Chapter 4

1. Chapter 4 HIGHLIGHTS DNA Exact duplication of genetic material from generation to generation is crucial to continuity and survival Genes: hereditary units controlling identifiable traits General structure of nucleic acids Mechanism of DNA synthesis Not responsible for nucleosomes and heterochromatin • DNA and Chromosomes

2. Chromosomes in Cells

3. DNA is composed of 4 different nucleotides A,C,G,T

4. Nucleic Acids are the building blocks of DNA and RNA • DNA (deoxyribonucleic acid) • RNA (Ribonucleic acid) • Both are linear polymers of nucleic acids • Pentose • Ribose • 2-Deoxyribose

6. * * It is the chemical basicity of the nucleotides that has given them the common term "bases" as they are associated with nucleotides present in DNA and RNA. There are five major bases found in cells. The derivatives of purine are called adenine and guanine, and the derivatives of pyrimidine are called thymine, cytosine and uracil. The common abbreviations used for these five bases are, A, G, T, C and U. The purine and pyrimidine bases in cells are linked to carbohydrate and in this form are termed, nucleosides. The nucleosides are coupled to D-ribose or 2'-deoxy-D-ribose through a b-N-glycosidic bond between the anomeric carbon of the ribose and the N9 of a purine or N1 of a pyrimidine.

7. Nucleosides and Nucleotides

8. Efficient H-bonds for only between A-T and G-C

9. Hydrogen bonds holds DNA strands together

10. A-T; 2H bonds G-C; 3H bonds Sugar phosphate backbone

11. DNA Double Helix

12. DNA provides a template for its own duplication

13. Chromosome painting identifies different human chromosomes

14. The Human Karyotype One set of human chromosomes. Each somatic cell will have a maternal and paternal set, thus 44 chromosomes plus two sex chromosomes XX, female or XY, male = 46 TOTAL

15. Two closely related species of deer with very different chromosome numbers, but very similar number of genes.

16. Conserved synteny (gene order) between human and mouse genomes demonstrates that many of the human genes are shared by mice and that they are organized in a similar fashion within their genomes, which suggests that their expression is also controlled in a similar fashion

17. DNA in the cell is organized into protein-DNA complexes known as nucleosomes Nucleosomes are composed of eight histone proteins (2X four different types) that form a core that wraps around approx. 200 nucleotides. Nucleosomes serve to pack the DNA and also control the expression of genes.

18. Chapter 5 • DNA Replication, Repair, and Recombination (Not responsible for)

19. Common rules of DNA Synthesis: 1. Limited # of distinct monomeric subunits (5 nuc. acids) 2. Monomers are added one at a time (step by step addition) 3. Specific starting point Growth proceeds in one direction 4. DNA polymerases can not initiate synthesis de novo need RNA or DNA primer to provide free 3’ OH group Fixed terminus (5’ end to 3’ end in polynucleotides)

20. DNA Replication: Watson Crick Model of DNA suggested semiconservative DNA Multiple enzymes are required at the replication fork (helicase, topoisomerase, DNA polymerase, ligase and more) Leading strand and lagging strand (Okazaki fragments) Energy requiring process; requires a primer (RNA or DNA)

21. DNA Replication is very accurate

22. DNA synthesis is catalyzed by DNA polymerase.

23. DNA template is replicated through a semiconserved mechanism.

24. Incorrect model of DNA replication: DNA is always processed 5’-3 this diagram suggests that DNA can be synthesized 3’-5’ direction

25. Correct model of DNA synthesis 5’-3’ direction

26. DNA polymerases also have error correction function

27. 5’-3’ elongation of DNA provides an efficient means to correct mistakes.

28. DNA Primase RNA polymerase

29. Okazaki fragments

30. Nicks are ligated together by DNA ligase.

31. DNA helicase helps unwind DNA

32. Helicase movie

33. Proteins found at the DNA replication fork

34. DNA replication in action.

35. Replication occurs in both directions

36. DNA Replication Movies