1. Chapter 14 From DNA to Protein

2.  Ricin – comes from the castor oil plant  Inactivates ribosomes, the protein-building machinery of all cells Impacts, Issues: Ricin and Your Ribosomes

3. Marvelous Mussel Adhesive Marvelous Mussel Adhesive  Mussel binds itself to rocks with threads coated with the protein bysuss  Gene for bysuss has been put into yeast  Yeast synthesize the protein based on the instructions in the mussel DNA  WHY IS THIS POSSIBLE?

4. Central Dogma DNARNAPROTEIN TRANSCRIPTIONTRANSLATION

5. Same two steps produce all proteins: 1) DNA is transcribed to form RNA Occurs in the nucleus Occurs in the nucleus RNA moves into cytoplasm RNA moves into cytoplasm 2) RNA is translated to form polypeptide chains, which fold to form proteins Steps from DNA to Proteins

6. Three Classes of RNAs  Messenger RNA Carries protein-building instruction Carries protein-building instruction  Ribosomal RNA Major component of ribosomes Major component of ribosomes  Transfer RNA Delivers amino acids to ribosomes Delivers amino acids to ribosomes

7. A Nucleotide Subunit of RNA A Nucleotide Subunit of RNA phosphate group sugar (ribose)‏ uracil (base)‏ Fig. 14-2, p. 220

8. base pairing during transcription DNA RNA DNA base pairing during DNA replication Fig. 14-2c, p.220 Base Pairing during Transcription

9. Transcription & DNA Replication  Like DNA replication Nucleotides added in 5’ to 3’ direction Nucleotides added in 5’ to 3’ direction  Unlike DNA replication Only small stretch is template Only small stretch is template RNA polymerase catalyzes nucleotide addition RNA polymerase catalyzes nucleotide addition Product is a single strand of RNA Product is a single strand of RNA

10. Promoter  A base sequence in the DNA that signals the start of a gene  For transcription to occur, RNA polymerase must first bind to a promoter (Initiation)‏

11. Initiation promoter region RNA polymerase, the enzyme that catalyzes transcription a RNA polymerase initiates transcription at a promoter region in DNA. It recognizes a base sequence located next to the promoter as a template. It will link the nucleotides adenine, cytosine, guanine, and uracil into a strand of RNA, in the order specified by DNA. Fig. 14-3a, p.220

12. newly forming RNA transcript DNA template unwindingDNA template winding up DNA template at selected transcription site b All through transcription, the DNA double helix becomes unwound in front of the RNA polymerase. Short lengths of the newly forming RNA strand briefly wind up with its DNA template strand. New stretches of RNA unwind from the template (and the two DNA strands wind up again). Fig. 14-3b, p.220 Elongation

13. direction of transcription 3´ growing RNA transcript 5´ 3´ c What happened at the assembly site? RNA polymerase catalyzed the assembly of ribonucleotides, one after another, into an RNA strand, using exposed bases on the DNA as a template. Many other proteins assist this process. Fig. 14-3c, p.221 Adding Nucleotides

14. d At the end of the gene region, the last stretch of the new transcript is unwound and released from the DNA template. Shown below is a model for a transcribed strand of RNA. Fig. 14-3d, p.221 Termination

15. unit of transcription in a DNA strand exon intron mature mRNA transcript poly-A tail snipped out exon intron cap transcription into pre-mRNA Fig. 14-4, p.221 Transcript Modification

16. mRNA Modification  5' cap – modified guanine cap  3' poly-A tail  Introns = interuptions  Exits = exit  Alternative splicing

17. mature mRNA transcript 5’3’ poly-A tail 5’ snipped out ca p transcription into pre-mRNA unit of transcription in a DNA strand exonintronexon intron 3’ 5’ Stepped Art Fig. 14-4, p.221

18. Conference Assignment  Response paper: Find an article that relates to the conference. Find an article that relates to the conference. You will turn a copy of this in.You will turn a copy of this in. Basically a five paragraph essay: Basically a five paragraph essay: Summarize the articleSummarize the article How does this topic relate to the conferenceHow does this topic relate to the conference Your response to this topic (why is it important, etc)Your response to this topic (why is it important, etc)

19. Genetic Code  Set of 64 base triplets  Codons  61 specify amino acids  3 stop translation  High conserved Fig. 14-6, p.222

20. DNA mRNA codons threonineprolineglutamate lysine amino acids Fig. 14-5, p.222 Genetic Code

21. tRNA Structure codon in mRNA anticodon amino acid OH amino-acid attachment site Figure 14.7 Page 223

22. tRNA Structure  aa attachment site Attached by activating enzymes Attached by activating enzymes  There are 45 tRNA, not 64 as the genetic code would suggest, WHY? Wobble effect Wobble effect

23. funnel small ribosomal subunit large ribosomal subunit intact ribosome + Fig. 14-8, p.223 Ribosomes  2 units of rRNA and protein Large and small units converge when translating Large and small units converge when translating  Built in nucleus (nucleosome)‏

24. Three Stages of Translation OR Gum Drop Protein Synthesis Initiation InitiationElongationTermination

25. Overview Transcription Translation mRNA rRNAtRNA Mature mRNA transcripts ribosomal subunits mature tRNA

26. Initiation  Initiator tRNA binds to small ribosomal subunit  Small subunit/tRNA complex attaches to mRNA and moves along it to an AUG “start” codon  Large ribosomal subunit joins complex

27. Binding Sites binding site for mRNA P (first binding site for tRNA)‏ A (second binding site for tRNA)‏

28. Elongation  mRNA passes through ribosomal subunits  tRNAs deliver amino acids to the ribosomal binding site in the order specified by the mRNA  Peptide bonds form between the amino acids and the polypeptide chain grows

29. Elongation

30. Termination  Stop codon into place  No tRNA with anticodon  Release factors bind to the ribosome  mRNA and polypeptide are released new polypeptide chain mRNA

31. What Happens to the New Polypeptides?  Some just enter the cytoplasm  Many enter the endoplasmic reticulum and move through the cytomembrane system where they are modified

32. Gene Mutations  Base-Pair Substitutions or Point Mutations Insertions Insertions Deletions Deletions

33. Base-Pair Substitution original base triplet in a DNA strand During replication, proofreading enzymes make a substitution a base substitution within the triplet (red)‏ original, unmutated sequence a gene mutation possible outcomes: or

34. Frameshift Mutations  Insertion Extra base added into gene region Extra base added into gene region  Deletion Base removed from gene region Base removed from gene region  Both shift the reading frame  Result in many wrong amino acids

35. THREONINEPROLINEGLUTAMATE LYSINE THREONINEPROLINEVALINEGLUTAMATELYSINE THREONINEPROLINEGLYCINEARGININE part of DNA template mRNA transcribed from DNA resulting amino acid sequence base substitution in DNA altered mRNA altered amino acid sequence deletion in DNA altered mRNA altered amino acid sequence Fig. 14-10, p.226 Frameshift Mutation

36. Transposons  DNA segments that move spontaneously about the genome  When they insert into a gene region, they usually inactivate that gene

37. Transposons  Barbara McClintock  Nonuniform coloration of kernels in strains of indian corn Fig. 14-11, p.227

38. Mutation Rates  Each gene has a characteristic mutation rate Can be used as a molecular clock for evolution Can be used as a molecular clock for evolution  Average rate for eukaryotes is between 10 -4 and 10 -6 per gene per generation  Only mutations that arise in germ cells can be passed on to next generation

39. Mutagens  Ionizing radiation (X rays)‏  Nonionizing radiation (UV)‏  Natural and synthetic chemicals

40.  How can you explain the occurrence of birth defects (caused by altered genes) in children and grandchildren of the victims of the atomic bombs that destroyed Hiroshima and Nagasaki, Japan, when the victims themselves were only mildly affected?

41. Euk vs Prok Protein Synthesis  Most have introns  mRNA must be completely formed and pass thru nuclear membrane  mRNA modified before translation  Larger ribosomes  None (w/ exceptions)‏  Often start translation before transcription is done  Begin at AUG but proceeded by a special sequence  Small ribosomes