1 / 56

Chapter 5: DNA Replication, Repair, and Recombination

Chapter 5: DNA Replication, Repair, and Recombination. Maintenance of DNA Sequences. Long Term Survival of Species Vs Survival of the Individual. Maintenance of DNA Sequences. Methods for Estimating Mutation Rates

Download Presentation

Chapter 5: DNA Replication, Repair, and Recombination

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Chapter 5: DNA Replication, Repair, and Recombination

  2. Maintenance of DNA Sequences Long Term Survival of Species Vs Survival of the Individual

  3. Maintenance of DNA Sequences Methods for Estimating Mutation Rates • Rapid generation of bacteria makes possible to detect bact w/ specific gene mutation • Mutation in gene required for lactose metabolism detected using indicator dyes • Indirect estimates of mutation rate: comparisons of aa sequence of same protein across species • Better estimates: 1. comparisions aa sequences in protein whose aa sequence does not matter 2. comparisions DNA sequences in regions of genome that does not carry critical info

  4. Maintenance of DNA Sequences Many Mutations Are Deleterious & Eliminated • Ea protein exhibits own characteristic rate of evol which reflects probability that aa chg will be harmful • 6-7 chgs harmful to cytochrome C • Every aa chg harmful to histones

  5. Maintenance of DNA Sequences Mutation Rates are Extremely Low • Mutation rate in bact and mammals = 1 nucleotide chg/109 nucleotides ea time DNA replicated • Low mutation rates essential for life • Many mutations deleterious, cannot afford to accumulate in germ cells • Mutation frequency limits number of essential proteins organism can encode ~60,000 • Germ cell stability vs Somatic Cell Stability

  6. Maintenance of DNA Sequences Multicellular Organisms Dependent upon Hi Fidelity Maintenance Afforded By: • Accuracy of DNA replication and distribution • Efficiency of DNA repair enzymes

  7. Maintenance of DNA Sequences High Fidelity DNA Replication • Error rate= 1 mistake/109 nucleotides • Afforded by complementary base pairing and proof-reading capability of DNA polymerase

  8. Maintenance of DNA Sequences DNA Polymerase as Self Correcting Enzyme • Correct nucleotide greater affinity than incorrect nucleotide • Conformation Chg after base pairing causes incorrect nucleotide to dissociate • Exonucleolytic proofreading of DNA polymerase • DNA molecules w/ mismatched 3’ OH end are not effective templates; polymerase cannot extend when 3’ OH is not base paired • DNA polymerase has separate catalytic site that removes unpaired residues at terminus

  9. Mechanism of DNA Replication General Features of DNA Replication • Semiconservative • Complementary Base Pairing • DNA Replication Fork is Assymetrical • Replication occurs in 5’ 3’ Direction

  10. DNA Replication Okazaki Fragments • DNA Primase uses rNTPs to synthesize short primers on lagging Strand • Primers ~10 nucleotides long and spaced ~100-200 bp • DNA repair system removes RNA primer; replaces it w/DNA • DNA ligase joins fragments

  11. DNA Replication DNA Helicase • Hydrolyze ATP when bound to ssDNA and opens up helix as it moves along DNA • Moves 1000 bp/sec • 2 helicases: one on leading and one on lagging strand • SSB proteins aid helicase by destabilizing unwound ss conformation

  12. DNA Replication SSB proteins help DNA helicase destabilizing ssDNA

  13. DNA Replication DNA Polymerase held to DNA by clamp regulatory protein • Clamp protein releases DNA poly when runs into dsDNA • Forms ring around DNA helix • Assembly of clamp around DNA requires ATP hydrolysis • Remains on leading strand for long time; only on lagging strand for short time when it reaches 5’ end of proceeding Okazaki fragments

  14. DNA Replication Replication Machine (1 x 106 daltons) • DNA replication accomplished by multienzyme complex that moves rapidly along DNA by nucleoside hydrolysis • Subunits include: (2) DNA Polymerases helicase SSB Clamp Protein • Increases efficiency of replication

  15. DNA Replication Okazaki Fragments • RNA that primed synthesis of 5’ end removed • Gap filled by DNA repair enzymes • Ligase links fragments together

  16. DNA Replication Strand Directed Mismatch Repair System • Removes replication errors not recognized by replication machine • Detects distortion in DNA helix • Distinguishes newly replicated strand from parental strand by methylation of A residues in GATC in bact • Methylation occurs shortly after replication occurs • Reduces error rate 100X • 3 Step Process recognition of mismatch excision of segment of DNA containing mismatch resynthesis of excised fragment

  17. DNA Replication Strand Directed Mismatch Repair

  18. DNA Replication Strand Directed Mismatch Repair in Humans • Newly synthesized strand is preferentially nicked and can be distinguish in this manner from parental strand • Defective copy of mismatch repair gene predisposed to cancer

  19. DNA Replication DNA Topoisomerases • Reversible nuclease that covalently adds itself to DNA phosphate backbone to break phosphodiester bond • Phosphodiester bond reforms as protein leaves • Two Types Topoisomerase I- produces single stranded break Topoisomerase II- produces transient double stranded break

  20. DNA Replication Topoisomerase I

  21. DNA Replication Topoisomerase II

  22. DNA Replication Eucaryotes vs Procaryotes • Enzymology, fundamental features, replication fork geometry, and use of multiprotein machinery conserved • More protein components in Euk replication machinery • Replication must proceed through nucleosomes • O. fragments in Euk ~200 bp as opposed to 1000-2000 Pro • Replication fork moves 10X faster in Pro

  23. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • DNA Replication Begins at Origins of Replication • Positions at which DNA helix first opened • In simple cells ori defined DNA sequence 100-200 bp • Sequence attracts initiator proteins • Typically rich in AT base pairs

  24. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Bacteria • Single Ori • Initiation or replication highly regulated • Once initiated replication forks move at ~400-500 bp/sec • Replicate 4.6 x 106 bp in ~40 minutes

  25. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Eukaryotic Chromosomes Have Multiple Origins of Replication • Relication forks travel at ~50 bp/sec • Ea chromosome contains ~150 million base pairs • Replication origins activate in clusters or replication units of 20-80 ori’s • Individual ori’s spaced at intervals of 30,000-300,000 bp

  26. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Eukarotic DNA replication During S phase • Ea chromo replicates to produce 2 copies that remain joined at centromeres until M phase • S phase lasts ~8 hours • Diff regions on same chromosomes replicate at distinct times during S phase • Replication btwn 2 ori’s takes ~ 1 hr • BrdU experiments • Highly condensed chromatin replicates late while less condensed regions replicate early • Housekeeping and cell specific genes

  27. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Replication Origins Well Defined Sequences in Yeast • ARS autonomously replicating sequence • ARS spaced 30,000 bp apart • ARS deletions slow replication • ORC origin recognition complex marks replication origin binds Mcm (DNA helicase) Cdc6 (helicase loading factor)

  28. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Mammalian DNA Sequences that Specify Initiation of Replication • 1000’s bp in length • Can function when placed in regions where chromo not too condensed • Human ORC required for replication initiation also bind Cdc6 and Mcm proteins • Binding sites for ORC proteins less specific

  29. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • New Nucleosomes Assembled Behind Replication Fork • lg amt of new histone protein required during replication • 20 repeated gene sets (H1, H2A, H2B, H3, H4) • Histones syn in S phase ( transcription, degradation) • Histone proteins remarkably stable • Remodeling complexes destabilize DNA histone interface during replication • CAFs (chromatin assembly factors) assist in addition of new nucleosome behind replication fork

  30. DNA ReplicationInitiation and Completion of DNA Replication in Chromosomes • Telomerase Replicates Ends of Chromosomes • Telomere DNA sequences contain many tandem repeat sequences • Human telomere sequence GGGTTTA extends 10,000 nucleotides • Telomerase= special reverse transcriptase • Telomerase elongates repeat sequence recognizing tip of G-rich strand uses RNA template that is a component of enzyme itself • Protruding 3’ end loops back to hid terminus and protect it from degradative enzymes

  31. DNA Repair • Despite 1000’s of alterations that occur in DNA ea day, few are retained as mutations • Efficient reapir mechanisms • Impt of DNA repair highlighted by: • # of genes devoted to DNA repair • mutation rates as a function of inactivation or loss of DNA repair gene • Defects in DNA repair associated w/ several disease states

  32. DNA RepairTypes of DNA Damage: Base Loss and Base Modification Chemical Modification Photodamage thymine dimer Depurination Chemical Modification by O2 free radicals Deamination

  33. DNA Repair DNA Glycosylases Cleave glycosyl bond that connects base to backbone sugar to remove base > 6 Different types including those that remove: deaminated C’s different types of alkylated or oxidize bases deaminated A’s bases w/ open rings bases w/ C=C

  34. DNA Repair • Base Excision Repair • DNA glycosylase recognizes damaged base • Removes base leaving deoxyribose sugar • AP endonuclease cuts phosphodiester bkbone • DNA polymerase replaces missing nucleotide • DNA ligase seals nick

  35. DNA Repair Nucleotide Excision Repair • Bulky Lesion • Recognition • Demarcation and unwinding • Assembly of Repair enzymes • Dual Incision • Release of Damaged Nucleotide • Gap Filling DNA Synthesis

  36. DNA Repair Chemistry of DNA Bases Facilitates Damage Detection RNA thot to be original genetic material A, C, G, U Why U replaced w/ T? Deaminated C converted to U DNA repair system unable to distinguish daminated C from U in RNA

  37. DNA Repair Repairing Double Stranded Breaks in DNA Nonhomologous end-joining repair original DNA sequence is altered during repair (deletions or insertions) Homologous end-joining repair general recombination mechanism; info transferred from intact strand

  38. DNA Repair DNA Damage Can Activate Expression of Whole Sets of Genes • Heat Shock Response • SOS Response

  39. DNA Repair DNA Damage Delays Progression of Cell Cycle DNA damage generates signals that block cell cycle progression Blocks occur to extend the time for DNA Repair ATM ataxia telangiectasia- defects in gene encoding ATM protein

  40. Recombination • DNA sequences occasionally rearranged • Rearrangments may alter gene structure as well as timing and level of expression • Promote variation

  41. Recombination Two Classes 1. General or Homologous Recombination 2. Site-Specific Recombination

  42. Recombination General or Homologous Recombination • Exchange btwn homologous DNA sequences • Essential repair mechanism • Essential for chromosomal segregation • Very Precise • Crossing over creates new combinations of DNA seq on ea chromo

  43. Recombination Major Steps in General or Homologous Recombination 1. Synapsis 2. Branch Chain Migration 3. Isomerization of Holliday Junction 4. Resolution

  44. Recombination • General or Homologous Recombination Guided by Base Pairing Interactions • Cross over of DNA from different chromosomes • ds helices break and two broken ends join opp. partners to reform intact ds helices • Exchange occurs only if there is extensive sequence homology • No nucleotides are altered at site of exchange; no loss or gain

  45. Recombination DNA Synapsis catalyzed by RecA Protein • DNA strand from one helix has been exposed and its nucleotides made available for pairing w/ another molec= synapsis • Initiated by endonuclease cutting two strands of DNA and 5’ end chewed back to form ss 3’ end • SSB proteins hold strands apart • RecA allows ssDNA to pair w/ homologous region of DNA=synapsis

  46. Recombination RecA Proteins also Facilitate Branch Chain Migration • Unpaired region of one of the ss displaces paired region of other ss moving the point • RecA catalyzes unidirectional branch migration producing region of heteroduplex DNA 1000’s bp in length

  47. Recombination Holliday Junction • Two homolgous DNA helices paired and held together by reciprocal exchg of two of the four strands • Two pairs of strands: one pair of crossing strands and one pair or noncrossing • Isomerization leads to open structure where both pairs occupy equivalent positions • Holliday junction resolved by cutting of helices

  48. Recombination Resolution of Holliday Junction

  49. Recombination Site-Specific Recombination • Mobile genetic elements move btwn nonhomologous sequences • Molibe genetic elements size range 100s-1000s bp found in nearly all cells some represent viral sequences relics constitute significant portion of genome (repeat sequences)

  50. Recombination Movement of Mobile Genetic Elements • Site specific recombo mediated by enzymes recognize short specific nucleotide sequences present in one or both of recombo DNA molec • No sequence homology required • Mobile genetic elements generally encode enzyme that guides movement and special sites upon which enzyme acts • Elements move by transposition or conservative mechanisms

More Related