Chapter 21

1. Chapter 21 Nucleic Acids

2. Queen Victoria • Hemophilia

3. Goals • Describe nucleotides, RNA and DNA, polypeptides • Know the 3D structure of nucleic acids • Describe mutations and their effects • Describe viruses and Recombinant DNA technology

4. Chromosomes • Humans have 46 • Germ cells have 23 • Contain all genetic information of the organism

5. RNA • Leave nucleus

6. Nucleotides • Monomers that make up DNA and RNA

7. Nucleotides • Made from

8. Naming • Sugar and base • Adenine + sugar = • Cytosine + sugar = • is second part of the name • dGMP

9. 5’ – 3’ Phosphodiester • In making DNA – • This is the direction used for naming

10. DNA Structure • Watson and Crick 1953 • Complementary pairs

11. Complementary Strands • Bases located • Maximum • Maximum • Hydrophobic bonds to the bases above and below

12. Given… • G A T T A C A • What is the complementary strand?

13. Size of DNA • 3x109 base pairs • Organized around • Around 200 base pairs/

14. RNA • Single strand • Different types

15. RNA Pairing • Only about ½ molecules base pair • Acceptor stem: • Anticodon -

16. Information flow • Replication: • Transcription: • Translation:

17. Replication • Copy all 46 chromosomes in less than a day (about 8 hrs) • Error – • Always in 5’  3’ direction and two strands grow opposite • DNA

18. DNA Polymerase • “Checks” the accuracy of the pairing and correcting errors

19. Practice • What is the corresponding daughter strand to the parent

20. Transcription • Transcription bubble • RNA Polymerase acts on the template strand only • There is a start site • There is a termination site

21. RNA Polymerase • No proofreading function • Error • Initial RNA is called primary transcript RNA, ptRNA • Later modified to the other types

22. What RNA is formed? • If the DNA sequence is: • What is the RNA that is synthesized?

23. Post transcription • End capping • Base modification • Splicing

24. Translation • Protein synthesis • Sequence of bases specifies amino acid sequence • 64 codons for 20 amino acids

25. Translation • Each tRNA carries ONLY ONE aa • Aminoacyl-tRNA synthetase • Peptidyl transferase • Synthesis terminates when STOP codon is reached

26. Posttranslational Processing • Most lose • Folding begins • Disulfide-bridging • Quaternary structures assembled

27. Control at every step • Not every cell expresses every gene • Specialized • Repressor proteins • Inducer proteins

28. Mutations • Error in base sequence • Substitution (point) mutations • Frameshift mutations

29. Spontaneous Mutations and Mutagens • Spontaneous mutations • Sodium nitrite • In processed meats • Converts cytosine to uracil • Overall danger thought to be low • Reduces occurrence of botulism

30. Spontaneous Mutations and Mutagens • Benzopyrene • Found in car exhaust, tobacco smoke, burnt meats • Radiation

31. Silent Mutations • Base-sequence errors that don’t affect organism • 64 codons for 20 amino acids • Change may be in unimportant region • Genes have 2 or more copies

32. Mutations • Somatic cells • Germ cells

33. Antibiotics • Chemicals to fight infection • Block protein synthesis • Must finish whole course • Bacteria • Antibiotic resistant bacteria

34. Viruses • DNA or RNA with protein coat • No functions outside cell • Enter cell and “hijack” it • Each virus attacks only specific cells • TMV • AIDS

35. DNA Viruses • Enter host cell and nucleus • Insert themselves into • Hiding inside cell – hard for immune system to detect • Can stay indefinitely

36. RNA Viruses • Enters cell • Directs synthesis of • Uses machinery of host to make copies of itself

37. Retroviruses • Special RNA virus • Enters cell and directs synthesis of viral DNA using reverse transcriptase • DNA inserts into host genome • Can hide or remain dormant for long periods of time • HIV

38. Treatment • Antibiotics don’t work • Body doesn’t recognize virus once hiding in host cell • Best method:

39. Recombinant DNA Technology • Began in mid-70s • Transplanting or altering of DNA • Benefits • Therapeutic drugs • Improvements to crops and herds • Curing/treating of genetic diseases

40. Production of human insulin • First application of recombinant DNA technology • Uses yeast and bacteria as vehicle • Bacteria have genomic DNA and a plasmid • Less side effects than cow or pig insulin

41. Process Identify gene encoding wanted protein • Isolate this gene from the donor DNA • Splice into plasmid (vector DNA) • Restriction enzymes • Recombinant DNA (new plasmid) back into E. coli • Chemical shock • Heat shock

42. Other techniques • Microinjections • Direct injection of DNA into nucleus of another cell • Cloning ~~~ Dolly • Viral vectors • Altered virus (usually retrovirus) • Carries new DNA to host cell • Research now for cystic fibrosis

43. A Little More About Cloning • Enucleation of cell: • http://gslc.genetics.utah.edu/units/cloning/whatiscloning/images/enucleation.mpg • Nuclear Transfer: • http://gslc.genetics.utah.edu/units/cloning/whatiscloning/images/transfer.mpg • Cloning “Practice”: • http://gslc.genetics.utah.edu/units/cloning/clickandclone/

44. Transgenic Breeding • Organisms with altered DNA • Grow faster, larger, etc. • Resistant to pests • http://www.pbs.org/wgbh/harvest/engineer/transgen.html • Many already in your supermarket

45. Gene Therapy • Human Genome Project • Finished with sequence • Now identify genes and proteins • Insert correct gene for defective one • Modified adenovirus (common cold) • Aerosol spray inhaled • Injection into bloodstream • Incubation of cells

46. Ethical Considerations • Effects of recombinant DNA? • Can we test people for diseases? • Alzheimer’s; Huntington’s • Gene Therapy • Enhance intelligence, strength • Pick eye color • Who will benefit? Will anyone suffer?

47. Internet Sites of Interest • PBS Site about GMOs • http://www.pbs.org/wgbh/harvest/ • Genetic Science Learning Center • http://www.pbs.org/wgbh/harvest/ • NWABR • http://www.nwabr.org