Molecular Genetic Techniques Notes - Burman University

Summary

These notes provide an overview of molecular genetic techniques, including various types of mutations and their effects. They also discuss the use of recombinant DNA technology and various molecular biological techniques in different scientific fields. The notes are primarily for an undergraduate level biology course.

Full Transcript

Molecular Genetic Techniques
Learning Objectives. After completing this chapter on Molecular Genetic Techniques, you
will be able to:
1. Name the different types of mutations that occur in DNA, and how these nucleotide
mutations can lead to alterations at the protein level.
2. Describe how recombinant DNA technology is used to identify, clone, express and study
(by the inactivation of) genes.
3. Describe the principles, methods, and applications of Northern, Southern, Western blot,
microarray, PCR, DNA sequencing, and other molecular biological techniques, for
biological, clinical, and forensic sciences.

Textbook: Molecular Genetic Techniques, Chapter 6, Lodish et al.

Verse: Genesis, Ch 1 and 2.

The creation of life by God is described in Genesis 1 and 2. The natural biological laws
of human reproduction ensures that human lives continue. Cloning is the transfer of genetic
material, in some cases, to create life, by unnatural and artificial means. This chapter discusses
the many molecular tools to achieve cloning.

The subject of human cloning and issues that arise from this technology have prompted
several Christian denominations, including the Seventh-day Adventist (SDA) Church, to outright
condemn it - “Given our present state of knowledge and the current refinement of somatic cell
nuclear transfer, the use of this technique for human cloning is deemed unacceptable by the
Seventh-day Adventist Church. Given our responsibility to alleviate disease and to enhance the
quality of human life, continued appropriate research with animals is deemed acceptable.” (the
complete document is available at https://www.adventist.org/articles/ethical-considerations-
regarding-human-cloning/)

However, it has also left the door opened for “therapeutic cloning”. What do you think?
That is a good question to ask yourself. To help you, I will direct you to an article written by two
of my teachers at Loma Linda University, who have guided a lot of my thoughts on human
cloning. Here I quote them “God endowed human beings with intelligence and creativity and
gave us responsibility to cooperate with him in the care of the planet and all its creatures. He
intends for us to grow in our understanding of the principles of life, including the function of our
bodies. Ethical research and examination can only increase our appreciation of God's wisdom
and goodness. ….. Within the medical realm, we are powerfully driven to control disease—
conditions that disrupt the order and harmony that God intended. We are invited to use the
knowledge he gives us. Consequently, gene therapy need not be an expression of human pride or
arrogance. As long as the aim is to alleviate suffering, and we use our creativity with purpose,
courage, caution, contingency, and compassion, keeping in mind the protection of the
defenseless and helpless, genetic medicine has the same moral justification as traditional
medicine. On the other hand, an attempt to redesign ourselves into creatures with new and

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superlative powers would be perilous. A balanced view of our God-likeness should remind us
that we tamper with fundamental human attributes at great risk.” (Anthony J. Zuccarelli and
Gerald Winslow, 2002. The Test of Human Cloning. Spectrum, Vol. 30, pp. 25-40.)

A lot to think about!

5.1 Genetic Analysis of Mutations to Identify and Study Genes

§ Widely accepted strategies are
used to relate genes to their
function, genomic location, and
structure of gene products. All
utilize common molecular
biological/genetic techniques but
have different starting points
(F6-1):
1. In classical genetics, a
mutant organism is first
isolated to facilitate gene
cloning from a genomic library, or from specific amplification of genomic DNA.
Once the gene is cloned, it is used to produce the encoded protein for biochemical
analysis.
2. Or, a purified protein with observable biochemical activity is first used to identify
and isolate a gene.
3. Lastly, from a genomic sequence database (from completely sequenced genomes of
organisms), sequence analysis leads to the identification of a protein-coding
sequence. This putative gene can also be used to produce a purified protein.
Additionally, if the gene sequence is confirmed to be a protein-coding sequence, it
can be inactivated by various techniques and used to generate mutant cells or
organisms.
§ An organism’s genotype is its entire set of genes and may denote whether an individual
carries mutation(s) in one or more genes. An organism’s phenotype is its function and
physical appearance and depends on that individual’s genotype.

§ Mutations are alterations in DNA sequences that result in changes in the structure of a
gene.
– Normal (wild type) organisms may develop mutations in their DNA sequence
thereby altering their genotype and perhaps their phenotype.
– Organisms that develop such mutations are termed “mutants”.
– A mutation with a change in a single base generally affects the function of one gene.
– At the DNA level, these single base changes result in:
1. Transitions – purine replaced by a different purine, or pyrimidine replaced by a

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different pyrimidine.
2. Transversion – purine replaced by a pyrimidine, or pyrimidine replaced by a
purine.
3. Indel – addition or deletion of one or more base pairs of DNA
– At the protein level, point mutations lead to:
1. Synonymous or silent – no change in the amino acid sequence or activity of a
gene’s encoded protein (i.e., alternate codon specifies the same amino acid).
2. Missense – conservative (codon specifies chemically similar amino acid) or
nonconservative (codon specifies chemically dissimilar amino acids)
substitutions.
3. Nonsense – codon signals chain termination.
4. Frameshifts – one-base-pair addition or one-base-pair deletion.
§ While most mutations in noncoding sequences may not be detrimental, it can affect gene
expression if the mutated sequence is involved in gene control.
§ Spontaneous mutations (e.g., frameshifts) can occur during DNA replication.
§ Spontaneous mutations may also result from chemical instability of purine and
pyrimidine bases, or from exposure to UV light or chemical carcinogens. For example,
scientists often induce of point mutations by treatment of experimental organisms with
EMS (ethyl methyl sulfoxide; a chemical mutagen), or exposure to ionizing radiation.
§ Chromosomal mutations or abnormalities are large scale changes in chromosomal
structure that can affect several genes. These are inversions, deletions or insertions, and
translocations.

§ Haploids and diploids
– A haploid organism has a single copy of each chromosome, and its phenotype is a
consequence of that one copy.
– A diploid organism has two copies of each chromosome and thus two copies of each
gene.
§ Alleles in a diploid organism
– The two copies of each gene may be the same, or the copies may be different.
Different forms of each gene are termed alleles.
– Diploids that carry identical alleles are termed homozygous.
– Diploids that carry different alleles are termed heterozygous.

§ The phenotypic expression
of alleles in diploid
organisms is dependent
whether the alleles are
recessive or dominant (F6-2).
– Recessive mutations lead to a loss of function mutation, which is masked if a normal
allele of the gene is present.
– For mutant phenotype to occur, both alleles must carry the mutation.
– Such mutations may remove part of the gene or the entire gene from the
chromosome, disrupt expression of the gene, or alter the structure of the encoded
protein, thereby altering its function.
– Dominant mutations usually result in a gain of function mutation.

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– Mutant phenotype in the presence of a normal copy of the gene is observed.
– In a gain of function mutation, this mutation may increase the activity of the
encoded protein, confer a new function on it, or lead to its inappropriate spatial or
temporal pattern of expression.
– A dominant mutation could also result in a loss of function mutation.

§ A haploinsufficient gene requires both alleles for normal function.
– Removing or inactivating a single allele in such a gene leads to a mutant phenotype.
– Some alleles can exhibit both recessive and dominant properties, e.g., Hbs.
Homozygous Hbs/Hbs individuals suffer from sickle-cell anemia but heterozygous
Hbs/Hba individuals do not, i.e., Hbs is recessive for the trait of sickle-cell anemia.
However, heterozygous Hbs/Hba individuals are more resistant to malaria than
homozygous individuals, i.e., Hbs is dominant for the trait of malaria resistance.

§ Segregation of Mutations
– Dominant and recessive mutations
exhibit characteristic segregation
patterns in genetic crosses (F6-4).
– Random segregation occurs during the
first meiotic division yielding daughter
cells with different mixes of paternal and
maternal chromosomes.

§ Mitosis and Meiosis (F6-3).
– Somatic cells divide by mitosis.
– A diploid cell undergoes one DNA replication and two cell divisions.
– The members of each pair of homologous chromosomes segregate independently
during meiosis, leading to the random assortment of maternal and paternal alleles
in the gametes.

§ Genetic Screens
– The procedures used to identify and isolate mutants are termed “genetic screens”.
– The screen used depends on whether the organism is haploid or diploid.
– If diploid, the screen used also depends on whether the mutation is dominant or
recessive.
– Crosses between haploid cells can determine
whether a mutant allele is dominant or recessive
(e.g., segregation of alleles in yeast, F6-5).

§ Conditional Mutations
– A mutation that has the wild-type phenotype under
certain (permissive) environmental conditions and
a mutant phenotype under restrictive, or non-
permissive, conditions.
– Screens with haploid organisms can involve
temperature-sensitive (ts; or conditional) mutants,

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e.g., in haploid yeast, Drosophila and C. elegans, temperature-sensitive mutants are
particularly useful for identifying and studying genes essential for survival.
– When ts mutants are maintained at permissive temperature, the mutant phenotype is
not observed. Then for analysis, a subculture is incubated at the nonpermissive
temperature where the mutant phenotype is observed. For example, ts genetic screen
used to identify cell cycle mutants in yeast [F6-6a].
– ts mutants cannot be isolated in warm-blooded animals

§ Complementation Analysis
– Used to determine whether different
recessive mutations, associated with
the same phenotype, are on the same
gene.
– Complementation is the restoration of
wild-type phenotype by mating of two
different mutations.
– For example, in F6-7, if recessive
mutations X and Y are in the same
gene, then a diploid heterozygous for
both mutations (i.e., carrying one X allele
and one Y allele) will exhibit the mutant
phenotype because neither allele
provides a functional copy of the gene.
– However, if recessive mutations X and
Y are in separate genes, then
heterozygotes carrying a single copy of
each mutant allele will exhibit the wild-
type phenotype because a wild-type
allele of each gene will also be present
(i.e., mutations are said to complement each other).

§ Ordering of Genes involved in Biosynthetic and Signaling Pathways
– The order in which genes function in either a biosynthetic or signaling pathway can
be deduced from the phenotype of double mutants defective in two steps of the
affected process.
– i.e., in the genetic dissection of pathways, a double mutant, with successive enzymes
mutated, will clearly accumulate the
intermediate immediately preceding
the earlier step catalyzed by the wild-
type proteins (F6-8a).
– Double-mutant analysis is possible if
two mutations, affecting the same
process, have opposite effects on
expression of a reporter gene. The observed phenotype of the double mutant provides

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information about the order in which the
proteins act and whether they are positive or
negative regulators (F6-8bc).

§ Suppressor Mutation
– A suppressor mutation is one that reverses
the phenotypic effect of a second mutation,
i.e., a “compensatory” mutation.
– Can be used to identify genes encoding
interacting proteins, e.g., observation that
double mutants with two defective proteins
(A and B) have a wild-type phenotype but
that single mutants give a mutant phenotype
indicates that the function of each protein
depends on interaction with each other (F6-9a).

§ Synthetic Lethal Mutations
– Produces a phenotype opposite that of suppression, i.e., the deleterious effect of one
mutation is greatly exacerbated (rather than suppressed) by a second mutation in
the same or related gene.
– Can be used to reveal whether proteins interact
with each other or if they are redundant (i.e.,
proteins with the same function).
– Observation that double mutants have a more
severe phenotypic defect than single mutants
also is evidence that two proteins (e.g., subunits of
a heterodimer) must interact to function normally
(F6-9b).
– Observation that a double mutant is nonviable, but
the corresponding single mutants have wild-type
phenotype indicates that two proteins function in
redundant pathways to produce an essential
product (F6-9c).

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5.2 DNA Cloning and Characterization

§ DNA cloning permits scientists to prepare large numbers of identical DNA molecules.
§ A variety of techniques, often referred to recombinant DNA technology, are used in
DNA cloning.
§ Recombinant DNA is simply any DNA molecule composed of sequences derived from
different sources.
§ Two important discoveries in the 1970’s ushered in the era of DNA cloning, allowing one
to "cut and splice" or recombine DNA, (hence, recombinant DNA technology):
1. Restriction endonucleases – “scissors” that cut DNA at specific sites.
2. DNA ligase – enzymatically joins 2 DNA fragments together.

§ In a typical DNA Cloning Scheme, steps:
1. Recombinant DNA molecules are formed in vitro by inserting DNA fragments of
interest into vector DNA molecules.
2. “Recombined” DNA is introduced into host cells, where they replicate, producing
large numbers of recombinant DNA molecules including the original DNA fragment.
3. Recombinant DNA molecules are isolated, sequenced and manipulated after it is
purified in large quantities.
4. Cloned DNA is used in experiments, e.g., structure-function studies.

A. Restriction endonucleases (RE)
Bacterial enzymes that recognize specific 4- to 8-bp sequences, called restriction
sites, cleaving both DNA strands at this site.
Endonucleases cleave DNA within the molecule, exonucleases digest nucleic acids
from an end.
RE sites are inverted repeats (palindromic), i.e., restriction-site sequence is the same
on each DNA strand when read in the 5’ à 3’ direction.
e.g., for the EcoRI site (F6-11)
5’-GAATTC-3’
3’-CTTAAG-5’
Most leave “sticky ends” or self-complementary
single-stranded tails with 5’ overhangs or 3’
overhangs (e.g., EcoR1 digestion leaves 5’-
overhangs).
Some result in blunt (or flush) ends in which all the
nucleotides at the fragment ends are base-paired, e.g., SmaI.
RE's were discovered first in bacteria where they functioned to destroy (or restrict)
incoming foreign DNA.
RE Sites and Cut Frequency
§ The frequency a RE cuts DNA depends on the length of the restriction recognition
site.
§ If the RE recognizes a 4-bp site, then it will cleave DNA an average of once every
44, or 256, base pairs. One that recognizes an 8-bp sequence will cut DNA once
every 48 base pairs, or ~ 65 kb (4n, where n is length of recognition sequence, and
4 for the four possible bases - A, T, G and C).

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§ Often, these RE enzymes are named after the microorganism source (e.g.,
EcoRI form E. coli; HindIII from Haemophilus Influenzae strain D).
How do bacteria prevent their own REs from destroying their DNA?
§ Host DNA is protected by a modification of its
own DNA.
§ Modification enzymes, recognizing the same
sites as the REs, methylate some of the
nucleotides (A or G) inside that restriction site
(right fig, old text).
§ This prevents the RE from cutting at a modified
RE site. This is called the restriction-
modification system.
– Because DNA isolated from an individual
organism has a specific sequence, REs cut the DNA into a reproducible set of
fragments called restriction fragments. For example, in the fig (old text) below, the
AD2 viral genomic DNA is digested with two different enzymes (EcoR1 and HindIII)
that creates different restriction fragments.

B. DNA Ligase
– Catalyzes formation of 3’à5’ phosphodiester bonds
between Okazaki fragments (in DNA replication).
– Used to covalently link restriction fragments, DNA
ligase requires a 3’-OH group at one end and a 5’-
phosphate, along with ATP to fuel the enzyme.
– Fragments that are “cut” with the same enzymes
(compatible ends) are easily ligated. Blunt-end
ligations require more DNA (100-1000 × higher).
– To use DNA ligase to join incompatible ends,
overhangs are first “filled-in”, or removed, to get
blunt ends.
– e.g., "filling-in" a 5' overhang can be done with
Klenow (DNA polymerase lacking 3'à5'
proofreading) to make a blunt end. The two blunt
ends are then ligated.

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C. Plasmid vectors
– Plasmids are circular, extra-chromosomal, self-
replicating dsDNA molecules (F6-13).
– Plasmids occur naturally in bacteria and lower
eukaryotes (e.g., yeast), existing in a parasitic or
symbiotic relationship with their host cells.
– E. coli plasmids are commonly engineered for use
as cloning vectors (usually small, ~3 kb, with all
nonessential genes removed).
– Important components of a plasmid:
1. Replication origin (ORI)
Specific region of 50-100 bp that must be present for plasmid DNA to
replicate.
Once DNA replication has begun, any foreign DNA in the plasmid will be
replicated.
2. Drug resistance gene(s)
Selectable gene/marker placed into a plasmid to select for bacteria harboring
this plasmid.
Most used is b-lactamase, which inactivates
ampicillin (ampr). Others: tetr (tetracyclin) or kanr
(Kanamycin) resistances.
Some plasmids may contain more than one drug
resistance gene.
3. Polylinker or multiple cloning site (MCS)

Made from synthetic oligonucleotides composting of
one copy each of several different restriction sites (not normally found in
the vector).
Many RE sites permits cloning of restriction fragments generated by cleavage
of DNA with different REs.

REs and DNA ligase allow the splicing of DNA fragments
into cloning vectors (right top fig, old text).

D. Transformation
Genetic alteration of a cell caused by the uptake and
expression of foreign DNA.
After pretreatment of bacteria with CaCl2 or RbCl2, cells
become competent (i.e., able to take up DNA). Typically, 1
out of 10,000 cells become competent, incorporating a single
plasmid and thus becomes transformed.
Finally, select for transformed bacteria, carrying the
antibiotic-resistance gene, on an agar plate with antibiotics
(F6-14).

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E. Other Cloning Vectors
– Plasmid vectors are relatively simple to use but limited by insert fragment size (20
kb maximum) and transformation efficiency.
– Transformation efficiency also decreases as
plasmid size increases.
l Phage Structure
– l Phage Vectors
Bacteriophage l vectors can take inserts up to – Contains
DNA
25 kb, permitting the efficient construction of – Infection
large DNA libraries. of host
cell
Infection of E. coli host cells by l-phage
occurs at ~1000-fold greater
frequency than transformation
(theoretically, need only one virus to
infect a cell, and thus transform a cell).
The genes for lysogenic growth are
removed, leaving space for the inserted
genes (right fig, old text).

– Cosmids
A cosmid (cos sites + plasmid = cosmids) is a type of hybrid plasmid that
contains a l phage cos sequence required for the packing of l DNA. Basically, a
circularized version of a l cloning vector.
Cosmids vectors are designed to clone large fragments of DNA (~ 40-50 kb).
The vector can be carried in a l phage (thus, all the advantages of a l phage) or
grown in a bacterial host as a circularized plasmid.

– BACs/YACs/HACs
Acronyms mean bacterial artificial chromosome,
yeast artificial chromosome and human artificial
chromosome, respectively.
These vectors contain selectable markers and ori
(as in regular plasmids) but additionally contain
CEN (centromeric; required for mitotic
segregation) and TEL (telomeric; required for the
replication and protection of the ends in linear
DNA sequences) sequences, e.g., pYAC3
(Pearson Publishing, 2012).
A restriction site(s) is used to insert the DNA fragment for cloning.
These vectors can carry large, megabase-
sized DNA fragments.
These mini-chromosomes behave as stable
chromosomes that are independent from
the chromosomes of host cells (e.g., HAC
from https://igtrcn.org/tool-for-making-
synthetic-chromosomes/).
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– Shuttle Vectors
Most vectors are propagated in one host type.
Shuttle vectors are those capable of propagation in
two different hosts.
e.g., Shuttle vectors that replicate in both yeast and
E. coli can be used to construct a yeast genomic
library (F6-15).
The vector contains the basic elements (ORI, ampr
and polylinker)that permit the cloning of DNA
fragments in E. coli.
The presence of a yeast origin of replication (ARS)
and a yeast centromere (CEN) allows stable
replication and segregation in yeast.
A yeast selectable marker, URA3 (enzyme for uracil
synthesis), which allows a ura3- mutant host
harboring the vector to grow on medium lacking
uracil.

F. DNA Libraries
1. Genomic Libraries
A set of l, or plasmid, clones that collectively
contain every DNA sequence in the genome of a
particular organism.
Nearly complete genomic libraries of higher
organisms can be prepared by l cloning (right fig,
old text).
A haploid human genome (3 x 109 bp) requires
~150,000 l phages.
2. cDNA Libraries
cDNA libraries
are made from
complimentary
DNA (hence, cDNA), reverse transcribed
from mRNA (i.e., reverse transcriptase
makes a DNA copy using an mRNA
template; F6-17).
A cDNA library represents all the mRNA
expressed in a cell type.
cDNA libraries, unlike the genomic library,
lack introns.
cDNA library should contain 106 – 107
individual recombinant clones to ensure
slowly transcribed genes are included in
these clones.

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G. Screening DNA Libraries
Two approaches are taken to isolate (or screen for) a DNA clone encoding a protein
of interest from a collection of different clones, such as a genomic library or a cDNA
library:
1. Detection by amplification of a specific DNA sequence with the polymerase
chain reaction (PCR; see section H).
2. Detection based on functional complementation of the encoded proteins.
§ Specific genes can be isolated by their ability to complement the
corresponding mutant genes in
yeast cells.
§ i.e., only yeast colonies that carry
recombinant plasmids expressing a
copy of the wild-type copy of a
mutated gene will be able to grow.
This vector-borne wild-type gene
complements, or reverses, the
mutant phenotype (F6-16).
Screening relies on several chemicals and
background concepts:
1. Use of Oligonucleotides in molecular biology.
a) Primers (~20 n’tides) are DNA sequences used for sequencing, PCR, and
site-directed mutagenesis.
b) Probes (> 20 n’tides) are short DNA/RNA sequences for probing/screening
cDNA libraries, Southern Blots, etc.
c) Synthesis of completely synthetic DNA (e.g., poly linker or MCS has the
sequences of many restriction enzymes and are usually around 50-150 n’tides
long).
§ The synthesized ssDNA (i.e., single-stranded DNA) is chemically identical
to, and can be substituted for native DNA.
§ DNA is synthesized in the 3’à 5’direction (in vivo DNA replication is 5’
à 3’).
§ Automated machines called DNA synthesizers are used at a cost of <
$1/base.
§ Oligonucleotide probes, to be synthesized, can be designed from
information provided by protein
sequencing or homology searches
(i.e., sequence alignments) of
genetic databases.
§ Since the genetic code is redundant,
an amino acid may be coded by
several codons, thus, to obtain a
probe for with all the possible
sequence iterations, a degenerate
probe is created that is a mixture of
all possible DNA sequences that
encode the determined amino acid

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sequence. This ensures that the probe mixture contains the one sequence
exactly complementary to the gene of interest (fig above, old text).
§ For some procedures, the oligonucleotide is labelled with a radioactive
(e.g., 32P-labeled phosphate), or fluorescent (e.g., fluorescein, rhodamine,
etc), molecule for detection of the probe.

2. Nucleic Acid Hybridization
§ Hybridization is the ability of single-stranded DNA or RNA molecules to
associate (or hybridize) specifically with complimentary DNA/RNA via
base pairing (i.e., A=T and Gº C).
§ Denaturation of two strands of complementary nucleic acids can occur due to:
1. a temperature increase, which breaks the H-bonds), or
2. a pH increase (adding NaOH), which disrupts the H-bonding (OH-
competes with bases for H-bonding sites).
§ If these conditions are reversed slowly, the individual H-bonding bases on the
separated ssDNAs have time to find
its complimentary sequence partner
and renature (or reassociate or
anneal) properly.
§ If reversed quickly, the ssDNA will
form “self complementary tangles”
(between complementary bases in
the ssDNA).
§ Temperature is the preferred
method.
§ e.g., Membrane-hybridization assay
detects nuclei acids complementary to an oligonucleotide probe [F5-16, old
text].

3. Gel Electrophoresis
§ Resolves/separate DNA and RNA molecules in a gel matrix
based on size (F5-19a, old text).
§ The mobility of either a ds- or ss-nucleic acid molecule during
gel electrophoresis is inversely proportional to the logarithm
of its length in nucleotides (i.e., the larger the molecule, the
slower the mobility).
§ The size of a DNA molecule of unknown length can be
determined by comparison to the electrophoretic migration of
molecules of known length.
§ Different gels:
a) Polyacrylamide gels are used for separation of nuclei acids
up to 2000 n’tides.
b) Most traditional method, Agarose gels, for fragments 500
n’tides to 20 kb.
c) Pulsed-field gel electrophoresis separates large DNA
molecules – 20 to 10,000 kb.

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§ Fragments separated by gel electrophoresis are visualized using Ethidium
bromide + UV light. The fluorescent dye ethidium bromide intercalates
between DNA bases, increasing intrinsic fluorescence when illuminated with
UV light.

H. PCR
– The polymerase chain reaction (PCR) permits exponential
amplification of a specific segment of DNA from just a single initial
template DNA molecule if the sequence flanking the DNA region
to be amplified is known (F6-18).
– PCR can amplify a specific DNA sequence from a complex mixture
of DNA because the reaction is based on the highly specific
complementary base-pairing of template and primers.
– The two flanking primers, 18-20 nucleotides long, are
complementary to the 3’-end of the target DNA.
– Primers are annealed to the target DNA by a cycle of heating (95 °C)
and cooling (50-60 °C, close to the tm of the primer-template hybrid).
– Uses a heat-stable DNA polymerase (Taq polymerase from
Thermus aquaticus) that can survive up to 95 °C and can extend the
primers at optimal temperatures of 72 °C.
– The products undergo repeated doublings in an exponential fashion
(amplification of 2n, where n is the number of PCR cycles).
– Procedure is a highly sensitive method to detect nucleic
acids, e.g., HIV virus, forensics, etc.
– However, prone to false-positives due to contamination
of DNA sample from exogenous sources.
– PCR is commonly used as a rapid cloning tool for the
direct isolation of specific segments of DNA, either from
genomic or cDNAs libraries (F6-19).
– Alternately, it can be used to generate longer probes for
hybridization-based experiments, tagging of genes by
insertion mutagenesis and mRNA expression profiles
(RT-PCR).
Short primers are first synthesized to flank the target
sequence from which a probe is going to be generated.
PCR probes are usually more efficient for
hybridization because they are usually longer - 100 bp.
Radioactive probes can also be generated when 32P-
labeled dNTPs are included in the PCR reaction.

I. The DNA sequence of cloned DNA fragments can be determined by various DNA
sequencing protocols discussed in the laboratory exercise (see DNA sequencing, L3;
note, you will still be responsible for that content).

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5.3 Using Cloned DNA Fragments to Study Gene Expression

Once you have a cloned piece of DNA fragment, it can be used for several experiments that
can reveal the identity, function, temporal and spatial expression of its gene or gene products.
Here are some common molecular biological techniques to facilitate that.

A. Blotting Techniques
§ Southern blotting can detect a single, specific DNA fragment within a complex mixture
by combining gel electrophoresis, transfer (blotting) of the separated bands to a
membrane, and hybridization with a complementary labeled DNA/RNA probe (F6-24).

§ The similar technique of Northern blotting detects a specific mRNA within a mixture.
§ Expression of a particular gene can be followed by assaying the corresponding
[mRNA] by Northern blotting. The temporal expression of a gene can also be
performed if one is interested in the timing of gene expression in an experimental cell, or
tissue.

B. In Situ Hybridization
§ Northern blotting requires extracting the mRNA from a cell/tissue, which means that
positional information (i.e., the location of cells relation to its neighbors) is lost.
§ In precise studies of gene expression, a
whole or sectioned tissue, or even a
whole organism (e.g., embryo) may be
subjected to in situ hybridization to
detect the (spatial) location of an
expressed mRNA (F6-30).
§ If the detection of minor mRNA species
is required, it may be coupled to a PCR
step that would amplify single or low
copy mRNA in the tissue section. This procedure is sometimes
referred to in situ PCR.

C. DNA Microarrays
§ DNA microarray analysis simultaneously detects the relative
expression of thousands of genes in different types of cells or
in the same cells under different conditions (i.e., complete
transcriptional program).
§ A DNA microarray consist of thousands of individual gene

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sequences (~ 1 kb) bound to closely spaced regions on the surface of a glass microscope
slide. Some DNA microarray slides from different experimental organisms are available
commercially (F6-31b).
§ Typically, total mRNA is isolated from experimental cultures, converted to cDNA
before labelled with a fluorescent dye. If the
experiment requires the differentiation of mRNA
expression in two different conditions (or
developmental stages), the cDNA probes created
from the two different conditions are labelled with
different coloured fluorescent dyes – allowing for
differentiation of the signal (F6-26a).
§ A hybridized cDNA probe is captured by a
complimentary gene sequence on the DNA
microarray, identified by a fluorescent spot – which
indicates the mRNA expression of that
corresponding gene sequence.
§ The intensity of the spot can also indicate the level
of mRNA expression.
§ Several, usually 2 different, coloured probes can be
used simultaneously for the different
conditions/developmental stages. A
“housekeeping” gene is one that is expressed at all
developmental stages of the cell, thus, would result
in probes (of different colour) hybridizing to the
same spot in the DNA microarray.
§ Cluster analysis of the data from multiple
microarray expression experiments can identify
genes that are similarly
regulated under various
conditions (i.e., regions A,
B, C, etc; F6-32).
§ Such co-regulated genes
commonly encode proteins
that have biologically
related functions.

D. PCR-based Assays for Gene Expression
1. Quantitative PCR
Quantitative PCR, or qPCR, or real-time PCR, can
be adapted to estimate copy numbers of a
particular sequence in a sample.
PCR is carried out in the presence of a probe (i.e.,
primer) that emits a fluorescent signal when the
PCR product is present (F9-13a, Lehninger).

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If the sequence of interest is present at higher levels
than other sequences in the sample, the PCR signal
will reach a predetermined threshold faster (F9-
13b, Lehninger).
Reverse transcriptase PCR (that converts mRNA
sequences first to DNA; see below) and qPCR can
be combined to determine the relative
concentration of a particular mRNA concentration
in a cell, hence, monitor gene expression.
2. Reverse Transcriptase PCR (or RT-PCR)
The enzyme reverse transcriptase first converts
mRNA to cDNA, which is then used as a template to synthesize dsDNA (double-
stranded DNA).
PCR primers are then used to amplify the DNA.
Accumulation of a PCR product indicates the presence of mRNA in the original
sample, hence, the expression of the gene for the mRNA. The amount of PCR
product can also be used to estimate the level of gene expression.
3. in situ PCR
Mentioned in section B, an RT-PCR is performed directly on a tissue slice mounted
on a microscope.
The presence of a PCR product in a specific location in the tissue indicate the spatial
expression of mRNA at that location.

E. Expression Vectors
§ Expression vectors derived from plasmids allow the
production of abundant quantities of a protein of interest
once a cDNA encoding it has been cloned.
§ This unique feature of the vectors is the presence of a
promoter fused (i.e., joined) to the cDNA that allows high-
level transcription in host cells (F6-33).
§ Even larger quantities of a
desired protein can be
produced in more
complicated E.coli expression systems where high
transcription is coupled to high translation
systems.
§ Eukaryotic Expression Vectors
– Eukaryotic expression vectors can be used to
express cloned genes in yeast or mammalian
cells.
– Most can also function as shuttle vectors for
cloning procedures in E. coli and expression
purposes in mammalian cells, e.g., Dual
Prokaryotic/Eukaryotic Expression Vector
(many commercially available but here is one
example from Vickers et al.).

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F. Transfection
§ Transfection is a process to introduce cloned genes into cultured animal cells.
§ Cells can be transfected by:
1. Liposome-mediated – DNA is delivered in liposomes
that fused with the cell membranes of animal cells.
2. Electroporation – cells are subjected to a brief electric
shock of several thousand volts that makes them
transiently permeable to DNA.
§ Transient Transfection (F6-34a)
– Plasmid vectors (with viral ORI, polylinker, selectable
marker and mammalian promoter adjacent to the cloned
DNA) are not incorporated into the genome of the
animal cell.
– Production of the cDNA-encoded proteins occur if the
animal cell has the plasmid.
– Over time plasmids are lost from the cells because
the plasmids are not faithfully segregated into
daughter cells (hence, transient transfection).
§ Stable Transfection (F6-34b)
– If an introduced vector integrates into the genome of
the host cell, a stable transfection occurred.
– Since the genome is permanently altered, the cell is
said to be transformed.
– A selectable marker, neor (which provides resistance
to G-418, a chemical related to neomycin), is used to
select for neor after several passages of cell culture when plasmids are lost from host
cells.

G. Retroviral Expression Systems
§ Retroviruses can integrate into host
genomes with high efficiencies.
§ An example of such an expression system
uses a class of retroviruses called the
lentiviruses. Three different plasmids are
introduced into cells by transient
transfection to produce recombinant
lentivirus particles that can efficiently
introduce a cloned gene into target animal
cells (F6-35).
1. Vector plasmid
– The vector plasmid contains the
cloned gene of interest next to a selectable marker such as neor flanked by
lentiviral LTR sequences.
– LTRs are required for integration into host chromosomes of the target cell.
– LTRs direct the synthesis of recombinant viral RNA (i.e., sequence between the
LTRs).

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2. Packaging plasmid
– Carries all the viral genes, except for the major viral envelope protein, necessary
for the packaging of the LTR-containing viral RNA into a functional
lentiviral particle.
– Since it is lacking the viral envelop, this plasmid by itself cannot form an
infectious viral particle.
3. Envelope plasmid
– Plasmid controls the expression of a viral envelope protein which when
incorporated into the recombinant lentivirus results in an infectious hybrid viral
particle.
– Often the envelope protein from vesicular stomatitis virus is used to replace the
lentiviral envelope protein because it would allow the hybrid virus to infect a
wide variety of mammalian cells, including hematopoietic stem cells, neurons,
muscle and liver cells.

H. Fusion Proteins as Tags, Epitopes and Protein
Reporting
§ An important application is the tagging of proteins
with a reporter protein (F6-36), or epitope for
antibody detection, or protein purifications
(bottom fig).
§ These tags are protein domains fused to the protein
of interest. Some of these tags are removed after the
fusion proteins are made (e.g., to facilitate the
purification of a fusion protein).

Purification of
Fusion Proteins

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5.4 Identifying and Locating Human Disease Genes

§ Inherited diseases and other traits in humans show three major patterns of inheritance -
autosomal dominant, autosomal recessive, and X-linked recessive (T6-1; F6-26).
§ Autosome is one of the chromosomes that is not a sex chromosome.
§ Genes located on the same chromosome can be
separated by crossing over during meiosis, thus
producing new recombinant genotypes in the next
generation (F6-10a).
§ Genes for human diseases and other traits can be
mapped by determining their co-segregation with
markers whose locations in the genomes are known.
§ The closer the gene is to a particular marker, the more
likely they are to co-segregate (i.e., they are linked; F6-
10b).
§ Mapping of human genes with great precision requires
thousands of molecular markers distributed along
the chromosomes.
§ The most useful markers are differences in the DNA sequences (polymorphisms)
among individuals in noncoding regions of the genome.
§ DNA polymorphisms useful in mapping human genes include
restriction fragment length polymorphisms (RFLPs), single-
nucleotide polymorphisms (SNPs), and simple tandem repeats
(STRs; 2-4 base repeats).
§ Restriction fragment length polymorphism (RFLP) is a
technique that exploits variations in homologous DNA
sequences to distinguish individuals, populations, or species

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or to pinpoint the locations of genes within a sequence
(F5-36, old text).
§ Single-Nucleotide Polymorphisms (SNPs) can be
followed like genetic markers (Old text; F6-33).
§ SNP and STR polymorphisms can be detected by PCR
amplification and DNA sequencing.
§ Linkage mapping often can locate a human disease
gene to a chromosomal region that includes as many as
10 genes (F6-28).
§ To identify the gene of interest within this candidate region typically requires
expression analysis and comparison of DNA
sequences between wild-type and disease-affected
individuals.
§ Some inherited diseases can result from mutations in
different genes in different individuals (genetic
heterogeneity).
§ The occurrence and severity of other diseases
depend on the presence of the mutant alleles of
multiple genes in the same individual
(polygenic traits).
§ Mapping of the genes associated with these
diseases is particularly difficult because the
occurrence of the disease cannot readily be
correlated to a single chromosomal locus.

5.5 Inactivating the Function of Specific
Genes in Eukaryotes

§ Once a gene has been cloned, important clues
about its normal function in vivo can be
deduced from the observed phenotypic
effects of mutating the gene.
§ Basic strategies are utilized:
1. Replacing a normal gene with other sequence.
2. Introducing an allele whose encoded
protein inhibits functioning of the
expressed normal protein.
3. Destruction of the mRNA
expressed from a gene.
4. Precise gene editing with CRISPR-
Cas9 system.

A. Disrupting Genes in Yeast (F6-37)
– Genes can be disrupted in yeast by
inserting a selectable marker gene

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into one allele of a wild-type gene via homologous recombination, producing a
heterozygous mutant.
– When such a heterozygote is sporulated, disruption of an essential gene will
produce two nonviable haploid spores.

B. “Knockout” Mice
– In mice, modified genes can be incorporated into the germ line at their original
genomic location by homologous recombination, producing “knockouts” (or
gene-targeted knockout).
– Normal in vivo functions of genes can be deduced from the observed effects of
disrupting it.
– Mouse knockouts can provide models for human
genetic disease.
– Step 1: Production of “knockout” mice.
Modified (or mutant) alleles are introduced
by homologous recombination into
embryonic stem (ES) cells. ES cells appear
as the inner cell mass at the blastocyst stage
of development.
Preparation of ES cells carrying a knockout

mutation (F6-37a; Old
text).
Isolation of ES cells
with a gene-targeted
disruption by positive
and negative selection
(F6-37b; Old text).
– Step 2: Selection of
“knockout” mice (F6-38; Old
text).

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The selected ES cells are injected into
blastocoel cavity of early embryo of a mouse
with different coat colour.
Offsprings with chimeric coat colours are
crossed to obtain ES-cell- derived progeny.
– The loxP-Cre recombination system can knock
out genes in one specific cell type (F6-39; Old
text).

C. Transgenic Animals
– In the production of transgenic cells or organisms, exogenous DNA is integrated
into the host genome by nonhomologous recombination (F6-40; Old text).

– Introduction of dominant-negative allele in this
way can functionally inactivate a gene without
altering its sequence (F6-41; Old text).

D. “Knockin” Mouse
– To avoid the problems associated with a standard transgenic mice (i.e., transgene
interrupting a gene), many researchers now rely on knockin mice to study the
exogenous expression of a protein.
– A knockin mouse is generated by targeted insertion of the transgene at a selected
locus. The insert is flanked by DNA from a non-critical locus, and homologous
recombination allows the transgene to be targeted to that specific, non-critical
integration site.
– In this way, a researcher has complete control of the genetic environment
surrounding the overexpression cassette and it is likely that the DNA does not
incorporate itself into multiple locations.
– Site-specific knockins result in a more consistent level of expression of the
transgene from generation to generation because it is known that the
overexpression cassette is present as a single copy.

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– Also, because a targeted transgene is not interfering with a critical locus, the
researcher can be more certain that any resulting phenotype is due to the exogenous
expression of the protein.
– Disadvantage compared to transgenic mice, this procedure requires more time to
assemble the vector and to identify ES cells that have undergone homologous
recombination.

E. RNA interference (RNAi)
– In some organisms, double stranded
RNA triggers the destruction of all
mRNA molecules with the same
sequence, but not that of mRNAs with a
different sequence.
– This phenomenon, known as RNAi,
provides a specific and potent means of
functionally inactivating genes without
altering their structure.
– First, double stranded RNA is created by using sense
and antisense transcripts (F6-42a; Old text), or with a
hairpin construct (F6-42c; Old text).
– The dsRNA is microinjected into a cell to disrupt the
production of the gene in question (F6-42b; Old text).
– A specialized RNA-processing enzymes,
called Dicer, cleave the injected dsRNA into
short fragments, known as small inhibitory
RNAs (siRNAs), which can base-pair with
endogenous mRNA.
– The resulting hybrid molecules are cleaved by
another enzyme complex, called the RISC
complex, thus destroying any mRNA that is complementary to the siRNA.

F. Genome Editing – Site/oligonuleotide-directed Mutagenesis
– In site-directed mutagenesis, a synthetic DNA segment
replaces a fragment removed by REs.
– In oligonucleotide-directed
mutagenesis, a complimentary
oligonucleotide with a specific
sequence change is used to alter
the cloned gene to be altered (F9-
10, Lehninger).

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G. Genome Editing – CRISPR
– The CRISPR (clustered regularly interspersed
short palindromic repeats) mechanism is used by
bacterial cells to protect against foreign DNA such
as phage DNA.
– Adapted to be used in many organisms, cleavage
by CRISPR-Cas9 results in a short deletion at the
cleavage site.
– Cas (CRISPR-associated) 9 is the nuclease
that performs the cleavage.
– A chimeric guide RNA (gRNA) is expressed to
provide the tracrRNA scaffold for binding to
Cas proteins to initiate the cleavage (F6-38).
– The chimeric gRNA includes a target sequence
that guides the Cas nuclease complex to the
specific target through base pairing.
– Cas creates a double strand break at the target
sequence in the genome; when repaired via a
nonhomologous end joining process, the removal
of some nucleotide bases inactivates the gene
(due to a frameshift mutation).
– If an appropriately designed DNA segment
(HDR template – which spans the cleavage
site) is introduced by transfection, specific
DNA changes, such as point mutations, can
be introduced at the cleavage site.

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