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Transcript
Outline: Gene Technology
Central Dogma: DNA Æ RNA Æ Protein
Viruses & bacteria
CONNECTION: Many viruses cause disease in
animals and plants
ƒ Both DNA viruses and RNA viruses cause disease in
animals & plants
ƒ Reproductive cycle of an RNA virus
Mutation
– Entry
Cancer
Gene Splicing and Cloning
– Glycoprotein spikes contact host cell receptors
– Viral envelope fuses with host plasma membrane
PCR
Gel Electrophoresis
– Uncoating of viral particle to release the RNA genome
Biotechnology Applications
– mRNA synthesis using a viral enzyme
Genomics
– Protein synthesis
– RNA synthesis of new viral genome
– Assembly of viral particles
Copyright © 2009 Pearson Education, Inc.
Human Immunodeficiency Virus
• HIV, the AIDS virus
– A retrovirus
Human Immunodeficiency Virus
Glycoprotein spike
Protein coat
Membranous
envelope
VIRUS
Viral RNA
(genome)
Envelope
Glycoprotein
Plasma membrane
of host cell
1
Entry
2
Uncoating
3
RNA synthesis
by viral enzyme
Protein coat
RNA (two
identical strands)
Reverse transcriptase
Viral RNA
(genome)
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
1
Human Immunodeficiency Virus
Viral RNA
CYTOPLASM
1
DNA
strand
NUCLEUS
Chromosomal
DNA
2
Doublestranded
DNA
3
Viral
RNA
and
proteins
5
Provirus
DNA
4
Emerging viruses threaten human health
How do emerging viruses cause human diseases?
¾Mutation
RNA viruses mutate rapidly
¾Contact between species
RNA
Viruses from other animals spread to humans
¾Spread from isolated populations
6
HIV replication animation
Copyright © 2009 Pearson Education, Inc.
Emerging viruses threaten human health
ƒ Examples of emerging viruses
– HIV
– Ebola virus
– West Nile virus
– RNA coronavirus - severe acute respiratory syndrome
(SARS)
– Avian flu virus
10.22 Bacteria can transfer DNA in three ways
ƒ Three mechanisms allow transfer of bacterial DNA
– Transformation is the uptake of DNA from the surrounding
environment
– Transduction is gene transfer through bacteriophages
– Conjugation is the transfer of DNA from a donor to a recipient
bacterial cell through a cytoplasmic bridge (pilus)
ƒ Fate of “new” DNA entering a bacterium
(1) Recombination of the transferred DNA with the host bacterial
chromosome
(2) Uptake of a plasmid (small circular loop of DNA)
Copyright © 2009 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc.
2
Plasmids transfer genes for antibiotic resistance
by conjugation
History of Staphylococcus
antibiotic resistance
Penicillin Æ 1947
Methicillin Æ 1961
Plasmids
Tetracycline Æ ∼1990s
Erythromycin Æ ∼1990s
Mu
ta t
io n
Vancomycin Æ late 1990s
Linezolid Æ 2003
Superbugs: Staphylococcus Æ necrotizing fasciitis
Escherichia coli Æ “hamburger disease”
Streptococcus Æ pneumonia, meningitis
Pseudomonas Æ lung, blood infections
Enterococcus Æ diverticulitis, meningitis
Mutation
Mutation
1. Definition: Change in DNA
2. Frequency:
Mutation = change in the nucleotide sequence of DNA
1 in 50 million base pairs
1 in a million gametes
Why mutation?
1. Spontaneous
errors in DNA replication
errors in DNA recombination
Albino rainbow trout
2. Induced to form by mutagens
High-energy radiation
Chemicals
Blue Trout
White grapes
Seedless navel orange
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
3
Mutation – gene alteration
Mutation: Altered Genes
Point mutations Æ Changes in 1-few nucleotides
Normal gene
Base substitution
mRNA
Protein
mRNA
Protein
A U G A AG U U U G G C G C A
Met
Lys
mRNA
Protein
Ala
Normal
A U G A A G U U U A G C G C A
Met
Lys
Ser
Phe
U
Base deletion
Gly
Phe
Point mutations Æ alter one or a few DNA bases.
What happens when a point mutation occurs?
Silent Æ no change in mRNA codon
Nonsense Æ create stop codon
Frameshift Æ shifts reading of mRNA codons
Ala
Lys
Nonsense
Frameshift
TTAGGCC
DNA
ATG
ATA
ATT
mRNA
UAC
UAU
UAA
Missing
TTAGCGCC
AU G AA G U U GG C G C A U
Met
Silent
Mutation
Leu
Ala
UCG
His
Amino Tyrosine
acid
Base insertion
Tyrosine
Stop
Serine
14
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Examples of Mutation – Sickle Cell Anemia
Examples of Mutation – Cystic Fibrosis
250,000 base pairs
Normal hemoglobin DNA
Mutant hemoglobin DNA
27 Exons + Introns
61,000 base pair mRNA
mRNA
1,480 Amino
Acid Sequence
of CTFR protein
mRNA
Normal hemoglobin
Sickle-cell hemoglobin
Glu
Val
4
Chromosomal mutations
Mutation: Altered Genes
Deletion
Chromosomal mutations change chromosome structure.
deletion Æ part of chromosome is lost
duplication Æ part of chromosome is copied
inversion Æ part of chromosome in reverse order
translocation Æ part of chromosome moves to a new
location
part of chromosome is lost
Duplication
part of chromosome is copied
Inversion
part of chromosome is reversed in order
Translocation
17
Chromosomal Mutations
Transposition = Jumping genes
chromosome segments move/swap places
Chromosomal mutations – Transposons
Chromosome A
Transposon
Chromosome B
Consequences of transposition (48% Human genome = transposons)
1. Cause mutations
2. May disable functional genes
3. May cause cancer by insertion of transposon promoter near
cancer-causing gene
4. Transposon diseases: Hemophilia, SCID, Muscular Distrophy
5. Viruses like HIV behave like transposons
5
Alterations of chromosome structure - Deletion
Reciprocal translocation associated with
chronic myelogenous leukemia (CML)
Chromosome 9
Deletion in
Chromosome #5
Cri du chat Syndrome
Chromosome 5 deletion
1 in 25,000-50,000
Detected by amniocentesis
Mental retardation
May live normal life span but
usually die in early childhood
Chromosome 22
Reciprocal
translocation
“Philadelphia chromosome”
Activated cancer-causing gene
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
DNA Damage and Repair
DNA Damage and Repair
Xeroderma pigmentosa
6
11.18 Cancer results from mutations in genes
that control cell division
THE GENETIC BASIS
OF CANCER
ƒ Mutations in two types of genes can cause cancer
– Oncogenes
– Proto-oncogenes normally promote cell division
– Mutations to oncogenes enhance activity
– Tumor-suppressor genes
– Normally inhibit cell division
– Mutations inactivate the genes and allow uncontrolled
division to occur
Copyright © 2009 Pearson Education, Inc.
11.18 Cancer & Proto-Oncogenes
Cancer & Proto-Oncogenes
Proto-oncogene DNA
Promote cancer when present in a single copy
Can be viral genes inserted into host chromosomes
Can be mutated versions of proto-oncogenes, normal genes
that promote cell division and differentiation
Mutation within
the gene
Multiple copies
of the gene
Gene moved to
new DNA locus,
under new controls
Converting a proto-oncogene to an oncogene can occur by
– Mutation causing increased protein activity
– Increased number of gene copies causing more protein to be
produced
– Change in location putting the gene under control of new
promoter for increased transcription
New promoter
Oncogene
Hyperactive
growthstimulating
protein in
normal
amount
Normal growthstimulating
protein
in excess
Normal growthstimulating
protein
in excess
Copyright © 2009 Pearson Education, Inc.
7
Cancer & Tumor-suppressor genes
Tumor-suppressor gene
Mutated tumor-suppressor gene
Normal
growthinhibiting
protein
Defective,
nonfunctioning
protein
Cell division
under control
Cell division not
under control
Signal
Transduction
Pathways &
Proto-Oncogenes
Signaling cell
1
2
Signaling
molecule
Receptor
protein
Plasma
membrane
3
Target cell
Relay
proteins
Transcription
factor
(activated)
4
Cell
Division
Nucleus
DNA
5
mRNATranscription
New
protein
6
Promote cancer when both copies are mutated
Translation
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Proteins Regulate Cell Cycle
Ras
protein
Cytoplasm
Src
kinase
Rb
protein
Nucleus
p53
protein
Cell cycle
checkpoints
PROTO-ONCOGENES
Growth factor receptor:
more per cell in many
breast cancers.
Ras protein:
activated by mutations
in 20–30% of all cancers.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Activity of Abnormal p53 gene
Benzopyrene
ABNORMAL p53
Abnormal
p53 protein
Src kinase:
activated by mutations
in 2–5% of all cancers.
TUMOR-SUPPRESSOR GENES
Rb protein:
mutated in 40% of all cancers.
p53 protein:
mutated in 50% of all cancers.
Cancer
cell
Step 1
Step 2
DNA
damage
caused by
heat,
radiation,
chemicals.
p53 protein fails to
stop cell division
and DNA repair.
Cell division
continues without
repair.
Step 3
Damaged cells may
turn cancerous if other
mutations appear.
8
Multiple mutations lead to cancer
Cancer in the United States
Cancer
Carcinogens
Cases in
1999
Prostate
Testosterone; dietary fat
179,300
Breast
Estrogen; possibly dietary fat
176,300
Lung
Cigarette smoke
171,600
Colon & Rectum
High dietary fat; low dietary fiber
129,400
Bladder
Cigarette smoke
54,200
Skin
Ultraviolet light
44,200
Kidney
Cigarette smoke
30,000
Mouth and Throat
Tobacco & alcohol
29,800
Pancreas
Cigarette smoke
28,600
Stomach
Table salt; cigarette smoke
21,900
Cervix
Viruses; cigarette smoke
12,800
Mutation of
Tumor
Suppressor
Gene APC
Chromosomes
Normal
cell
1
mutation
Increased
Cell
Division
Mutation of
ProtoOncogene
K-ras
Mutation of
Tumor
Suppressor
Gene DCC
Mutation of
Tumor
Suppressor
Gene p53
2
mutations
3
mutations
4
mutations
Benign
polyp
Benign
polyp
Malignant
Cell &
metastasis
Gene Cloning & Gene Technology
D
EN
9
Gene Technology
Cleaving, Splicing & Cloning DNA
Manipulating DNA – Cleaving, Splicing & Cloning
Restriction enzyme
recognition sequence
Transferring & Storing DNA
DNA
Genetic engineering
Procedures related to gene technology
PCR
DNA Fingerprinting
Restriction enzyme
cuts the DNA into
fragments
Applications of gene technology
Sticky end
Cleaving, Splicing & Cloning DNA
Restriction enzyme
recognition sequence
DNA
Cleaving,
Splicing & Cloning DNA
1
Restriction enzyme
cuts DNA into fragments
DNA from
species A
2
Restriction enzyme
cuts DNA into fragments
3
3
Addition of a DNA
fragment from
another source
Fragments stick
together4 by
base-pairing
DNA from species B
Addition of a DNA
fragment from
Species B
10
Restriction enzyme
recognition sequence
1
DNA
Restriction enzyme
cuts the DNA into
fragments
Cleaving,
Splicing &
Cloning DNA
Cloning a Gene in a Bacterial Plasmid
E.coli
Human cell
DNA
Isolate DNA
1 two sources
from
Cut both DNAs
with same restriction enzyme
Plasmid
2
Sticky ends
Sticky end
Addition of a DNA
fragment from
another source
Mix DNAs;
Join by base-pairing
3
Add DNA ligase to bond the DNA covalently
Fragments stick together
by base-pairing
4
Recombinant DNA plasmid
Recombinant bacterium
DNA ligase
pastes DNA strands
Recombinant
DNA molecule
5
Bacterial clone carrying many
copies of the human gene
Gene of interest
Insert plasmid into bacterium
Clone bacterium
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Cloned genes can be stored in genomic libraries
Cell nucleus
Exon Intron Exon Intron Exon
Genomic library = DNA fragments containing all of an organism’s genes.
Eukaryote DNA
1 Transcription
Constructed & stored in cloned bacterial plasmids or phages.
Genome cut up with
restriction enzyme
Recombinant
plasmid
or
Recombinant
phage DNA
RNA primary
transcript
2 RNA splicing
mRNA
3 Isolation of mRNA
Reverse transcriptase
Bacterial
clone
Plasmid library
Phage
clone
Phage library
cDNA strand
being synthesized
and addition of reverse
transcriptase; synthesis
of DNA strand
4 Breakdown of RNA
5 Synthesis of second
cDNA of gene
(no introns)
DNA strand
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
11
• Recombinant DNA technology
– Can be used to produce new genetic
varieties of plants and animals,
genetically modified (GM) organisms
Agrobacterium
tumefaciens
DNA containing
gene for desired trait
Ti
plasmid
1
Recombinant
Plant cell
2
Plant with
new trait
3
Insert plant geneTi plasmid Introduction
Regeneration
into plasmid using
of plant
Into
restriction enzyme
plant
cells
T DNA
and DNA ligase
Restriction
T DNA carrying new
site
gene within plant chromosome
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Fig. 16.20
Examples of genetically modified (GM) crops
Glyphosate Resistance
1. Cotton
2. Corn
3. Soybeans
4. Canola
5. Wheat
Bt Crops
• Cotton
• Corn
Other engineered crops
1. Papaya
virus resistance
Enhancement of Nutritional Value/Longevity
2. Carnation
longevity
1. Rice
3. Flax
herbicide resistance 2. “Flavr Savr” Tomato
4. Lentil
herbicide resistance
5. Potato
insect resistance
6. Squash
virus resistance
7. Sugar beet herbicide resistance
8. Cucumber virus resistance
9. Watermelon virus resistance
12.11 DNA profiles and Genetic Marker Analysis
ƒ DNA profiling is the analysis of DNA fragments to
determine whether they come from a particular
individual
– PCRÆ
PCR amplification of DNA markers
– Gel Electrophoresis Æ Sizes of fragments are compared
Compares genetic markers from noncoding regions that
show variation between individuals
Copyright © 2009 Pearson Education, Inc.
12
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Polymerase
Chain
Reaction
(PCR)
Gel Electrophoresis
Target sequence
1 copy
1. Heat ÆDenature DNA
Cool
& add primers
1
Cycle
1
Mixture of DNA molecules
Of different sizes
2.2 Add DNA polymerase
& Nucleotides
3 New DNA synthesized
3.
Repeat 1, 2 & 3
4 copies
Longer
molecules
–
–
2 copies
Cycle
2
Repeat 1, 2 & 3
Power
source
Gel
+
+
Completed gel
8 copies
Shorter
molecules
Cycle
3
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
How Restriction Fragments Reflect DNA Sequence
• Restriction fragment length polymorphisms (RFLPs)
Short tandem repeats (STRs) are genetic markers
STRs are short DNA sequences repeated many times in a row at the
same location. Number of STR units differs between individuals.
• Reflect differences in the sequences of DNA samples
STR site 1
STR site 2
Crime scene DNA
Crime scene
Suspect
w
G
Cut C
CG
GC
GC
z
x
y
Number of short tandem Number of short tandem
repeats match
repeats do not match
AT
CG
GC
GC
Suspect’s DNA
G
Cut C
CG
GC
GC
y
CG
Cut C
G
GC
GC
DNA from chromosomes
Figure 12.11A
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
13
Short tandem repeats (STRs) are genetic markers
DNA Fingerprinting
Crime scene DNA
Suspect’s DNA
Crime scene
DNA
Suspect’s
DNA
DNA fragments
separated by
Gel
Electrophoresis
Copyright © 2005 Pearson Education, Inc. Publishing as Benjamin Cummings
Nutritional Deficiencies
Iron
Main component of hemoglobin
Supports energy production enzymes
May have anti-cancer properties
Powerful immune-system booster
Symptoms of Iron Deficiency
Anemia
Tiredness
Sleep problems
Impaired mental / intellectual function
Learning, growth and behavioural disturbances
Frequent infections
Some types of deafness
Nutritional Deficiencies
Vitamin A Roles
•Vision
•Immune defense
•Reducing morbidity of measles
•Reducing respiratory infections
•Cell differentiation and morphogenesis
14
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Genetically Engineered Golden Rice
Beans
Aspergillus fungus
Ferritin gene
is transferred
into rice from
beans.
Fe
Phytase gene is
transferred into
rice from a
fungus.
Pt
Wild rice
Metallothionin
gene is
transferred into
rice from wild
rice.
Rice
chromosome
Ferritin protein Phytate, which
increases iron inhibits iron
content of rice. reabsorption,
is destroyed by the
phytase enzyme.
Daffodil
β-carotene enzyme
Synthesis genes are
transferred into
rice from daffodils.
S
Metallothionin
protein supplies
extra sulfur to
increase iron
uptake.
A1 A2 A3 A4
β-carotene, a
precursor to
vitamin A, is
synthesized.
12.8 CONNECTION: Genetically modified
organisms are transforming agriculture
ƒ Genetically modified (GM) organisms contain
one or more genes introduced by artificial means
ƒ Transgenic organisms contain at least one
gene from another species
ƒ GM plants
– Resistance to herbicides
– Resistance to pests
– Improved nutritional profile
ƒ GM animals
Golden Rice
12.7 CONNECTION: DNA technology has changed the
pharmaceutical industry and medicine
ƒ Products of DNA technology
– Therapeutic hormones
– Insulin to treat diabetes
– Human growth hormone to treat dwarfism
– Diagnosis and treatment of disease
– Testing for inherited diseases
– Detecting infectious agents such as HIV
– Improved qualities
– Production of proteins or therapeutics
Copyright © 2009 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc.
15
12.7 CONNECTION: DNA technology has changed the
pharmaceutical industry and medicine
ƒ Products of DNA technology
– Vaccines
– Stimulate an immune response by injecting
– Protein from the surface of an infectious agent
– A harmless version of the infectious agent
12.7 CONNECTION: DNA technology has changed the
pharmaceutical industry and medicine
ƒ Advantages of recombinant DNA products
– Identical to human protein
– Purity
– Quantity
– A harmless version of the smallpox virus containing
genes from other infectious agents
Copyright © 2009 Pearson Education, Inc.
Copyright © 2009 Pearson Education, Inc.
Table 09.02
Adenosine deaminase deficiency patient
16
12.17 Genomics is the scientific study of whole
genomes
Exons (regions of genes coding for protein
or giving rise to rRNA or tRNA) (1.5%)
ƒ Genomics is the study of an organism’s complete
set of genes and their interactions
– Initial studies focused on prokaryotic genomes
– Many eukaryotic genomes have since been
investigated
ƒ Evolutionary relationships can be elucidated
Repetitive
DNA that
includes
transposable
elements
and related
sequences
(44%)
– Genomic studies showed a 96% similarity in DNA
sequences between chimpanzees and humans
Introns and
regulatory
sequences
(24%)
Unique
noncoding
DNA (15%)
Repetitive
DNA
unrelated to
transposable
elements
(15%)
– Functions of human disease-causing genes have
been determined by comparisons to similar genes in
yeast
Copyright © 2009 Pearson Education, Inc.
12.18 CONNECTION: The Human Genome
Project revealed that most of the human
genome does not consist of genes
ƒ Results of the Human Genome Project
– Humans have 21,000 genes in 3.2 billion nucleotide
pairs
– Only 1.5% of the DNA codes for proteins, tRNAs, or
rRNAs
– The remaining 88.5% of the DNA contains
END
GENE
TECHNOLOGY
– Control regions such as promoters and enhancers
– Unique noncoding DNA
– Repetitive DNA
– Found in centromeres and telomeres
– Found dispersed throughout the genome, related to
transposable elements that can move or be
copied from one location to another
Copyright © 2009 Pearson Education, Inc.
17