1. 1 DNA that contains functional information for the synthesis of RNA or Protein → gene Ribosomal RNA’s (rRNA’s)→ complex that synthesizes proteins Messenger RNAs (mRNA’s) → intermediaries → carrier of genetic Info. from 1 or may genes to the ribosome Transfer RNA’s (t-RNAs) → translate mRNA to protein sequence Nucleotides and Nucleic Acids

2. 2 Nucleotides have 3 features: Nitrogen containing bases Pentose (5 C- sugar) Phosphate moiety Molecule WITHOUT Nucleoside PO 4 → Nucleoside NB: ‘ (primers) give to distinguish from C in purine/pyrimidines Ester bond bond

3. 3 Purine and Pyrimidine Bases Purine and Pyrimidine Bases N-  -glycosyl bond with the 1’ C in the pentose (previous slide) Break double bond Proton extraction Pentose + Purine/Pyrimidine O-glycosidic bond (Nucleoside) + phosphate Nucleotide

4. 4 Purines Purines BOTH Present in BOTH DNA and RNA (A) (G)

5. 5 Pyrimidines Pyrimidines BOTH Cytosine (C) found in BOTH DNA and RNA ONLY Thymine (T) found ONLY in DNA ONLY Uracil (U) found ONLY in RNA Distinguishing features A, T G and C nucleotides → genetic information

6. 6 Two kinds of Pentoses present…… Two kinds of Pentoses present…… H Deoxy → deoxyribo(nucleotides/sides) → ribo(nucleotides/sides)

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9. 9 Phosphodiester Bonds link Successive Nucleotides in Nucleic acids Phosphodiester Bonds link Successive Nucleotides in Nucleic acids DNA and RNA nucleotides linked via PO 4 - grp 5’→ 3’-OH grp of the next nucleotide (phosphodiester linkage) Backbone of alternative linkages b/w PO 4 and pentose grps Backbone is hydrophilic → -OH in CHO/carbohydrate undertake H-H bonding with H 2 O PO 4 gp pK a = 0, pH 7 → -ve charged → interactions with +ve charges (proteins/metals/polyamines) [Expt. - Adding salt interfers with these interactions = ability to separate DNA from other cellular constituents] ALL phosphodiester linkage have the SAME orientation 5’ → 3’ (polarity) 5’ end → LACKS a nucleotide at position 5’ 3’ end → LACKS a nucleotide at position 3’

10. 10 DNA/RNA Slow/non-enzymatic hydrolysis Breaking phosphodiester bonds RNA is more unstable → rapid breakdown in base (via the 2’-OH) NOT DNA does NOT (2’-OH gp is absent)

11. 11 RNA Breakdown

12. 12 pA-C-G-T-A OH pApCpGpTpA pACGTA Written in the 5’→ 3’ direction (left to right) Oligonucleotides ( 50 – polynucleotides) Nomenclature of nucleotides – what’s in a name… Maybe written as:

13. MBBE 402 Lecture 1513

14. 14 DNA is “defined” DNA base composition varies at a inter-special level Same species, different tissues have the same DNA base composition DNA base composition does not change ALL DNA follows these simple rules: A = T G = C Sum of purines = Sum of pyrimidines: A + G = T + C (Chargeff’s rules) The famous double helix – solved by x-ray diffraction; insight that molecule was helical; 2 periodicities 3.4Å and 34Å Solve the structure? A = T G = C DNA Structure DNA Structure

15. 15 Watson and Crick – the master the minds of the jigsaw puzzle Watson and Crick – the master the minds of the jigsaw puzzle 2 helical DNA chain wound around an axis, forming a right handed double helix Hydrophobic backbone of alternative deoxyribose and PO 4 gr on outside Pyrimidines/purines stacked inside the double helix (hydrophobic and planar ring structure perpendicular to long axis Offset pairing of 2 stands causes major and minor groove Each paired nucleotide shares the same plane 3 H-H bonds b/w G/C ( G≡C) ;2 b/w A/T (A=T) DNA with high G≡C content difficult to denature 10 base pairs/turn* *crystal form

16. 16 Complementary strands; two anti-parallel strands containing not identical base bases, yet base pair which fit the A=T and G≡C rules of engagement. Replication

17. 17 The Chemical Properties of DNA The Chemical Properties of DNA Highly viscous at Room Temp., pH 7.0  pH or Temp. (>80oC) →  in viscosity Reflect in structural changes Denaturation Melting → disruption of H-H bonding b/w base pairs DS → SS (no covalent bonds are broken) Renaturation is a rapid one step process in undone DS DNA Temp/pH return to physiological conditions → annealing → intact DS In SS DNA, two step process which is slower: “finding” then “zippering” DS – double stranded SS – single stranded

18. 18 Free nucleotides have the highest UV Absorbance (Abs.) Once in sequence, stacking of the base pairs ↓ the Abs. (same number/types of nucleotides as above) Abs. is ↓↓ with complementary pair formation Denaturation of DS ↑ Abs. HYPERCHROMIC EFFECT Thus transition from DS to SS can be monitored by UV Abs. Some areas more susceptible to denaturation that others… Here we can measure the increase and decrease in DNA DS and SS via UV light

19. 19 DNA (viral/Bacterial) denature when heated slowly Each DNA species has a specific denaturation temp. (T m ) which is reflective of the base pair composition Higher G≡C content; higher T m (3 H-H bonds) A=T bonds require less  H to denature T m determination can provide estimation of base-pair content Region with high T=A, denature first (“bubbles”)

20. 20 Nucleic Acids from different species can form Hybrids Nucleic Acids from different species can form Hybrids The process of complementary sequences in DNA strands can be used to detect similar DNA via duplex formation Denaturing and renealling, complementary regions will bind/seek each other.. Small % will form a mixture of two strands from  species – hybrid duplexes→ common evolutionary Heritage, conserved proteins (i.e. conserved DNA/RNA) Gene detection – hybridize ‘seeking’ labeled nucleotide sequence which are site specific. CSI – DNA matching (bone fragments etc.) See changes in UV abs. Thus know if you have a ‘match’ Only small No. will form hybrids

21. 21 UV light/radiation…..(200-400nm) UV light/radiation…..(200-400nm) 2 adjacent Ts Breaking double bond Dimer Similar effect: Radiation (C 14, H 3, X-rays etc.) Chemicals/alkylating agents Carcinogens

22. 22 What does it mean?

23. 23 Sequencing DNA via Sanger Method Sequencing DNA via Sanger Method Separating and identifying DNA strands that differ by a single nucleotide via gel electrophoresis Primer stand has single “non-native” Nucleotides added to it

24. 24 H Stops DNA synthesis → a freeze frame of the process of DNA\sequence chain elongation P OH BASE (radio labeled nucleotide analogue) Add these to our growing sequence (Dideoxynucleoside)

25. MBBE 402 Lecture 1525 Analyze the primer at different stages of 5’ chain elongation Different masses separate Labeled Nucleotides Freeze frame

26. 26 Nucleotides carry chemical energy in cells Nucleotides carry chemical energy in cells Mono-PO 4 Di-PO 4 Tri-PO 4 Sequential hydrolysis Energy

27. 27 ATP is the most common source for driving energy requiring cellular R x ATP is the most common source for driving energy requiring cellular R x Phosphoanhydride bonds = 30 KJ/mol = 14 KJ/mol

28. 28 Adenine Nucleotide are components for many Enzymes cofactors Adenine Nucleotide are components for many Enzymes cofactors Removal of Adenine → loss of co-factor activity (Vitamin B 2 )

29. 29 cAMP, cGMP and ppGpp – used in extracellular chemical signaling cAMP, cGMP and ppGpp – used in extracellular chemical signaling Secondary messengers – target specific membrane bond receptors, which active a cascade of internal cellular events via G-coupled proteins. (bacteria)