1. Unit 4 - Molecular Genetics DNA Replication Protein Synthesis – Transcription – Translation Cell Cycle

2. 1928 – Griffith

3. 1944 – Avery, McCarty, & McCleod

4. Bacteriophage Viruses that attack bacterial cells (“bacteria eaters”)

5. 1952 – Harvey & Chase

6. 1953  Watson & Crick (and Franklin)

7. 1958 – Meselson & Stahl

8. DNA Structure Nucleotides – the building blocks of DNA (nucleic acids)

9. Base Pairing A-T (double) G-C (triple)

10. 3’ vs. 5’ ends of DNA

11. Gene – a portion of DNA that codes for a specific protein

13. DNA Function Transmission of genetic material to offspring Basis of all cell processes (DNA  RNA  Protein) Structure relates to function! – DNA structure provides a perfect template for semi- conservative replication

14. Leading vs. Lagging Strands Nucleotides can only be added to the 3’ end of a DNA molecule – THUS - DNA elongates only in the 5’  3’ direction

15. DNA Replication 1.Starts at an origin of replication (ori) – Bacterial DNA is circular (only 1 ori) – Eukaryotic DNA is linear (multiple ori’s)

16. 2. RNA primase (enzyme) recognizes an ori site on DNA, “sits” down on DNA, and synthesizes an RNA strand (5-10 nucleotides long) called a primer 3. DNA polymerase (enzyme) finds this primer and begins replication – Adds nucleotides in a 5’  3’ direction only!

17. Replication fork – spots where DNA double strand “forks” DNA helicase (enzyme) – unzips the DNA double helix

18. 3a – Leading Strand As the helix is unzipped, the 3’ end of leading strand is synthesized continuously Only 1 RNA primer and 1 DNA polymerase is needed!

19. 3b – Lagging Strand Lagging strand is synthesized BACKWARDS in short chunks called Okazaki fragments with each getting: – RNA primer (thus RNA primase) – DNA polymerase (to synthesize DNA) DNA ligase – enzyme that ligates (“sticks together”) Okazaki fragments together to form a single DNA strand

23. DNA Replication Video http://www.youtube.com/watch?v=teV62zrm 2 http://www.youtube.com/watch?v=teV62zrm 2

24. A few essential ideas to remember: 1.DNA copies itself almost always without error. (Approximately 1 true error per 10 billion bp; actually 1 error in 10,000 bp but DNA polymerases proof-read and fix) 1.Eukaryotic DNA replicates @ 50 nucleotides/second; bacterial DNA replicates much faster (10x)

25. Proof-reading & Repair DNA polymerases proof-read each strand against the parent template. If error goes unrepaired by DNA polymerases, then other repair mechanisms kick in. There are 130 different DNA repair enzymes in humans!

26. An example…

27. Telomeres Telomere- a 100 to 1000 base-pair section at the tips of Eukaryote’s chromosomes (DNA) Repeating sequences of TTAGGG (humans) Function to protect the end of genes from being shortened by successive rounds of replication but telomeres themselves are shortened after each round of replication

29. Telomeres can only be shortened so much (thus a cell can divide only so many times) and then the cell dies via apoptosis (programmed cell death) Get this: – Certain cells (e.g. germ cells) have telomerase, an enzyme that catalyzes the repair of telomere DNA damaged after replication – Certain types of cancer cells overexpress telomerase which allows those cells to continuously divide w/o consequence