Examining the genetic material

1. Examining the genetic material • Criteria for genetic material • Discovering the genetic material • Reviewing the structure of DNA • Nucleotides • Polynucleotides • Structure of DNA holds the key to understanding its function! • DNA Replication Review • Semiconservative replication, Replication fork • DNA Polymerase & Initiation • Elongation: Antiparallel strands: continous & discontinuous

2. I. Criteria for genetic material • Must store the information necessary to construct an entire organism (BLUEPRINT) • During reproduction, the genetic material usually must be replicated, passing from parent to offspring, and each cell must be supplied with a copy. (FAITHFUL REPLICATION) • Must have variation that can account for the know phenotypic variation within each species (POTENTIAL FOR MUTATION) • Must be able to be activated in order to create products (EXPRESSION OF INFORMATION)

3. DNA - - - the genetic material • DNA stores information • Can be faithfully replicated • Undergoes mutation • Is expressed

4. II. Discovering the genetic material • Experiments implied that the substance responsible for genetic transformation was the DNA of the cell • Griffith • Avery, MacLoed & McCarty • Hershey & Chase

5. Griffith’s experiment:

6. Avery, MacLeod & McCarty’s follow-up experiment:

7. The Hershey & Chase experiment: Verified that DNA was the genetic material – Bacteriophage added to E.coli in radioactive medium (35S – protein, 32P – DNA)

8. III. Reviewing the structure of DNA DNA - function based upon molecular Structure A. Nucleotides: • Composed of 3 kinds of molecules: • Nitrogenous compound (pyrimidine/purine) • Five-carbon sugar (ribose/deoxyribose) • Phosphate • Linked together via phosphodiester bond with 5’ to 3’ directionality

10. Nucleotide triphosphate (NTP)

11. B. Polynucleotides

12. C. Structure of DNA holds the key to understanding its function! • Base composition studies (Chargraff) • Amount of adenine residues is proportional to the amount of thymine residues in the DNA of any species… • (A+G) = (C+T) • X ray diffraction analysis • Watson-Crick, Franklin Model

13. complementary • antiparallel • base pair = unit of length • 1,000 bp = 1kb

14. Note the directionality -

15. Secondary structure

16. Alternative forms of DNA

17. DNA structure & function • How does DNA fulfill the requirements of genetic material? • Replicate? • Encode info? • Mutate? • Get expressed?

18. IV. DNA Replication REVIEW • Transfer of genetic info from parent to progeny by faithful replication of the parent DNA • Faithful but not perfect… and this is a good thing because??? • Complex process, not completely understood • http://www.wehi.edu.au/education/wehi-tv/dna/replication.html

19. A. DNA is reproduced by semiconservative replication

20. Meselson-Stahl Experiment Bacteria labeled with heavy isotope (15N) transferred to medium w/light isotope (14N) – the new DNA would be “lighter” than the parent DNA & could be distinguished via centrifugation.

21. The replication fork • Strands of helix unwind at the replicon (origin of replication: ori) • Bidirectional, continues until it reaches the termination region: ter • Speed – in humans is about 50 nucleotides per second per replication fork

22. B. DNA Polymerase & Initiation • Polymerase catalyzes the synthesis of the daughter DNA strand • Uses the parent strand as a template • chain elongation proceeds in the 5’ to 3’ direction - New dNTPs are added to the 3’OH end • DNA POL I, POL II, POL III (all can elongate and existing DNA strand) • 3' to 5' exonuclease functions as a "proofreader". • 5' to 3' exonuclease activity to remove RNA primers. • POL I & POL II DNA repair • POL III Replication

23. POL III: 10 different subunits Active form = holoenzyme

24. Initiation • Unwinding of Helix • DNA helix unwinds at the origin • Helicases unwind Helix at the ori • H-bonds “melt” • Single strand binding proteins (SSBPs) hold the strands apart

25. 2). Primer • PRIMER = Sequence of RNA synthesized on the template • Primer terminus generated within Duplex DNA, a nick generates free 3’-OH end of the RNA that is extended by Polymerase RNA primers are synthesized by RNA polymerase or by a primase (which is made up of additional proteins)

26. C. Elongation=synthesis of a new strand of DNA by the addition of a new base, (one base at a time). http://www.contexo.info/DNA_Basics/replication%20move.htm

27. Antiparallel strands: continuous & discontinuous • Antiparallel structure: problem, as replication fork advances-daughter strands must be synthesized on both parental single strands. New nucleotides only added on 3’-OH end • Leading strand: one strand serves as template for continuous DNA synthesis • Lagging strand: oriented in the 3’-5’ direction, so short fragments synthesized “backwards” in the 5’ to 3’ direction • Series of fragments joined together via DNA ligase

28. http://nobelprize.org/medicine/educational/dna/a/replication/lagging_ani.htmlhttp://nobelprize.org/medicine/educational/dna/a/replication/lagging_ani.html

29. Eukaryotic replication • Similar, but more complex • Multiple replication origins • Six different DNA polymerases • Telomers