1. DNA and RNA Chapter 12

2. Griffith Studied disease in humans in 1928 Wanted to know how certain types of bacteria cause pneumonia Found two strains of pneumonia bacteria Smooth coated bacteria caused the disease to appear in humans Rough coated bacteria of the same type did not

3. Rough Strain Smooth Strain Heat-killed smooth Live rough and heat killed smooth

4. Transformation Somehow the heat-killed bacteria had passed their disease-causing ability to the harmless strain. One strain of bacteria was “ transformed ” into a disease-causing strain. Griffith called the process transformation

5. Bacteriophage Phage-eat Bacterio- Composed of a DNA or RNA core and protein coat Injects viral genes into bacteria and “ reprogram ” the bacteria to make more viruses

7. Hershey-Chase If they could determine which part of the virus, the protein coat or the DNA core, entered the infected cell they would know whether genes were made of protein or DNA They grew viruses in cultures of radioactive isotopes found in protein coats and in DNA

9. Sulfur 35

10. DNA Long molecule made up of units called nucleotides Each nucleotide is made up of three basic components Sugar (deoxyribose) Phosphate group Nitrogenous (nitrogen-containing) base

11. DNA, It ’ s not just for cells anymore

12. Nucleotides Nucleic Acid Deoxyribose

13. H - Bonds Return! Chargraff ’ s Rules C=G in almost any sample of DNA A=T in almost any sample of DNA From bacteria to humans, it ’ s always true

14. Hydrogen Bonds Return! Hydrogen bonds can form between certain nitrogenous bases and provide just enough force to hold the two strands together H-bonds form only between given pairs A-T and C-G This is known as base pairing Adenine-Thiamine, Cytosine-Guanine

15. Chromosomes Eukaryote Prokaryote

16. Prokaryotic DNA The prokaryotic DNA molecule is located in the cytoplasm. It is usually a single circular molecule It contains nearly all of the cell ’ s genetic information Usually referred to as the cell ’ s chromosome.

17. Miles and Miles of Info! E. coli contains 4,639,221 base pairs and is around 1.6mm In larger terms, that ’ s like stuffing 300m of rope into your book bag Bacterial DNA is usually about 1000 times as long as the bacteria itself

18. Chromosome Structure Many eukaryotes have as much as 1000 times the amount of DNA as prokaryotes. The nucleus of a human cell contains more than 1 meter of DNA. (3.28 feet or 39.37 inches in each nucleus!)

19. Eukaryotic chromosomes contain both DNA and protein, packed together to form chromatin. Chromatin is DNA that is tightly coiled around proteins called histones. Histone

20. To make a chromosome The DNA and histone molecules form a bead-like structure called a nucleosome. During most of the cell cycle the fibers are dispersed and not visible. During mitosis, the fibers are drawn together to form a tightly wound chromosome.

21. Supercoils Coils

22. DNA Histone Supercoils Nucleosome Chromosome Nucleosomes seem to be able to forld enormous lengths of DNA into the tiny space available in the cell. The histone proteins have hardly changed during evolution, probably because mistakes in DNA folding could be devastating to a cell Coils

23. DNA Replication: Why Multiply? Mitosis and Meiosis both require replication of DNA molecules Growth Healing from injury Replacing worn molecules Creating Sex Cells for sexual reproduction

24. Replication 1. Before a cell divides, it duplicates its DNA in a copying process called replication. 2. The two DNA strands are “ uncoiled ” and “ unzipped ” from each other by enzymes regulating replication 1. “ Unzipped ” means the hydrogen bonds holding the opposing bases together are broken 3. DNA polymerase builds a new complementary strand onto each of the old unzipped strands

25. DNA Replication In prokaryotes, DNA replication begins at a single point in the chromosome Replication proceeds in two directions around the circle In eukaryotes, DNA replication occurs at hundreds of places Replication proceeds in both directions Sites where separation and replication occur are called replication forks

26. Replication Fork Original DNA strand New DNA strands DNA Polymerase “ Unzipping ” - breaking Hydrogen bonds

27. Polymerase Joins individual nucleotides to produce a DNA molecule (which is a polymer) “ Proofreads ” each new DNA strand to maximize odds of correct pairing

28. DNA