1. Chapter 16: Molecular Basis of Inheritance

2. The Search for the Genetic Material 1928 = Frederick Griffith and Streptococcus pneumoniae 1928 = Frederick Griffith and Streptococcus pneumoniae 1940s = Protein or DNA ?? 1940s = Protein or DNA ?? – The case for proteins seemed stronger 1944 = Oswald Avery, Maclyn McCarty and Colin MacLeod working with E.coli and T2 1944 = Oswald Avery, Maclyn McCarty and Colin MacLeod working with E.coli and T2 1953 = James Watson and Francis Crick shook the scientific world with their elegant DNA model 1953 = James Watson and Francis Crick shook the scientific world with their elegant DNA model

3. Frederick Griffith, 1928 Attempting to develop a vaccine against pneumonia Attempting to develop a vaccine against pneumonia Two strains: Two strains: – One pathogenic (S strain, capsule) – One non pathogenic (R strain) S train was killed by heating, and mixed the dead S strain with live R strain S train was killed by heating, and mixed the dead S strain with live R strain Transformation occurred!! Transformation occurred!!

5. Streptococcus pneumoniae

7. Observations Clearly, some chemical component of the dead pathogenic cells caused this heritable change Clearly, some chemical component of the dead pathogenic cells caused this heritable change Griffith called the phenomenon transformation (assimilation of external DNA that causes change in genotype and phenotype) Griffith called the phenomenon transformation (assimilation of external DNA that causes change in genotype and phenotype)

8. Avery, McCarty and MacLeod 1944 Studied DNA, RNA and protein for 14 years Studied DNA, RNA and protein for 14 years They worked with Streptococcus pneumoniae They worked with Streptococcus pneumoniae In 1944 Avery, MacLeod and McCarty announced that the transforming agent was DNA In 1944 Avery, MacLeod and McCarty announced that the transforming agent was DNA Their discovery was greeted with interest but considerable skepticism Their discovery was greeted with interest but considerable skepticism

9. Oswald Avery Colin MacLeod Maclyn McCarty

11. Alfred Hershey and Martha Chase, 1952 They worked with bacteriophage (phage) and Escherichia coli (intestines of mammals) They worked with bacteriophage (phage) and Escherichia coli (intestines of mammals) T2 sequesters E. coli’s cell machinery and makes it produce many copies of itself T2 sequesters E. coli’s cell machinery and makes it produce many copies of itself

15. Observations/Conclusions They where able to observe which type of molecule had entered the bacterial cells and changed them They where able to observe which type of molecule had entered the bacterial cells and changed them Phage DNA entered the cell, but the phage protein did not Phage DNA entered the cell, but the phage protein did not Conclusion: DNA injected by the phage must be the molecule carrying the genetic information that makes the cells produce new viral DNA and proteins Conclusion: DNA injected by the phage must be the molecule carrying the genetic information that makes the cells produce new viral DNA and proteins

16. Erwin Chargaff, 1950

17. Chargaff It was already know that DNA is a polymer of nucleotides It was already know that DNA is a polymer of nucleotides Analyzed the base composition of DNA from a number of different organisms Analyzed the base composition of DNA from a number of different organisms He noticed a peculiar regularity in the ratios of nucleotide bases within a single species He noticed a peculiar regularity in the ratios of nucleotide bases within a single species

19. Chargaff’s Rules # A approximately equaled the # T # G approximately equaled the # C A = 30.3 % A = 30.3 % T = 30.3 % T = 30.3 % G = 19.5 % G = 19.5 % C = 19.9 % C = 19.9 % But why was not yet known (structure)

20. Building a DNA model (1950s) Linus Pauling proposed a triple helix model (California Institute of Technology) Linus Pauling proposed a triple helix model (California Institute of Technology) Maurice Wilkins and Rosalind Franklin and others (Kings College, London) Maurice Wilkins and Rosalind Franklin and others (Kings College, London)

21. The story… James Watson journeyed to Cambridge, where Francis Crick was studying protein structure using X-ray crystallography James Watson journeyed to Cambridge, where Francis Crick was studying protein structure using X-ray crystallography Watson visited Maurice Wilkins in the Randall Lab and saw the diffractions images produced by Franklin Watson visited Maurice Wilkins in the Randall Lab and saw the diffractions images produced by Franklin

22. X-ray Chrystallography Produces an X-ray diffraction image Produces an X-ray diffraction image The crystal is bombarded with X-rays The crystal is bombarded with X-rays The rays are deflected as the pass through the aligned fibers of purified DNA The rays are deflected as the pass through the aligned fibers of purified DNA Mathematical equations are used to translate the patterns into information on the 3D structure of the molecule Mathematical equations are used to translate the patterns into information on the 3D structure of the molecule

23. Watson and Crick Built models of a double helix that would conform to the X-ray measurements and to what was known about the chemistry of DNA Built models of a double helix that would conform to the X-ray measurements and to what was known about the chemistry of DNA They read an unpublished annual report summarizing Franklin’s work where she had concluded that the sugar-phosphate backbones were on the outside of the double helix They read an unpublished annual report summarizing Franklin’s work where she had concluded that the sugar-phosphate backbones were on the outside of the double helix

24. Model made of tin and wire Model made of tin and wire

25. pyrimidine purine

27. Great idea!!! The arrangement was appealing because it put the relatively hydrophobic nitrogenous bases towards the interior The arrangement was appealing because it put the relatively hydrophobic nitrogenous bases towards the interior Sugar-phosphate backbones are antiparallel Sugar-phosphate backbones are antiparallel Nitrogenous bases are paired in specific combinations (maintain uniform diameter) Nitrogenous bases are paired in specific combinations (maintain uniform diameter)

29. April 1953 Watson and Crick surprised the scientific world with a succinct, one-page paper in Nature Watson and Crick surprised the scientific world with a succinct, one-page paper in Nature The beauty of the model is that is suggested a mechanism for replication The beauty of the model is that is suggested a mechanism for replication

30. Base Paring to a Template Strand Watson and Crick wrote a second paper in which they stated their hypothesis for how DNA replicates Watson and Crick wrote a second paper in which they stated their hypothesis for how DNA replicates

31. The semiconservative model remained untested for several years The semiconservative model remained untested for several years Other models were: Other models were: – Conservative model – Dispersive model

32. 1962: Nobel Prize awarded Watson and Crick Watson and Crick Also to Maurice Wilkins Also to Maurice Wilkins But not given to Rosalind Franklin! But not given to Rosalind Franklin! – She sadly died of cancer in 1958

33. Matthew Meselson and Franklin Stahl

34. In 1958 they published a clever experiment that distinguished between the three models In 1958 they published a clever experiment that distinguished between the three models Their results supported the semiconservative model of replication Their results supported the semiconservative model of replication

36. DNA replication: a closer look E. coli has a singular, circular chromosome of about 4.6 million nucleotide pairs It can divide to form two genetically identical daughter cells in less than an hour More than a dozen enzymes and other proteins participate in DNA replication

37. 1. Initiation (E. coli) Replication begins at special sites called origins of replication (specific sequence) Bacterial chromosomes have a single origin Special proteins recognize and bind to the DNA of the origin allowing the separation of the two strands (replication bubble)

38. Replication proceeds in both directions, driven by replication fork

39. Replication in Eukaryotes

40. Other proteins Helicases: untwist the double helix at the replication forks Single-strand binding proteins: bind to the unpaired DNA strands and stabilize them Topoisomerase: relives super-coiling Primase: allow initiation of synthesis by adding a short stretch of RNA (primer, 5-10 nt)

42. 2. Elongation DNA polymerases (enzymes) catalyze the synthesis of new DNA by adding nucleotides to a preexisting chain E. coli = two are the most important in DNA replication (DNA Pol III, DNA Pol I) DNA Pol III adds a DNA nucleotide to the RNA primer, then continues adding dNTPs

44. Antiparallel Elongation The two strands of the double helix are antiparallel DNA Pol can only add nucleotides to a free 3’ end (5’ to 3’ direction) Elongation: – Leading strand: continuous elongation, only one RNA primer – Lagging strand: discontiuous elongation, many RNA primers

45. 5’ 3’

46. Synthesis of Leading strand

47. Synthesis of Lagging strand

49. Lagging Strand DNA Pol moves away from the replication fork The segments observed on the lagging strand are called Okazaki Fragments (1000-2000 nt) DNA Pol I removes RNA nucleotides DNA ligase joins the final nucleotide of the replaced segment

50. Summary

51. DNA Replication Complex It is convenient to represent DNA polymerase molecules as little trains, but: – Various proteins actually form a single large complex – DNA replication complex does not move: rather, DNA moves through the complex (in eukaryotes, they may be anchored to the nuclear matrix) – Lagging strand is looped back through complex

52. Proofreading and Repair There is an error rate of about 1/100,000 nucleotides During DNA replication, DNA polymerases proofread each nucleotide against its template Removes incorrect nucleotides and resumes synthesis

53. Repair Mechanisms Mismatch Repair: – Enzymes remove and replace the incorrectly paired nucletide Nucleotide Excision Repair: – A nuclease cuts out the damaged strand and the nucleotides are replaced (Ex: thymine dimers)

55. Replicating the Ends of DNA Molecules DNA Pol can only add nucleotides to a 3’ end This represents a problem for linear chromosomes (eukaryotes) Once the last primer is removed, it cannot be replaced with DNA After repeated rounds of replication, shorter, uneven DNA molecules remain

57. Ends of linear chromosomes Special nucleotide sequences are present at the end of linear chromosomes They are called TELOMERES Telomeres are made of repeated DNA (in humans, TTAGGG, 100-1000 times) They postpone erosion

59. What about germ cells? An enzyme called telomerase catalyzes the lengthening of telomeres in eukaryotic germ cells They compensate for shortening that occurs during DNA replication Inactive in most human somatic cells Active in cancer cells

60. Chromosome Structure Bacterial chromosomes: – circular, – double stranded – associate with a small amount of protein Eukaryotic chromosomes: – Linear DNA – Associate with large amount of protein

61. Eukaryotic Chromosomes DNA + protein = chromatin Multilevel DNA packing system: – DNA – 10 nm fiber – 30 nm fiber – Looped domains – Metaphase chromosome

62. Eukaryotic Chromosomes Chromatin of each chromosome occupies a specific restricted area within the interphase nucleus (they do not become entangled) Condensed state: – Heterochromatin: highly condensed – Euchromatin: more dispersed. DNA is accessible for expression machinery