Discover Biology Chapter 11: DNA and Genes PDF

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This document is a chapter from a textbook titled Discover Biology. The chapter covers DNA structure, function, and replication. It also explores the differences between prokaryotic and eukaryotic genomes in a table. The provided text is a preview of the content.

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Anu Singh-Cundy Gary Shin

Discover Biology
SIXTH EDITION
CHAPTER 11
DNA and Genes

© 2015 W. W. Norton & Company, Inc.
 An Overview of DNA and Genes
Genes code for genetic traits and
are located on chromosomes.
DNA is the genetic material that
makes up genes.
In the early part of the 1900s,
scientists were unsure if the
genetic material contained in
genes was the protein or the DNA.
By 1952, through a series of
experiments with bacteria,
biologists determined that the
genetic material was DNA.
 DNA Stores Genetic Information as a
Sequence of Nucleotides
DNA is a nucleic acid
composed of two strands
of polynucleotides
twisted to form a double
helix.

Four different
nucleotides make up
polynucleotides and can
be found in the DNA of
all cells.
 Generally, Complex Organisms Have a Larger
Genome and a Larger Number of Genes
TYPE OF GENOME SIZE (BP)* NUMBER OF
VIRUS/ORGANISM GENES"

Porcine circo virus Smallest eukaryotic virus; causes wasting 1,759 3
type 1 disease in pigs
Mycoplasma Smallest bacterium 580,073 517
genitalium

Mimivirus Largest known virus; infects Amoeba 1,181,404 1,262

Escherichia coli Most widely used lab bacterium 4,639,221 4,377
K-12
Saccharomyces Yeast (fungus) species used in baking and 12,110,000 5,770
cerevisiae brewing

Drosophila Fruit fly used in genetics and other types 130,000,000 17,000
melanogaster of research

Arabidopsis Thale-cress, a model plant used in 157,000,000 27,407
thaliana agricultural and other types of plant
research
Homo sapiens Humans 3,200,000,000 21,000

Oryza sativa Rice plant 4,311,000,000 56,000

Among eukaryotes, however, no strict relationship exists between
genome size and the structural and behavioral complexity of species.
 Most Genes Code for Proteins,
Which Generate Phenotypes
RNA is a single-stranded nucleic
acid similar to DNA.
Messenger RNA (mRNA) delivers
the genetic information, or
instructions, from DNA to the
ribosomes, where proteins are
made.
The conversion of a DNA-based
sequence of nucleotides in a gene
to an RNA-based sequence is called
transcription.

The process by which ribosomes
convert the genetic information in
Each protein has a unique amino acid sequence,
mRNA into proteins is known as which gives it a unique function; protein function
translation. produces the phenotype, the particular version of
a genetic trait in the individual organism.
 A Unique Set of Genes Is Expressed
in Each Specialized Cell Type

Gene expression is the manifestation of the information encoded in a gene as a specific
phenotype.
All cells in a multicellular individual have essentially the same DNA-based information;
however, not all cells express all the genes present in the genome.
Gene promoters are sections of a gene that function as an on/off switch for transcription.
The expression of developmentally regulated genes changes as an organism develops.
Structure
 The
Three-Dime
nsional
Structure of
DNA

James Watson and Francis Crick deciphered the physical structure of DNA in 1953.
Watson and Crick won the Nobel Prize for discovering that DNA is built from two
helically wound polynucleotides (the double helix).
 DNA’s Structure Explains Its Function

Base pair is the term for two
nitrogenous bases held together
by hydrogen bonds in a DNA
molecule.

Base-pairing rules, first proposed
by Watson and Crick, state that a
base on one strand of DNA pairs
exclusively with a corresponding
base on the other strand,
resulting in two complementary
stands of DNA.
 DNA Stores Information
in the Order of the Bases
in the Polynucleotide
Chain
Differences in DNA sequences
account for genetic variation.
One gene is different from
another gene because the two
have a different DNA sequence.
The same gene may have a
slightly different sequence
between two individuals of the
same species, and is likely to be
yet more variable between
different species.
Replication
 DNA Replication Is
Semiconservative
DNA replication
involves unwinding a
DNA double helix and
using each strand as a
template for a new,
complementary strand.
The replication is
semiconservative
because one “old”
strand (the template
strand) is retained, or
conserved, in each new
double helix. 5’ -> 3’
 Few Mistakes Are Made in DNA Replication
DNA polymerase is the enzyme
that connects nucleotides to
make the new strand, using the
old strand as the template.
DNA polymerase proofreads as
it links nucleotides; mismatches
are detected, removed, and
replaced with a 1 in 11 million
error rate.
Cells contain special DNA repair
proteins that correct 99 percent
of any base pair mismatches not
caught by DNA polymerase.
 DNA Replication
DNA replication starts at the origin of replication
(ori). An AT rich region of nucleotides.

One strand serves as a template for the production
of a second strand

Topoisomerase (gyrase) relax the strands

Helicase separates the strands

A replication fork is created (or replication bubble)
 DNA Replication
DNA polymerase adds nucleotides to the growing
DNA strand
– In the 5‘ 3' direction
– Initiated by an RNA primer
– Leading strand is synthesized continuously
– Lagging strand is synthesized discontinuously,
creating Okazaki fragments
– DNA polymerase removes RNA primers; Okazaki
fragments are joined by the DNA polymerase and
DNA ligase
Table 8.1 Important Enzymes in DNA
Replication, Expression, and Repair

https://www.youtube.com/watch?v=TNK
WgcFPHqw
Figure 8.5 A Summary of Events at the DNA
Replication Fork
REPLICATION

Proteins stabilize the The leading strand is
unwound parental DNA. synthesized continuously
by DNA polymerase.
3'

DNA polymerase 5'
Enzymes unwind and unzip the
parental double
helix.

Replication
fork

RNA primer
Primase
5'
DNA polymerase
3'
Okazaki fragment DNA ligase
Parental 3'
DNA
strand polymerase
5'
The lagging strand is DNA polymerase DNA ligase joins
synthesized discontinuously. digests RNA primer the discontinuous
Primase, an RNA polymerase, and replaces it with DNA. fragments of the
synthesizes a short RNA primer, lagging strand.
which is then extended by
DNA polymerase.
 DNA Replication
Energy Needs
– Energy for replication is supplied by nucleotides
– Hydrolysis of two phosphate groups on ATP
provides energy
Most bacterial DNA replication is bidirectional
Each offspring cell receives one copy of the DNA
molecule
Replication is highly accurate due to the proofreading
capability of DNA polymerase
 Figure 8.4 Adding a Nucleotide to DNA
New Template
Strand Strand

Sugar

Phosphate

When a nucleoside triphosphate Hydrolysis of the phosphate bonds
bonds to the sugar, it loses provides the energy for the
two phosphates. reaction.
Organization
 A Closer Look at Genome Organization

PROKARYOTES EUKARYOTES

Size and organization of Several million base pairs in a single Hundreds of millions to billions of base pairs
the genome chromosome. distributed among two to many
chromosomes.
Noncoding DNA Very little; most DNA codes for Large amount, found both within genes and
proteins. between genes.
Organization of genes Commonly organized by function; Genes with related functions may be found
genes for a particular pathway tend distant from one another, even on other
to be clustered together. chromosomes.

A bacterium contains one circular chromosome made up of several million base pairs of
DNA.
Prokaryotic genes tend to be organized by function.
Eukaryotes in general are structurally and behaviorally more complex than prokaryotes and
have larger genomes.
Eukaryote DNA contains large amounts of noncoding DNA; prokaryotes rarely contain
noncoding DNA.
 Genes Constitute Only a Small Percentage
of the DNA in Most Eukaryotes

Noncoding DNA is DNA that does not code for any kind of functional RNA.
Noncoding DNA that separates one gene from another is called spacer DNA.
Transposons are sequences that can move from one position on a chromosome to another,
or even from one chromosome to another, and may disrupt a gene’s function in the process.
Introns are noncoding sections interspersed with the coding regions of a gene or exons.
 Eukaryotic DNA Is
Highly Compacted
Eukaryotic cells must use
packaging proteins to compress a
large amount of genetic
information into each
chromosome.

Short lengths of DNA are wound
around histone proteins to create
a bead-on-a-string structure that
is further compressed into a
looped, 30-nanometer fiber.

During cell division, DNA
condenses into shorter, thicker
chromosomes, the highest level of
packing a chromosome can
acquire.
Class Quiz, Part 2
What is the percentage of adenines (A) in a DNA
double helix in which 30 percent of the nitrogenous
bases are guanine (G)?

A. 20 percent
B. 23.3 percent
C. 30 percent
D. 40 percent
E. 70 percent
 Class Quiz, Part 3
In about 5 minutes, 23 students at Medaille
College squeezed themselves into this
Volkswagen Beetle, during their annual
“Stuff the Bug” event. Each student’s
genome achieves an equally impressive
feat. Which of the statements below is
TRUE?

A. The eukaryotic genome has more noncoding DNA than does the
prokaryotic genome.

B. The prokaryotic genome is larger, on average, than the eukaryotic genome.

C. Prokaryotes have more genes on average than single-celled eukaryotes.

D. Humans have the largest genomes because humans are the most complex species.
Class Quiz, Part 4
DNA repair is
A. important only during replication.
B. found in eukaryotes but not in prokaryotes.
C. vital to maintaining DNA’s integrity.
D. an inherited disorder.
 11.1 Concept Check, Part 1

1. What is gene expression?

ANSWER: Gene expression consists of the processes
by which a gene produces a phenotype. For
protein-coding genes the gene’s DNA is transcribed into
mRNA, mRNA is translated into protein, and protein
function produces a phenotype.
 11.1 Concept Check, Part 2

2. Is the genome of your neurons (nerve cells)
identical to that of your liver cells?

ANSWER: Yes. All cells in the body have essentially the
same DNA-based information, or genome.
 11.1 Concept Check, Part 3
3. We have at least 21,000 protein-coding genes. Are all of
these genes expressed in each of your neurons (nerve
cells)?

ANSWER: No. A unique subset of the approximately
21,000 protein-coding genes is expressed in each cell
type.
 11.2 Concept Check, Part 1
1. If one strand of a DNA molecule has the sequence
ATATCTAT, what is the sequence of its complementary
strand?

ANSWER: A bonds with T, and C bonds with G.
Therefore, the sequence of the complementary strand
is TATAGATA.
 11.2 Concept Check, Part 2
2. What is the percentage of thymine (T) in a DNA double
helix in which 20 percent of the nitrogenous bases are
guanine (G)?

ANSWER: 30 percent (if G = 20 percent, C = 20
percent. When G + C = 40 percent, then A + T = 60
percent; therefore T = 30 percent)
 11.2 Concept Check, Part 3

3. If all genes are composed of just four
nucleotides, how can different genes carry
different information?

ANSWER: The information encoded by a gene is
determined by the precise sequence in which the four
nucleotides are arranged; changing the nucleotide
sequence changes the information. Because genes can
differ in the total number of nucleotides, they can vary
in length as well.
 11.3 Concept Check, Part 1

1. What key function is performed by DNA
polymerase? Where is this enzyme found in
eukaryotic cells?

ANSWER: DNA polymerase catalyzes the formation of
a polynucleotide strand complementary to a template
DNA strand. It is localized in the nucleus in eukaryotic
cells.
 11.3 Concept Check, Part 2

2. What is meant by the “semi” in
semiconservative replication?

ANSWER: “Semi” means that one strand (or half) of
each newly synthesized DNA double helix comes from
the original parent DNA.
 11.4 Concept Check, Part 1

1. What mechanisms reduce the chance of DNA
mutation? Are these mechanisms 100 percent
effective?

ANSWER: Proofreading by DNA polymerase and the
DNA repair system reduce the chance of mutation.
Neither mechanism is 100 percent effective.
 11.4 Concept Check, Part 2

2. What are the key steps in DNA repair?

ANSWER: There are three key steps: (1) recognition of
the damaged strand, (2) removal of the damaged DNA,
and (3) replacement of the removed DNA with a newly
synthesized segment.
 11.5 Concept Check, Part 1
1. Each human cell contains over a thousand times as much
DNA as an E. coli bacterium has. Do we have over a
thousand times as many genes as E. coli has? Explain.

ANSWER: No. Humans have only about 5.6 times as
many genes as E. coli has. We have more DNA
because we have a large amount of noncoding DNA.
 11.5 Concept Check, Part 2

2. Is all noncoding DNA useless “junk DNA”?

ANSWER: No. Noncoding DNA can regulate gene
expression, have structural functions, and serve as a
connector (intron) between segments in a single gene.
However, the function of most noncoding DNA is
unknown.
 11.6 Concept Check, Part 1

1. Which is a more compact form of DNA: the
beads-on-a-string configuration or the
30-nanometer fiber?

ANSWER: The 30-nanometer fiber
 11.6 Concept Check, Part 2

2. What is the functional value of the roughly
twofold greater condensation that chromosomes
undergo during prophase of mitosis or meiosis?

ANSWER: The increased condensation reduces the
chance that the chromosomes will become entangled
and break while being separated into different daughter
cells.
 11.7 Concept Check, Part 1

1. What is the adaptive value of gene
regulation?

ANSWER: Gene regulation ensures that genes are
expressed only when and where they are needed,
preventing waste of resources. It also enables
organisms to turn genes on or off to better cope with a
changing environment.
 11.7 Concept Check, Part 2

2. How are housekeeping genes different from
regulated genes?

ANSWER: Unlike regulated genes, housekeeping
genes provide essential functions and are therefore
kept on all of the time in almost all cell types.