levels of Protein Structure
1. Secondary
structure refers to the helical coil (as in hemoglobin) or sheetlike array (as in silk) that results from hydrogen
bonding of side groups on the amino acid chains.
2. Tertiary
structure is the result of folding due to interactions among R groups along
the polypeptide chain.
B. Fourth Level of Protein Structure
1. Quaternary
structure describes the complexing of two of more
polypeptide chains.
2. Hemoglobin is a good example of four
interacting chains that form a globular proteins;
keratin and collagen are complex fibrous proteins.
3. Glycoproteins
consist of oligosaccharides covalently bonded to proteins; they are abundant on
the exterior of animal cells, as cell products, and in the blood.
4. Lipoproteins have both lipid and protein
components; they transport fats and cholesterol in the blood.
C. Denaturation—How to
Undo the Structure
1. High temperatures or changes in pH can cause
a loss of a protein’s normal three-dimensional shape (denaturation).
2. Normal functioning is lost upon denaturation, which is often irreversible (for example, a
cooked egg).
3.8 Why
Is Protein Structure So Important?
A. Just One Wrong Amino Acid...
1. Alteration of a cell's DNA can result in the
wrong amino acid insertion in a polypeptide chain.
2. If valine is
substituted for glutamate in hemoglobin, the result is called HbS.
B. Sickle-Shaped Cells and a Serious Disorder
1. Persons who inherit two mutated genes for the
beta chain of hemoglobin can only make HbS.
2. The altered hemoglobin causes the red blood
cells to be misshapen—sickle-cell anemia, with many serious body dysfunctions.
3.9 Nucleotides
and Nucleic Acids
A. The Diverse Roles of Nucleotides
1. Each nucleotide consists of a five-carbon
sugar (ribose or deoxyribose), a nitrogen-containing
base, and a phosphate group.
a. Adenosine phosphates are chemical messengers
(cAMP) or energy carriers (ATP).
b. Nucleotide coenzymes transport hydrogen atoms
and electrons (examples: NAD+ and FAD).
2. Nucleotides also serve as building blocks for
nucleic acids.
B. Regarding DNA and the RNAs
1. Nucleic acids are polymers of nucleotides.
a. Four different kinds of nucleotides are
strung together to form large single or double-stranded molecules.
b. Each strand's backbone consists of joined
sugars and phosphates with nucleotide bases projecting toward the interior.
2. The two most important nucleic acids are DNA
and RNA.
a. DNA is a double-stranded helix carrying
encoded hereditary instructions.
b. RNA is single stranded and functions in
translating the code to build proteins.