1. Chapter 12 Sections 1 and 2 only
DNA
Chapter 12
Sections 1 and 2 only

2. HOW DID WE GET TO THE POINT OF KNOWING THAT THE “SNOT” YOU FOUND DURING THE DNA EXTRACTION LAB WAS ACTUALLY THE MOLECULE RESPONSIBLE FOR CONTROLLING ALL THINGS IN AN ORGANISM?

3. Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
Griffith
Performed the first major experiment that led to the discovery of DNA as the genetic material

4. Concluded that when the S cells were killed, DNA was released
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
Avery
Identified the molecule that transformed the R strain of bacteria into the S strain
Concluded that when the S cells were killed, DNA was released
R bacteria incorporated this DNA into their cells and changed into S cells.

5. Chapter 12
Molecular Genetics
12.1 DNA
Hershey and Chase
Used radioactive labeling to trace the DNA and protein
Concluded that the viral DNA was injected into the cell and provided the genetic information needed to produce new viruses

6. Rosalind Franklin

7. Watson and Crick Model

8. The closest we can get with microscopes

9. 12.1 DNA: The Genetic Material
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
DNA Structure
Nucleotides
Consist of a five-carbon sugar, a phosphate group, and a nitrogenous base

10. We will make a paper model
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
DNA Structure
DNA often is compared to a twisted ladder.
Rails of the ladder are represented by the alternating deoxyribose and phosphate.
The pairs of bases (cytosine–guanine or thymine–adenine) form the steps.
We will make a paper model

11. 12.1 DNA: The Genetic Material
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
Orientation
On the top rail, the strand is said to be oriented 5′ to 3′.
The strand on the bottom runs in the opposite direction and is oriented 3′ to 5′.

12. Chargaff Chargaff’s rule C = G and T = A
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
Chargaff
Chargaff’s rule
(AKA: Base-Pair Rule)
C = G and T = A

13. Coloring the Anatomy of DNA
You and your West partner need to select 6 colors in order to color in your DNA diagram

14. MAKING A DNA MODEL

15. 12.1 DNA: The Genetic Material
Chapter 12
Molecular Genetics
12.1 DNA: The Genetic Material
Chromosome Structure
DNA coils around histones to form nucleosomes, which coil to form chromatin fibers.
The chromatin fibers supercoil to form chromosomes that are visible in the metaphase stage of mitosis.

16. Semiconservative Replication
Chapter 12
Molecular Genetics
12.2 Replication of DNA
Semiconservative Replication
Parental strands of DNA separate, serve as templates, and produce DNA molecules that have one strand of parental DNA and
one strand of new DNA.
– Crash course video on DNA structure and replication

17. Chapter 12
Molecular Genetics
12.2 Replication of DNA
Good Video Showing REPLICATION
DNA helicase, an enzyme, is responsible for unwinding and unzipping the double helix.

18. Chapter 12
Molecular Genetics
12.2 Replication of DNA
watch it here
Base pairing
DNA polymerase adds appropriate nucleotides to the chain by adding to the 3′ end of the new DNA strand.

19. Chapter 12
Molecular Genetics
12.2 Replication of DNA
One strand is called the leading strand and is elongated as the DNA unwinds.
The other strand of DNA, called the lagging strand, elongates away from the replication fork.
The lagging strand is synthesized discontinuously into small segments, called Okazaki fragments.

20. DNA ligase makes sure all DNA nucleotides are bonded together.
Chapter 12
Molecular Genetics
12.2 Replication of DNA
Joining
DNA ligase makes sure all DNA nucleotides are bonded together.

21. Comparing DNA Replication in Eukaryotes and Prokaryotes
Chapter 12
Molecular Genetics
12.2 Replication of DNA
Comparing DNA Replication in Eukaryotes and Prokaryotes
Eukaryotic DNA unwinds in multiple areas as DNA is replicated.
In prokaryotes, the circular DNA strand is opened at one origin of replication.