Becker's World of the Cell Chapter 3 Study Guide PDF

Summary

This study guide provides an overview of Chapter 3, "The Macromolecules of the Cell", from Becker's World of the Cell, Tenth Edition. It covers important topics such as proteins, amino acids, and various classes of molecules. The guide also includes a table of common small molecules in cells.

Full Transcript

Becker’s World of the Cell
Tenth Edition

Chapter 3
The Macromolecules of the
Cell

Lectures by Anna Hegsted, Simon Fraser University

Modified by Taras Nazarko, Georgia State University

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The Macromolecules of the Cell
Polymers are synthesized by condensation reactions in
which activated monomers are linked together by the
removal of water.
Most biological macromolecules in cells are synthesized
from about 30 common small molecules.

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3.1 Proteins
Proteins are extremely important macromolecules in all
organisms, occurring nearly everywhere in the cell.
Proteins fall into nine major classes.

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Classes of Proteins (1 of 2)
Enzymes serve as catalysts, increasing the rates of
chemical reactions.
Structural proteins—physical support and shape
Motility proteins—contraction and movement
Regulatory proteins—control and coordinate cell function
Transport proteins—move substances into and out of cells

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Classes of Proteins (2 of 2)
Signaling proteins—communication between cells
Receptor proteins—enable cells to respond to chemical
stimuli from the environment
Defensive proteins—protect against disease
Storage proteins—reservoirs of amino acids

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The Monomers Are Amino Acids
Only 20 kinds of amino acids are used in protein
synthesis.
Some contain additional amino acids, usually the result of
modification.
No two different proteins have the same amino acid
sequence.

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Common Small Molecules in Cells
Table 3.1 Common Small Molecules in Cells
Kind of Number Figure Number
Names of Molecules Role in Cell
Molecules Present for Structures
Monomeric units of all
Amino acids 20 See list in Table 3-2 3-2
proteins
Aromatic Components of nucleic
5 Adenine 3-15
bases acids
Cytosine 3-15
Guanine 3-15
Thymine 3-15
Uracil 3-15
Sugars Varies Ribose Component of RNA 3-15
Deoxyribose Component of DNA 3-15
Energy metabolism;
Glucose component of starch and 3-21
glycogen
Energy metabolism;
Lipids Varies Fatty acids Components of 3-27a
phospholipids
and membranes
Cholesterol 3-27e

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Amino Acids
Every amino acid has the same basic structure.
Each has a unique side chain, called an R group.
All amino acids except glycine have an asymmetric α
carbon atom.
The specific properties of amino acids depend on the
nature of their R groups.

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The Structure and Stereochemistry of
an Amino Acid
Figure 3.1 The Structure
and Stereochemistry of an
Amino Acid.

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Classes of R Groups
Nine amino acids have nonpolar, hydrophobic R groups.
The remaining 11 amino acids are hydrophilic, with R
groups that are either polar or charged at cellular pH.
Acidic amino acids are negatively charged, whereas basic
amino acids are positively charged.
Polar amino acids tend to be found on the surfaces of
proteins.

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The Structures of the 20 Amino Acids
Found in Proteins
Figure 3.2 The Structures
of the 20 Amino Acids
Found in Proteins.

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Table 3.2 Abbreviations for Amino Acids
Amino Acid Three-Letter Abbreviation One-Letter Abbreviation
Alanine Ala A
Arginine Arg R
Asparagine Asn N
Aspartate Asp D
Cysteine Cys C
Glutamate Glu E
Glutamine Gln Q
Glycine Gly G
Histidine His H
Isoleucine Ile I
Leucine Leu L
Lysine Lys K
Methionine Met M
Phenylalanine Phe F
Proline Pro P
Serine Ser S
Threonine Thr T
Tryptophan Trp W
Tyrosine Tyr Y
Valine Val V

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The Polymers Are Polypeptides and
Proteins
Amino acids are linked together stepwise into a linear
polymer by dehydration (or condensation) reactions.
As the three atoms comprising the H2O are removed, a
covalent C—N bond (a peptide bond) is formed.

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Directionality of Polypeptides
Because of the way peptide bonds are formed,
polypeptides have directionality.
The end with the amino group is called the N- (or amino)
terminus.
The end with the carboxyl group is called the C- (or
carboxyl) terminus.

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Peptide Bond Formation
Figure 3.3 Peptide
Bond Formation.

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Proteins and Polypeptides
The process of elongating a chain of amino acids is called
protein synthesis.
However, the immediate product of amino acid
polymerization is a polypeptide.
A polypeptide does not become a protein until it has
assumed a unique, stable, three-dimensional shape and is
biologically active.

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Monomeric and Multimeric Proteins
Proteins that consist of a single polypeptide are
monomeric proteins, whereas multimeric proteins
consist of two or more polypeptides.
Proteins consisting of two or three polypeptides are called
dimers or trimers, respectively.
Hemoglobin is a tetramer, consisting of two α subunits and
two β subunits.

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The Structure of Hemoglobin
Figure 3.4 The Structure of Hemoglobin.

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Several Kinds of Bonds and
Interactions Are Important in Protein
Folding and Stability
Both covalent bonds and noncovalent interactions are
needed for a protein to adopt its proper shape, or
conformation.
These same bonds and interactions are required for
polypeptides to form multimeric proteins.
The interactions involve carboxyl, amino, and R groups of
the amino acids, called amino acid residues once
incorporated into a polypeptide.

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Bonds and Interactions Involved in
Protein Folding and Stability
Figure 3.5 Bonds and
Interactions Involved in
Protein Folding and
Stability.

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Disulfide Bonds
Covalent disulfide bonds form between the sulfur atoms
of two cysteine residues.
They form through the removal of two hydrogen ions
(oxidation) and can be broken only by the addition of two
hydrogens (reduction).
Once formed, disulfide bonds confer considerable stability
to the protein conformation.

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Categories of Disulfide Bonds
Intramolecular disulfide bonds form between cysteines in
the same polypeptide.
Intermolecular disulfide bonds form between cysteines in
two different polypeptides.
They link the two polypeptides together.

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Noncovalent Bonds and Interactions
Noncovalent bonds and interactions include hydrogen
bonds, ionic bonds, van der Waals interactions, and
hydrophobic interactions.
These are individually weaker than covalent bonds but
collectively can strongly influence protein structure and
stability.

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Hydrogen Bonds
Hydrogen bonds form in water and between amino acids
in a polypeptide chain via their R groups.
Hydrogen bond donors (e.g., hydroxyl or amino groups)
have hydrogen atoms covalently linked to more
electronegative atoms.
Hydrogen bond acceptors (e.g., carbonyl or sulfhydryl
groups) have an electronegative atom that attracts the
donor hydrogen.

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Ionic Bonds
Ionic bonds, or electrostatic interactions, form between
positively and negatively charged R groups.
They exert attractive forces over longer distances than
some of the other noncovalent interactions.
Because they depend on the charge on the R groups,
changes in pH can disrupt ionic bonds.

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Van Der Waals Interactions
Molecules with nonpolar covalent bonds may have
transient positively and negatively charged regions.
These are called dipoles, and two molecules with dipoles
will be attracted to one another if they are close enough.
This transient interaction is called a van der Waals
interaction or van der Waals force.

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Hydrophobic Interactions
A hydrophobic interaction is the tendency of
hydrophobic molecules or parts of molecules to be
excluded from interactions with water.
Amino acids with hydrophobic side chains tend to be
found within proteins.
Protein folding is a balance between the tendency of
hydrophilic groups to interact with water and of
hydrophobic groups to avoid interaction with water.

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Chaperone Interactions
Molecular chaperones are proteins that aid in the proper
and accurate folding of other proteins.
They act during protein synthesis or facilitate refolding.
The general mechanism involves shielding parts of the
protein from the interactions discussed until more of the
protein can be made.

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Protein Structure Depends on Amino
Acid Sequence and Interactions
The overall shape and structure of a protein are described
in terms of four levels of organization
– Primary structure—amino acid sequence
– Secondary structure—local folding of polypeptide
– Tertiary structure—three-dimensional conformation
– Quaternary structure—interactions between
monomeric proteins to form a multimeric unit

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Levels of Organization of Protein
Structure
Table 3.3 Levels of Organization of Protein Structure

Kinds of Bonds and
Level of Structure Basis of Structure
Interactions Involved

Primary Amino acid sequence Covalent peptide bonds
Hydrogen bonds between NH
Folding into α helix, β sheet, or
Secondary and CO groups of peptide bonds
random coil
in the backbone
Disulfide bonds, hydrogen
Three-dimensional folding of a bonds, ionic bonds, van der
Tertiary
single polypeptide chain Waals interactions, hydrophobic
interactions
Association of multiple
Quaternary polypeptides to form a Same as for tertiary structure
multimeric protein

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The Four Levels of Organization of
Protein
Figure 3.6 The Four Levels of Organization of Protein
Structure.

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Primary Structure
Primary structure refers to the amino acid sequence.
By convention, amino acid sequences are written from the
N-terminus to the C-terminus, the direction in which the
polypeptide was synthesized.
The first protein to have its amino acid sequence
determined was the hormone insulin.
Insulin consists of one A and one B subunit with 21 and 30
amino acids, respectively.

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The Structure of Insulin
Figure 3.7 The Structure of Insulin.

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Determining Amino Acid Sequence
Sanger obtained the Nobel Prize for his work on the
insulin protein sequence.
He cleaved the protein into smaller fragments and
analyzed the amino acid order within individual
overlapping fragments.
Sanger’s work paved the way for the sequencing of
hundreds of other proteins and for advancements in the
methods used for sequencing proteins.

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The Importance of Primary Structure
Primary structure is important genetically because the
sequence is specified by the order of nucleotides in the
corresponding messenger RNA.
It is important structurally because the order and identity of
amino acids directs the formation of the higher-order
(secondary and tertiary) structures.

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Secondary Structure
The secondary structure of a protein describes local
regions of structure that result from hydrogen bonding
between NH and CO groups along the polypeptide
backbone.
These result in two major patterns, the α helix and the β
sheet.

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The α Helix (1 of 2)
The α helix is spiral in shape, consisting of the peptide
backbone, with R groups jutting out from the spiral.
There are 3.6 amino acids per turn of the helix.
A hydrogen bond forms between the NH group of one
amino acid and the CO group of another amino acid that is
one turn away from the first.

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The α Helix (2 of 2)
Figure 3.8 The α Helix
and β Sheet.

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The β Sheet (1 of 3)
The β sheet is an extended sheetlike conformation with
successive atoms of the polypeptide chain located at
“peaks” or “troughs.”
The R groups jut out on alternating sides of the sheet.
Because of the formation of peaks and troughs, it is
sometimes referred to as a β-pleated sheet.

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The β Sheet (2 of 3)
The β sheet is characterized by a maximum of hydrogen
bonding, but β sheet formation may involve different
polypeptides or different regions of a single polypeptide.
If the parts of polypeptides forming the β sheet have the
same polarity (relative to the N- and C- termini), they are
called parallel.
If the parts of polypeptides forming the β sheet have
opposite polarity, they are called antiparallel.

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The β Sheet (3 of 3)
Figure 3.8 The Helix
and Sheet.

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Amino Acid Sequence and Secondary
Structure
Certain amino acids (e.g., leucine, methionine, glutamate)
tend to form α helices, whereas others (e.g., isoleucine,
valine, phenylalanine) tend to form β sheets.
Proline cannot form hydrogen bonds and tends to disrupt
α helix structures by introducing a bend in the helix.

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Motifs
Certain combinations of α helices and β sheets have been
identified in many proteins.
These units of secondary structure consist of short
stretches of α helices and β sheets and are called motifs.
Examples include the β–α–β, the hairpin loop, and the
helix-turn-helix motifs.

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Common Structural Motifs
Figure 3.9 Common
Structural Motifs.

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Tertiary Structure
The tertiary structure reflects the unique aspect of the
amino acid sequence because it depends on interactions
of the R groups.
Tertiary structure is neither repetitive nor easy to predict.
It results from the sum of hydrophobic residues avoiding
water, hydrophilic residues interacting with water, the
repulsion of similarly charged residues, and attraction
between oppositely charged residues.

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Native Conformation
The most stable possible three-dimensional structure of a
particular polypeptide is called the native conformation.
Proteins can be divided into two broad categories
– Fibrous proteins
– Globular proteins

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Fibrous Proteins
Fibrous proteins have extensive regions of secondary
structure, giving them a highly ordered, repetitive
structure.
Some examples include:
– Fibroin proteins of silk
– Keratin proteins of hair and wool
– Collagen found in tendons and skin
– Elastin found in ligaments and blood vessels

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The Fibroin Structure
Figure 3.10 Fibroin Structure.

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The Structure of Hair
Figure 3.11 The Structure of
Hair.

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Globular Proteins
Most proteins are globular proteins that are folded into
compact structures.
Each type of globular protein has its own unique tertiary
structure.
Most enzymes are globular proteins.

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The Three-Dimensional Structure of
Ribonuclease
Figure 3.12 The Three-
Dimensional Structure of
Ribonuclease.

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Structures of Globular Proteins
Globular proteins can be mainly α helical, mainly β sheet,
or a mixture of both structures.
Many globular proteins consist of a number of segments
called domains.

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The Structures of Several Globular
Proteins
Figure 3.13 Structures of Several Globular Proteins.

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Protein Domains
A domain is a discrete, locally folded unit of tertiary
structure, usually with a specific function.
A domain is typically 50–350 amino acids long, with
regions of α helices and β sheets packed together.
Proteins with similar functions often share a common
domain.
Proteins with multiple functions usually have a separate
domain for each function, like modular units from which
globular proteins are constructed.

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An Example of Protein Containing
Two Functional Domains
Figure 3.14 An Example
of a Protein Containing
Two Functional Domains.

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Prediction of Tertiary Structure
It is known that primary structure determines the final
folded shape of a protein.
However, we are still not able to predict exactly how a
given protein will fold, especially for larger proteins.

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Quaternary Structure
The quaternary structure of a protein is the level of
organization concerned with subunit interactions and
assembly.
The term applies specifically to multimeric proteins.
Some proteins consist of multiple identical subunits;
others, such as hemoglobin, contain two or more types of
polypeptides.

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Maintenance of Quaternary Structure
The bonds and forces maintaining quaternary structure are
the same as those responsible for tertiary structure.
The process of subunit assembly is usually spontaneous.
Sometimes, molecular chaperones are required to assist
the process.

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Higher Levels of Assembly
A higher level of assembly is possible in the case of
proteins (often enzymes) that are organized into
multiprotein complexes.
Each protein in the complex may be involved sequentially
in a common multistep process.
An example is the pyruvate dehydrogenase complex, in
which three enzymes and five other proteins form a
multienzyme complex.

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3.2 Nucleic Acids
Nucleic acids are of paramount importance to the cells
because they store, transmit, and express genetic
information.
They are linear polymers of nucleotides.
DNA is deoxyribonucleic acid, and RNA is ribonucleic
acid.

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D N A and R N A Differ
DNA and RNA differ chemically and in their role in the cell
– RNA contains the five-carbon sugar ribose, and DNA
contains the related sugar deoxyribose.
– DNA serves as the repository of genetic information,
whereas RN A plays several roles in expressing that
information.

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The Monomers Are Nucleotides
RNA and DNA each consist of only four different types of
nucleotides, the monomeric units.
Each nucleotide consists of a five-carbon sugar to which a
phosphate group and N-containing aromatic base are
attached.
Each base is either a purine or a pyrimidine.

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The Structure of a Nucleotide
Figure 3.15 The Structure of a Nucleotide.

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Types of Nucleotides
Purines are adenine (A) and guanine (G).
Pyrimidines are thymine (T) and cytosine (C), and in
RNA, uracil (U).
The sugar-base portion without the phosphate group is
called a nucleoside.

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Nomenclature
Nucleosides with one phosphate group can be thought of
as nucleoside monophosphates (example: adenosine
monophosphate, AMP).
Adenosine diphosphate (ADP) has two phosphate
groups, and adenosine triphosphate (ATP) has three.

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The Bases, Nucleosides, and
Nucleotides of RNA and DNA
Table 3.4 The Bases, Nucleosides, and Nucleotides of RNA
and DNA

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The Phosphorylated Forms of
Adenosine
Figure 3.16 The Phosphorylated Forms of Adenosine.

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The Polymers Are DNA and RNA
Nucleic acids are linear polymers of nucleotides linked by
a 3′, 5′ phosphodiester bridge, a phosphate group linked
to two adjacent nucleotides via two phosphodiester bonds.
The polynucleotide formed by this process has a
directionality with a 5′ phosphate group at one end and a 3′
hydroxyl group at the other.
Nucleotide sequences are conventionally written in the 5′
to 3′ direction.

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The Structure of Nucleic Acids
Figure 3.17 The Structure of Nucleic Acids.

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Nucleic Acid Synthesis
A preexisting molecule is used to ensure that new
nucleotides (NTPs for RNA, dNTPs for DNA) are added
in the correct order.
This molecule is called a template, and correct base
pairing between the template and the incoming nucleotide
is required to specify correct order.
A complementary relationship exists between certain
purines and pyrimidines.

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Complementary Base Pairing
Complementary base pairing allows A to form two
hydrogen bonds with T and G to form three hydrogen
bonds with C.
This base pairing is a fundamental property of nucleic
acids.

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Hydrogen Bonding in DNA Nucleic
Acid Structure
Figure 3.18 Hydrogen Bonding in DNA Nucleic Acid Structure.

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The DNA Molecule Is a Double-
Stranded Helix
Francis Crick and James Watson postulated the double
helix structure of DNA in 1953.
The structure accounted for the known physical and
chemical properties of DNA.
It also suggested a mechanism for DNA replication.
Two antiparallel and complementary strands of DNA twist
around a common axis to form a right-handed spiral
structure.

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The Structure of Double-Stranded DNA
Figure 3.19 The Structure of Double-
Stranded DNA.

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Base Pairing and RNA
RNA is normally single stranded.
RNA structure also depends on base pairing.
However, the pairing is usually between bases in different
areas of the same molecule and is less extensive than that
of DNA.

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3.3 Polysaccharides
Polysaccharides are long chain polymers of sugars and
sugar derivatives.
They serve primarily in structure and storage.
They usually consist of a single kind of repeating unit or
sometimes an alternating pattern of two kinds.
Short polymers, oligosaccharides, are sometimes attached
to cell surface proteins.

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The Monomers Are Monosaccharides
Repeating units of polysaccharides are
monosaccharides.
A sugar may be an aldehyde, aldosugars with a terminal
carbonyl group; or ketone, ketosugars with an internal
carbonyl group.
Sugars within these groups are named generically based
on how many carbon atoms they contain.

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Structures of Monosaccharides
Figure 3.20 Structures of Monosaccharides.

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Classification of Sugars
Most sugars have between three and seven carbons and
are classified as
– Trioses (three carbons)
– Tetroses (four carbons)
– Pentoses (five carbons)
– Hexoses (six carbons)
– Heptoses (seven carbons)

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Glucose
The single most common monosaccharide is the
aldohexose D-glucose (C6H12O6).
The formula CnH2nOn is common for sugars and led to the
general term carbohydrate.
For every molecule of CO2 incorporated into a sugar, one
water molecule is consumed.
The carbons of glucose (and other organic molecules) are
numbered from the more oxidized, carbonyl end.

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The Structure of Glucose
D-glucose is the most stable form of glucose though many
other stereoisomers are possible.
D-glucose is often depicted as a linear molecule, as in the
Fischer projection, in which the H and OH groups are
intended to project out of the plane of the diagram.
In the cell, D-glucose exists in a dynamic equilibrium
between the linear and ring form.
The Haworth projection shows the ring form of the
molecule.

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The Structure of D-Glucose
Figure 3.21 The Structure of D-Glucose.

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Two Ring Forms of D-Glucose
The formation of a ring by D-glucose can result in two
alternative forms.
These depend on the spatial orientation of the hydroxyl
group on carbon number 1.
These forms are designated α (hydroxyl group downward)
and β (hydroxyl group upward).

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The Ring Forms of D-Glucose
Figure 3.22 The Ring Forms of D-Glucose.

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Glucose Also Exists in Disaccharides
Glucose exists in disaccharides, in which two
monosaccharide units are covalently linked.
Common disaccharides include
– Maltose, two glucose units
– Lactose, one glucose linked to one galactose
– Sucrose, one glucose linked to one fructose

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Disaccharides
The linkage of disaccharides is a glycosidic bond, formed
between two monosaccharides by the elimination of water.
Glycosidic bonds involving the α form of glucose are called
α glycosidic bonds (e.g., maltose); those involving the β
form are called β glycosidic bonds (e.g., lactose).

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Some Common Disaccharides
Figure 3.23 Some Common
Disaccharides.

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The Polymers Are Storage and
Structural Polysaccharides
The most familiar storage polysaccharides are starch in
plant cells and glycogen in animal cells and bacteria.
Both consist of α-D-glucose units linked by α glycosidic
bonds, involving carbons 1 and 4 (1→4).
Occasionally α(1→6) bonds may form, allowing for the
formation of side chains (branching).

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The Structure of Starch and Glycogen
Figure 3.24 The Structure
of Starch and Glycogen.

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Glycogen
Glycogen is highly branched, the branches occurring
every 8–10 glucose units along the backbone.
Glycogen is stored mainly in the liver (as a source of
glucose) and muscle tissues (as a fuel source for muscle
contraction) of animals.
Bacteria also store glycogen as a glucose reserve.

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Starch (1 of 2)
Starch is the glucose reserve commonly found in plant
tissue.
It occurs both as unbranched amylose (10–30%) and
branched amylopectin (70–90%).
Amylopectin has α(1→6) branches once every
12–25 glucose units and has longer side chains than
glycogen.

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Starch (2 of 2)
Starch is stored as starch grains within the plastids:
– Chloroplasts, the sites of carbon fixation and sugar
synthesis in photosynthesis
– Amyloplasts, which are specialized for starch storage

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Structural Polysaccharides
The best-known structural polysaccharide is the cellulose
found in plant cell walls.
Cellulose, composed of repeating monomers of
β-D-glucose, is very abundant in plants.
Mammals cannot digest cellulose (though some have
microorganisms in their digestive systems that can).

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The Structure of Cellulose
Figure 3.25 The Structure
of Cellulose.

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Other Structural Polysaccharides
The cellulose of fungal cell walls differs from that of plants
and may contain either β(1→4) or β(1→3) linkages.
Bacterial cell walls contain two kinds of sugars: GlcNAc
(N-acetylglucosamine) and MurNAc (N-acetylmuramic
acid).
Both are derivatives of β-glucosamine and are linked
alternately in cell walls.

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Chitin
The polysaccharide chitin consists of GlcNAc units only,
joined by β(1→4) bonds.
Chitin is found in insect exoskeletons, crustacean shells,
and fungal cell walls.

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Polysaccharides of Bacterial Cell
Walls and Insect Exoskeletons
Figure 3.26
Polysaccharides of
Bacterial Cell Walls
and Insect
Exoskeletons.

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Polysaccharide Structure Depends on
the Type of Glycosidic Bonds Involved
α and β glycosidic bonds are associated with marked
structural differences.
Starch and glycogen (α polysaccharides) form loose
helices that are not highly ordered because of the side
chains.
Cellulose (that forms β linkages) exists as rigid linear rods
that aggregate into microfibrils, about 5–20 nm in
diameter.
Plant and fungal cells walls contain these rigid microfibrils
in a noncellulose matrix containing other polymers
(hemicellulose, pectin) and a protein called extensin.
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3.4 Lipids
Lipids are not formed by the same type of linear
polymerization that forms proteins, nucleic acids, and
polysaccharides.
However, they are regarded as macromolecules because
of their high molecular weight and their importance in
cellular structures, particularly membranes.

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Features of Lipids
Although heterogeneous, all have a hydrophobic nature
and thus little affinity for water; they are readily soluble in
nonpolar solvents such as chloroform or ether.
They have relatively few polar groups, but some are
amphipathic, having polar and nonpolar regions.
Functions include energy storage, membrane structure, or
specific biological functions such as signal transmission.

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The Main Classes of Lipids (1 of 2)
The lipids can be divided into six classes based on their
structure:
– Fatty acids
– Triacylglycerols
– Phospholipids
– Glycolipids
– Steroids
– Terpines

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The Main Classes of Lipids (2 of 2)
Figure 3.27 The Main
Classes of Lipids.

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Fatty Acids
Figure 3.27 The Main Classes of Lipids.

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Fatty Acids Are the Building Blocks
of Several Classes of Lipids
Fatty acids are components of several other kinds of
lipids.
A fatty acid is a long amphipathic, unbranched
hydrocarbon chain with a carboxyl group at one end.
The polar carboxyl group is the “head,” and the nonpolar
hydrocarbon chain is the “tail.”

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Fatty Acid Structure (1 of 2)
The hydrocarbon tails are variable in length but usually 12
to 20 carbons long.
Even numbers of carbons are favored because fatty acid
synthesis occurs via the stepwise addition of two-carbon
units to the growing chain.
Fatty acids are highly reduced and so yield a large amount
of energy upon oxidation.

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Some Common Fatty Acids in Cells
Table 3.5 Some Common Fatty Acids in Cells

Number of Carbons Number of Double Bonds Common Name*

12 0 Laurate
14 0 Myristate
16 0 Palmitate
18 0 Stearate
20 0 Arachidate
16 1 Palmitoleate
18 1 Oleate
18 2 Linoleate
18 3 Linolenate
20 4 Arachidonate

*Shown are the names for the ionized forms of the fatty acids as they exist at the near
neutral pH of most cells. For the names of the free fatty acids, simply replace the –ate
ending with –ic acid.
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Fatty Acid Structure (2 of 2)
In saturated fatty acids, each carbon atom in the chain is
bonded to the maximum number of hydrogens.
These have long straight chains that pack together well.
Unsaturated fatty acids have one or more double bonds,
so they have bends in the chains and are less tightly
packed.

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Structures of Saturated and
Unsaturated Fatty Acids
Figure 3.28 Structures of Saturated and Unsaturated Fatty
Acids.

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Trans Fats
Trans fats are a type of unsaturated fatty acid with a
particular type of double bond that causes less of a bend
in the chain.
They are relatively rare in nature and are produced
artificially in shortening and margarine.
They have been linked to increased risk of heart disease
and elevated cholesterol levels.

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Triacylglycerols and Their Synthesis
Figure 3.27 The Main Classes of Lipids.

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Triacylglycerols Are Storage Lipids
Triacylglycerols, also known as triglycerides, consist of a
glycerol molecule with three fatty acids attached to it.
Glycerol is a three-carbon alcohol with a hydroxyl group
on each carbon.
Fatty acids are linked to glycerol, one at a time, by ester
bonds formed by the removal of water.

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Triacylglycerol Structure
Monoacylglycerols contain a single fatty acid.
Diacylglycerols have two fatty acids.
The three fatty acids on a triacylglycerol may vary in
length and degree of saturation.

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Triacylglycerol Function
The main function of triacylglycerols is energy storage.
Triacylglycerols containing mostly saturated fats are
usually solid or semisolid at room temperature and are
called fats.
Triacylglycerols in plants are liquid at room temperature
(e.g., vegetable oil) and are predominantly unsaturated.

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Phospholipids
Figure 3.27 The Main Classes of Lipids.

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Phospholipids Are Important in
Membrane Structure
Phospholipids are important to membrane structure
because of their amphipathic nature.
Phospholipids can be divided into phosphoglycerides or
sphingolipids, depending on their chemistry.

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Phosphoglycerides (1 of 2)
Phosphoglycerides are the predominant phospholipids in
most membranes.
The basic components of phosphoglycerides is
phosphatidic acid, which has two fatty acids and a
phosphate group attached to a glycerol.
Membrane phosphoglycerides invariably have a small
hydrophilic alcohol linked to the phosphate by an ester
bond.

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Structures of Common
Phosphoglycerides
Figure 3.29 Structures of Common
Phosphoglycerides.

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Phosphoglycerides (2 of 2)
The alcohol is usually serine, ethanolamine, choline, or
inositol, which contributes to the polar nature of the
phospholipid head group.
Typical phosphoglycerides often have one saturated and
one unsaturated fatty acid.
The length and degree of saturation of the fatty acids have
profound effects on membrane fluidity.

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Sphingolipids (1 of 2)
Sphingolipids are based on the amine sphingosine,
which has a long hydrocarbon chain with a single site of
unsaturation near the polar end.
Sphingosine can form an amide bond to a long-chain fatty
acid, resulting in a molecule called a ceramide.

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Sphingolipids (2 of 2)
A whole family of sphingolipids exists, with different polar
groups attached to the hydroxyl group of the ceramide.
Sphingolipids are predominantly found in the outer leaflet
of the plasma membrane bilayer, often in lipid rafts,
localized domains within a membrane.
Lipid rafts are important in communication between a cell
and its external environment.

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Glycolipids
Figure 3.27 The Main Classes of Lipids.

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Glycolipids Are Specialized
Membrane Components
Glycolipids are lipids containing a carbohydrate instead
of a phospholipid and are often derivatives of sphingosine
and glycerol (glycosphingolipids).
Carbohydrate groups attached to a glycolipid may be one
to six sugar units (D-glucose, D-galactose, or N-acetyl-D-
galactosamine).
Glycolipids occur largely on the outer monolayer of the
plasma membrane.

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Steroids
Figure 3.27 The Main Classes
of Lipids.

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Steroids Are Lipids with a Variety of
Functions
Steroids are derivatives of a four-ringed hydrocarbon
skeleton, which distinguishes them from other lipids.
They are relatively nonpolar and therefore hydrophobic.
Steroids differ from one another in the positions of double
bonds and functional groups.
The most common steroid in animal cells is cholesterol.

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Structures of Several Common
Steroid Hormones
Figure 3.30 Structures of
Several Common Steroid
Hormones.

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A Variety of Sterols
Cholesterol is insoluble and found primarily in plasma
membranes of animal cells and most membranes of
organelles.
Similar molecules are found in plant cells (stigmasterol
and sitosterol) and fungal cells (ergosterol).

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Steroid Hormones (1 of 2)
Cholesterol is the starting material for synthesis of steroid
hormones, including male and female sex hormones, the
glucocorticoids, and the mineralocorticoids.
Sex hormones include estrogens produced by the ovaries
of females (e.g., estradiol) and androgens produced by
male testes (e.g., testosterone).

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Steroid Hormones (2 of 2)
The glucocorticoids (e.g., cortisol) are a family of
hormones that promote synthesis of glucose and
suppress inflammation.
Mineralocorticoids (e.g., aldosterone) regulate ion balance
by promoting reabsorption of sodium, chloride, and
bicarbonate ions by the kidney.

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Terpenes
Figure 3.27 The Main Classes of
Lipids.

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Terpenes Are Formed from Isoprene
Terpenes are synthesized from the five-carbon compound
isoprene and are sometimes called isoprenoids.
Isoprene and its derivatives are joined in various
combinations to produce substances such as vitamin A
and carotenoid pigments.

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Other Isoprene-Based Compounds
The isoprene-based compounds, dolichols, are involved in
activating sugar compounds.
Electron carriers such as coenzyme Q and plastoquinone
are also isoprene derivatives.
Polyisoprenoids, polymers of isoprene, are found in cell
membranes of the Archaea.

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Copyright

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