1. Central dogma: from genome to proteins I: Transcription Haixu Tang School of Informatics

2. The flow of genetic information

3. Transcription: DNA  RNA Copy a particular portion of its DNA nucleotide sequence a gene into an RNA nucleotide sequence. The information in RNA, although copied into another chemical form, is still written in essentially the same language as it is in DNA the language of a nucleotide sequence.

4. Genes can be expressed with different efficiencies

5. The structure of RNA

6. RNA (single strand) can fold into specific structure

7. DNA transcription produces a single-stranded RNA molecule, complementary to one strand of DNA

8. RNA polymerase uses DNA as template

10. DNA polymerase vs. RNA polymerase RNA polymerase is more error prone: 10 -4 vs 10 -7 A modest proofreading mechanism RNA stores information only temporarily

11. Principal Types of RNAs Produced in Cells Table 6-1. Principal Types of RNAs Produced in Cells mRNAsmessenger RNAs, code for proteins rRNAsribosomal RNAs, form the basic structure of the ribosome and catalyze protein synthesis tRNAstransfer RNAs, central to protein synthesis as adaptors between mRNA and amino acids snRNAssmall nuclear RNAs, function in a variety of nuclear processes, including the splicing of pre-mRNA snoRNAssmall nucleolar RNAs, used to process and chemically modify rRNAs Other noncoding RNAsfunction in diverse cellular processes, including telomere synthesis, X-chromosome inactivation, and the transport of proteins into the ER © 2002 by Bruce Alberts, Alexander Johnson, Julian Lewis, Martin Raff, Keith Roberts, and Peter Walter. TYPE OF RNA FUNCTIO N

12. The transcription cycle

13. Initiating signal

15. Directions of transcription

16. Types of RNA polymerases in eukaryotic cells TYPE OF POLYMERASEGENES TRANSCRIBED RNA polymerase I5.8S, 18S, and 28S rRNA genes RNA polymerase IIall protein-coding genes, plus snoRNA genes and some snRNA genes RNA polymerase IIItRNA genes, 5S rRNA genes, some snRNA genes and genes for other small RNAs

17. Several important differences between the bacterial and eucaryotic RNA polymerases..While bacterial RNA polymerase (with  factor as one of its subunits) is able to initiate transcription on a DNA template in vitro without the help of additional proteins, eucaryotic RNA polymerases cannot. They require the help of a large set of proteins called general transcription factors, which must assemble at the promoter with the polymerase before the polymerase can begin transcription. Eucaryotic transcription initiation must deal with the packing of DNA into nucleosomes and higher order forms of chromatin structure, features absent from bacterial chromosomes.

18. Initiation of transcription of a eucaryotic gene by RNA polymerase II

19. Consensus sequences found in the vicinity of eucaryotic RNA polymerase II start points

20. 3D structure of TBP (TATA- binding protein) bound to DNA

21. Transcription initiation

22. Supercoiling of DNA

23. Transcription in Eukaryotic cells

24. RNA processing: pre-RNA  mature RNA 5’ Cap Poly-A Splicing Editing Coupled with elongation

25. 5’ Cap of RNA

26. Splicing

27. Splicing reactions and Lariats

28. Splicing signals

29. Alternative splicing

30. The RNA splicing mechanism

31. Variation in intron and exon lengths

32. Splicing errors

33. Additional factors for correct splicing site recognition RNA factory concept Exon definition hypothesis

34. The "RNA factory" concept

35. The exon definition hypothesis

36. Three major type of splicing mechanism

37. Abnormal splicing cause disease

38. Self splicing

39. PolyA addition

40. Exportation of mature RNA