DNA

1. Human Development Gene Therapy DNA Fingerprinting Evolution DNA Cloning Genetic Diseases Individualism Human Genome Project

2. THE BIG PICTURE DNA is the recipe for Life Each person has a unique sequence of DNA Each person to have a unique collection of proteins Each person having a unique appearance and behavior which causes which contributes to

4. Imagine that the genome is a book… • There are 23 chapters called CHROMOSOMES • Each chapter contains several thousand stories called GENES • Each story is made up of paragraphs called EXONS, which are interrupted by advertisements called INTRONS • Each word is written in letters called BASES

5. Proteins which are linear sequences of amino acids DNA contains a linear base code that… G - C Amino acid T - A Controls production of… C - G Amino acid A - T A - T Amino acid

6. Three nucleotides in DNA code for one amino acid in a protein Sequence of bases in DNA are read as triplet codes codes for C G C T A A C G A Amino acid Amino acid Amino acid

7. From Gene to Protein:Part 1 – Transcription Making mRNA Chapter 17 A-B

8. Garrod (1909) • 1st to suggest genes dictate phenotypes via enzymes that catalyze certain cell reactions • “Inborn error of metabolism” • Have a disease = cannot make an enzyme • i.e. Alkaptonuria • Proteins seem to be the link between genotype and phenotype!!!

9. Biochemistry Arises (1930s) • Degradation and creation of organic molecules in cells through metabolism • Catalyzed by specific enzymes • i.e. eye color pigments in fruit flies

10. Beadle and Tatum (1930s) • Studied a type of bread mold (Neurospora crassa) • Wild type: synthesized organic molecules from minimal salts media • Mutant: made by x-rays – could not survive b/c could not make these molecules • Hypothesized that 1 gene creates 1 enzyme • In this case, enzyme needed to catalyze a reaction to make molecules for survival

11. Figure 17.1 Beadle and Tatum’s evidence for the one gene-one enzyme hypothesis

12. 1 gene, 1 enzyme • This theory revised over and over again • Now: 1 gene, 1 polypeptide • b/c not all enzymes are proteins

13. DNA vs. RNA

14. DNA vs. RNA

15. So how exactly are proteins made? DNA  RNA  Polypeptide  Protein  Phenotype Transcription Translation Modification Expression

16. DNA & PROTEIN SYNTHESIS

17. TRANSCRIPTION • Process of using DNA as template to create RNA (message) • RNA is not identical to DNA • It is complementary b/c of base-pairing rules

18. Steps of Transcription • Initiation • Initiation complex binds to DNA at specific sequence • Elongation • Creation of pre-mRNA • Termination • Release of pre-mRNA

19. What is RNA polymerase? • Enzyme that pries DNA apart and puts together RNA nucleotides as it moves along DNA template • Moves 3’ – 5’ of template • 5’ – 3’ RNA growth • In prokaryotes – there is only 1 RNA polymerase • In eukaryotes – RNA Polymerase II does this

20. TRANSCRIPTION: INITIATION • Promoter – RNA polymerase binds to this site, upstream from terminator • Contains sequences for • RNA polymerase to bind • Which strand of DNA is the template • Where transcription begins on DNA • TATA box and TATA Binding Protein • In eukaryotes: transcription factors must help RNA polymerase II bind to promoter • In prokaryotes: RNA polymerase binds itself

21. TATA Box • 5’ TATAAA 3’ (or some variant) • 3+ adenine bases • 25-35 bp upstream of transcription site • TATA Binding Protein (TBP) • Helps unwind helix • Easy b/c 2 hydrogen bonds • About 50% promoters lack TATA box • But they have “initiator element” or “downstream core promoter” • And still use TBP

22. Eukaryotic Transcription Factors • Collection of proteins that help RNA polymerase II bind to DNA template and start transcription • After these proteins bind and RNA polymerase binds to DNA, it is called the Transcription Initiation Complex

23. TRANSCRIPTION: ELONGATION • RNA polymerase moves along DNA template • Adding RNA nucleotides • Remember SUGARS!!! • DNA double helix reforms as RNA polymerase 3’-5’ • New RNA strand peels from DNA

24. Several Proteins at Once! • Cells can increase the production of proteins at one time, using the same gene • Several RNA strands made using the same gene • RNA polymerases follow each other down DNA strand much like cars on highway

25. TRANSCRIPTION: TERMINATION • Termination sequence in DNA • RNA polymerase “stops” transcribing • In prokaryotes – polymerase usually stops right after the signal, leaves and DNA closes • In eukaryotes – polymerase continues transcribing several 100 bases past stop signal • AAUAAA pre-mRNA end • Polymerase continues about 10-35 bases after this signal

26. Eukaryotic Post-Transcriptional Modifications • 5’ cap • GTP added • Protection of mRNA from degradation • Signal for ribosome attachment in cytoplasm • 3’ end • Poly(A) tail • 50-250 Adenine nucleotides • Protection from degradation • May help export mRNA from nucleus

27. Eukaryotic Post-Transcriptional Modifications: RNA Splicing • Non-coding segments interspersed between coding segments of pre-mRNA • Therefore, need to be spliced out • Introns – “intervening segments” • Specific sequence codes surround introns for splicing to occur (“GU/AG” rule) • Exons – “expressed segments” • Spliced back together once introns are taken out to make final mRNA

28. Why do we have introns? • Regulatory roles in cell • Some genes are “coding” • Control mRNA to leave nucleus • Same gene – more than one polypeptide • Alternative RNA splicing • Facilitate evolution of new and potentially useful proteins • Increase potentially beneficial cross over or more places for cross over, leading to new proteins

29. How does splicing occur? • Spliceosome • snRNPs – small nuclear ribonucleoproteins • pronounced “snurps” • Made of protein and RNA • snRNA – thought to have catalytic activity • Proteins – ones in snRNPs and other proteins • Cuts specific sites (GU/AG) and rejoins exons

30. Spliceosomes – oval shaped • Bar = 50nm

31. Final mRNA Produced • Every 3 nucleotides codes for 1 amino acid • Start, stop, and 20 aa • Codon • Leaves nucleus (polyA to 5’ cap) • Cytoplasm and recruits ribosomal subunits

32. Figure 17.4 The dictionary of the genetic code

34. Code evolved early in life • Code is nearly universal • Simplest bacteria to complex plants and animals • Present in common ancestors • Few exceptions • Paramecium, chloroplasts, and mitochondria • Genes can be transcribed and translated after they are transplanted from one species to another • Insert human insulin gene into bacteria