1. Albia Dugger Miami Dade College Cecie Starr Christine Evers Lisa Starr www.cengage.com/biology/starr Chapter 9 From DNA to Protein (Sections 9.1 - 9.3)

2. 9.1 Ricin and Your Ribosomes Ricin, a natural protein in castor oil beans, is highly toxic: A dose as small as a few grains of salt can kill an adult Ricin inactivates ribosomes – organelles that assemble amino acids into proteins Proteins are critical to all life processes, so cells that cannot make them die very quickly

3. Ricin One of ricin’s polypeptide chains helps the molecule cross cell membranes The other chain destroys a cell’s capacity for protein synthesis

4. 2.2 Nature of Genetic Information DNA contains all of the instructions for building a new individual The linear order or sequence of the four bases (A, T, G, C) in the DNA strand is the genetic information, which occurs in subsets called genes gene Part of a DNA base sequence Specifies an RNA or protein product

5. Converting a Gene to RNA Transcription converts information in a gene to RNA Enzymes use the nucleotide sequence of a gene as a template to synthesize a strand of RNA (ribonucleic acid) transcription Process by which an RNA is assembled from nucleotides using the base sequence of a gene as a template

6. Three Types of RNA Three types of RNA have roles in protein synthesis: Ribosomal RNA (rRNA) is the main component of ribosomes, the structures upon which polypeptide chains are built Transfer RNA (tRNA) delivers amino acids to ribosomes in the order specified by a messenger RNA (mRNA)

7. Key Terms messenger RNA (mRNA) Type of RNA that carries a protein-building message ribosomal RNA (rRNA) Type of RNA that becomes part of ribosomes transfer RNA (tRNA) Type of RNA that delivers amino acids to a ribosome during translation

8. RNA Structure RNA is a single-stranded chain of four kinds of nucleotides Like DNA, a RNA nucleotide has three phosphate groups, a sugar, and one of four bases, but RNA is slightly different: The sugar in RNA is ribose, not deoxyribose RNA uses the base uracil instead of thymine

9. An RNA and a DNA Nucleotide

10. Fig. 9.2a, p. 138 An RNA Nucleotide

11. Fig. 9.2a, p. 138 A Guanine, one of the four nucleotides in RNA. The others (adenine, uracil, and cytosine) differ only in their component bases (blue). Three of the four bases in RNA nucleotides are identical to the bases in DNA nucleotides. An RNA nucleotide: guanine (G), or guanosine triphosphate (GTP) sugar (ribose) 3 phosphate groups base (guanine) An RNA Nucleotide

12. Fig. 9.2b, p. 138 A DNA Nucleotide

13. Fig. 9.2b, p. 138 B Compare the DNA nucleotide guanine. The only difference between the RNA and DNA versions of guanine (or adenine, or cytosine) is the hydrogen atom or hydroxyl group at the 2’ carbon of the sugar (shown in green). A DNA nucleotide: guanine (G), or deoxyguanosine triphosphate (dGTP) sugar (deoxyribose) 3 phosphate groups base (guanine) A DNA Nucleotide

14. DNA and RNA Compared

15. Fig. 9.3, p. 139 A DNA has one function: It permanently stores a cell’s genetic information, which is passed to offspring. B Different types of RNA have different functions. Some serve as disposable copies of DNA’s genetic message; some are catalytic; others have roles in gene control. base pair sugar– phosphate backbone nucleotide base RNA ribonucleic acid DNA deoxyribonucleic acid Nucleotide bases of DNA Nucleotide bases of RNA thymine T cytosine C guanine G adenine A uracil U DNA and RNA Compared

16. Fig. 9.3a, p. 139 DNA

17. Fig. 9.3a, p. 139 A DNA has one function: It permanently stores a cell’s genetic information, which is passed to offspring. base pair sugar– phosphate backbone nucleotide base DNA deoxyribonucleic acid Nucleotide bases of DNA thymine T cytosine C guanine G adenine A DNA

18. Fig. 9.3b, p. 139 RNA

19. Fig. 9.3b, p. 139 sugar– phosphate backbone nucleotide base Nucleotide bases of RNA cytosine C guanine G adenine A uracil U RNA ribonucleic acid B Different types of RNA have different functions. Some serve as disposable copies of DNA’s genetic message; some are catalytic; others have roles in gene control. RNA

20. Converting mRNA to Protein Translation converts information in an mRNA to protein mRNA carries a protein-building message encoded in the sequence of sets of three nucleotide bases mRNA is decoded (translated) into a sequence of amino acids, resulting in a polypeptide chain that folds into a protein translation Process by which a polypeptide chain is assembled from amino acids in the order specified by an mRNA

21. Gene Expression Transcription and translation are part of gene expression, a process by which information encoded by a gene is converted into a structural or functional part of a cell or a body gene expression Process by which the information in a gene becomes converted to an RNA or protein product

22. Key Concepts DNA to RNA to Protein The sequence of amino acids in a polypeptide chain corresponds to a sequence of nucleotide bases in DNA called a gene The conversion of information in DNA to protein occurs in two steps: transcription and translation

23. 9.3 Transcription During transcription, DNA acts as a template upon which a strand of RNA (transcript) is assembled from RNA nucleotides Each new RNA is complementary in sequence to the DNA template: G pairs with C; A pairs with U (uracil) RNA polymerase adds nucleotides to the end of a growing transcript

24. 3 Steps in Transcription Transcription begins with a gene on a chromosome: RNA polymerase and several regulatory proteins attach to a specific binding site (promoter) in the DNA

25. 3 Steps in Transcription 2. RNA polymerase starts moving along the DNA, in the 3' to 5’ direction over the gene, unwinding the double helix to “read” the base sequence of the DNA strand

26. 3 Steps in Transcription RNA polymerase bonds free RNA nucleotides into a chain, in the order dictated by that DNA sequence, making an RNA copy of the gene

27. Fig. 9.4.1, p. 140 RNA polymerase binds to a promoter in the DNA. The binding positions the polymerase near a gene. In most cases, the base sequence of the gene occurs on only one of the two DNA strands. Only the DNA strand complementary to the gene sequence will be translated into RNA. promoter sequence in DNA gene region RNA polymerase 1 3 Steps in Transcription

28. Fig. 9.4.2, p. 140 2 The polymerase begins to move along the DNA and unwind it. As it does, it links RNA nucleotides into a strand of RNA in the order specified by the base sequence of the DNA. The DNA winds up again after the polymerase passes. The structure of the “opened” DNA at the transcription site is called a transcription bubble, after its appearance. DNA unwindingDNA winding up RNA 3 Steps in Transcription

29. Fig. 9.4.3, p. 140 3 Zooming in on the gene region, we can see that RNA polymerase covalently bonds successive nucleotides into an RNA strand. The base sequence of the new RNA strand is complementary to the base sequence of its DNA template strand, so it is an RNA copy of the gene. direction of transcription 3 Steps in Transcription

30. RNA polymerase binds to a promoter in the DNA. The binding positions the polymerase near a gene. In most cases, the base sequence of the gene occurs on only one of the two DNA strands. Only the DNA strand complementary to the gene sequence will be translated into RNA. promoter sequence in DNA gene region RNA polymerase 1 Stepped Art Fig. 9.4, p. 140 2 The polymerase begins to move along the DNA and unwind it. As it does, it links RNA nucleotides into a strand of RNA in the order specified by the base sequence of the DNA. The DNA winds up again after the polymerase passes. The structure of the “opened” DNA at the transcription site is called a transcription bubble, after its appearance. DNA unwindingDNA winding up RNA 3 Zooming in on the gene region, we can see that RNA polymerase covalently bonds successive nucleotides into an RNA strand. The base sequence of the new RNA strand is complementary to the base sequence of its DNA template strand, so it is an RNA copy of the gene. direction of transcription 3 Steps in Transcription

31. ANIMATION: Gene transcription details To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

32. Finishing Transcription When the polymerase reaches the end of the gene, the DNA and the new RNA strand are released Typically, many polymerases transcribe a particular gene region at the same time, so many new RNA strands can be produced very quickly

33. Key Terms RNA polymerase Enzyme that carries out transcription promoter In DNA, a sequence to which RNA polymerase binds

34. Gene Transcription Three genes next to one another on the same chromosome are being transcribed simultaneously

35. Fig. 9.5, p. 141 RNA transcriptsDNA molecule Gene Transcription

36. Post-Transcriptional Modifications Eukaryotes modify their RNA inside the nucleus, then ship it to the cytoplasm Introns are nucleotide sequences that are removed from a new RNA, and exons are sequences that stay in the RNA Sometimes, some exons are removed and the remaining exons are spliced together (alternative splicing) which enables one gene to encode different proteins

37. Key Terms intron Nucleotide sequence that intervenes between exons and is excised during RNA processing exon Nucleotide sequence that is not spliced out of RNA during processing alternative splicing RNA processing event in which some exons are removed or joined in various combinations

38. Post-Transcriptional Modifications New transcripts that will become mRNAs are further modified after splicing A modified guanine “cap” is added to the 5’ end, which will help the mRNA bind to a ribosome A tail of 50-300 adenines (poly-A tail) is added to the 3’ end

39. Post-Transcriptional Modifications

40. Fig. 9.6, p. 141 intron gene promoterexonintron DNA transcription exonintronexon intronexon new transcript finished RNA cappoly-A tail RNA processing Post-Transcriptional Modifications

41. ANIMATION: Pre-mRNA transcript processing To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

42. Key Concepts DNA to RNA: Transcription During transcription, one strand of a DNA double helix serves as a template for assembling a single, complementary strand of RNA (a transcript) Each transcript is an RNA copy of a gene

43. ANIMATION: Overview of transcription To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

44. ANIMATION: Transcription - A molecular view To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

45. ANIMATION: Transcription - Introns and exons To play movie you must be in Slide Show Mode PC Users: Please wait for content to load, then click to play Mac Users: CLICK HERECLICK HERE

46. ANIMATION: Transcription