Title: Mutations
1- Mutations
- any change in the nucleotide sequence of DNA
- can be single nucleotide or large section
- (ie. many nucleotides) of a DNA molecule
- Types of mutation
- substitutions (changes)
- insertions (additions)
- deletions
2Mutations
- any change in the nucleotide sequence of DNA
Normal hemoglobin DNA
Mutant hemoglobin DNA
mRNA
mRNA
Sickle-cell hemoglobin
Normal hemoglobin
Glu
Val
Figure 10.21
3Types of Mutations
- two general categories
- 1.result in changes in the amino acids in proteins
mRNA
Protein
Met
Lys
Phe
Gly
Ala
(a) Base substitution
Met
Lys
Phe
Ser
Ala
Figure 10.22a
42.Change the reading frame of the genetic message
mRNA
Protein
Met
Lys
Phe
Gly
Ala
(b) Nucleotide deletion
- Disastrous effects
Met
Lys
Leu
Ala
His
Figure 10.22b
5Genotype determines phenotype
6Mutagens
- Mutations may result from
- Errors in DNA replication
- Physical or chemical agents called mutagens
7- Although mutations are often harmful
- They are the source of the rich diversity of
genes in the living world - They contribute to the process of evolution by
natural selection
Figure 10.23
8VIRUSES GENES IN PACKAGES
- Viruses sit on the fence between life and nonlife
They exhibit some but not all characteristics of
living organisms
- 3 categories of viruses
- - bacterial
- - plant
- - animal
9Bacteriophages
- Bacteriophages, or phages
Head
Tail
Tail fiber
DNA of virus
Bacterial cell
Figure 10.25
10- How phages infect bacteria and reproduce
Bacterial chromosome (DNA)
Phage DNA
4
Cell lyses, releasing phages
1
Many cell divisions
7
Lysogenic cycle
Lytic cycle
2
6
Prophage
3
5
New phage DNA and proteins are sythesized
Phage DNA inserts into the bacterial chromosome
by recombination
11Plant Viruses
- Viruses can also infect plants
Protein
RNA
- Can stunt growth and diminish plant yields
- Can spread throughout the entire plant
Figure 10.27
12Animal Viruses
- Molecular genetics helps us understand viruses
- Virus studies help establish molecular genetics
Membranous envelope
RNA
Protein coat
Protein spike
Figure 10.28
13HIV, the AIDS Virus
Envelope
Protein
- A retrovirus is an RNA virus that reproduces by
means of a DNA molecule - It copies its RNA to DNA using an enzyme called
reverse transcriptase
Protein coat
RNA (two identical strands)
Reverse transcriptase
(a) HIV
Figure 10.30a
14- How HIV reproduces inside a cell
Reverse transcriptase
Viral RNA
Cytoplasm
1
Nucleus
Chromosomal DNA
DNA strand
2
3
Provirus DNA
Double-stranded DNA
4
5
Viral RNA and proteins
6
(b) The behavior of HIV nucleic acid in an
infected cell
Figure 10.30b
15- Acquired immune deficiency syndrome
- The disease caused by HIV infection
- Treated with the drug AZT
(c) HIV infecting a white blood cell
Figure 10.30c
16EVOLUTION CONNECTIONEMERGING VIRUSES
- Many new viruses have emerged in recent years
(a) Ebola virus
(b) Hantavirus
17- How do new viruses arise?
- Mutation of existing viruses
- Spread to new host species
Figure 10.32
18- Chapter 11 Control of the Gene
- what makes all the cell in your body different
- cloning
19- Shortly after you drink a milk shake, bacteria
living in your large intestine turn on certain
genes. A cell can express some genes and
others that are in its genome.
- How cells determine and the mechanisms a cell
uses to express - some genes and not others
- gene regulation or regulation of
gene expression
- Gene expression refers to the process of
transcription and translation to make - a protein
20FROM EGG TO ORGANISM HOW AND WHY GENES ARE
REGULATED
- Four of the many different types of human cells
(a) Three muscle cells (partial)
(b) A nerve cell (partial)
- They all share the same genome
- What makes them different?
(c) Sperm cells
(d) Blood cells
Figure 11.2
21BIOLOGY AND SOCIETY BABYS FIRST BANK ACCOUNT
- In recent years umbilical cord and placental
blood has been collected at birth
Figure 11.1
22Fertilized Egg
How??
Fully developed, Multicellular organism
23- A process called cellular differentiation occurs
- Certain genes are turned on and off
- Gene expression is regulated
- Cells become specialized in structure and function
http//embryology.med.unsw.edu.au/Movies/Movies.ht
mEmbryoGrowth
24The Genetic Potential of Cells
- All contain a complete set of DNA
- May act like other cells if their pattern of gene
expression is altered
25- A gene is turned on and transcribed into RNA
- Information flows from genes to proteins,
genotype to phenotype
- The regulation of gene expression plays a central
role in development from a zygote to a
multicellular organism
26Eye lens cell (in embryo)
Pancreascell
Nerve cell
- Even though cells of an organism have the same
genes (genotype) - Patterns of gene expression in specialized human
cells
Glycolysis enzyme genes
Crystallin gene
Insulin gene
Hemoglobin gene
Key
Active gene
Inactive gene
Figure 11.3
27Where do stem cells come from?
Why are stem cells medically important?
- Totipotent stem cells
- Pluripotent stem cells
28- Umbilical cord and placental blood is rich in
stem cells
- Stem cells can develop into a wide variety of
different body cells
Stem Cell
liver
heart
brain
blood
bone
29Cloning
Cloning 1) Reproductive 2) Therapeutic
(involves stem cells)
How are cloning and stem cell research related?
30Reproductive Cloning
- Scottish researchers cloned the first mammal in
1997 using a technique called nuclear
transplantation
- Other organisms have since been produced using
this technique, some by the pharmaceutical
industry
(a) Piglets
(b) Banteng
31- The procedure that produced Dolly is called
reproductive cloning
Reproductive cloning
Donor cell
Nucleus from donor cell
Implant embryo in surrogate mother
Clone of donor is born
Therapeutic cloning
Remove nucleus from egg cell
Add somatic cell from adult donor
Grow in culture to produce an early embryo
Remove embryonic stem cells from embryo and grow
in culture
Induce stem cells to form specialized cells for
therapeutic use
Figure 11.6
32Eunucleation of egg
Transfer of new nucleus
33Therapeutic Cloning and Stem Cells
- Produces embryonic stem cells (ES cells)
- Can give rise to specific types of differentiated
cells
34Liver cells
Cultured embryonic stem cells
Nerve cells
Heart muscle cells
Different culture conditions
Different types of differentiated cells
Figure 11.8
35- Generate replacements for nondividing
differentiated cells - Are unlike ES cells, because they are partway
along the road to differentiation
36- In 2001, a biotechnology company announced that
it had cloned the first human embryo
Figure 11.9