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Published byBertram Peters Modified over 9 years ago
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1 Nucleic acids: DNA and RNA Done By Majed Felemban
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2 DNA Double helix –2 chains Building blocks –Nucleotides DNA directs –Is own replication –Directs RNA synthesis → protein synthesis Campbell and Reece, P86
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3 In Eukaryotes (animals, plants, fungi) Complete human genome
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4 In Prokaryotes (bacteria, archaea) Main chromosome is one large, continuous loop –Hundreds to thousands of genes May have smaller loops, with a few genes each –May be swapped between bacteria –Antibiotic resistance, etc.
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5 Replication Transcription Translation
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6 Roles of Nucleic Acids DNA –Responsible for inheritance –Codes for proteins and functional RNAs Genes –Regulatory sequences Control which genes are transcribed, and when –Other unknown functions 80-90% of the human genome has no known function Campbell and Reece, P86, 87
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7 Roles of Nucleic Acids RNA –Information transmission (mRNA) –Processing and transport (tRNA, rRNA, snRNA) –Catalytic (ribozymes) –Regulation and feedback (siRNA) –Unit of inheritance (retroviruses) –Other…? Campbell and Reece, P86, 87
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8 Nucleic Acid chemistry is the same for all life on earth. DNA & RNA are polymers of monomers - nucleotides. Each nucleotide has three components (Deoxy)ribonucleic Acid NUCLEIC ACID STRUCTURES Campbell and Reece, 86 2. (DEOXY)RIBOSE SUGAR = STRUCTURAL 3. NITROGENOUS BASES = INFORMATIONAL X X 1. PHOSPHORIC ACID = STRUCTURAL
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9 Campbell and Reece, P87
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10 Phosphoric Acid & Related Compounds Phosphoric acid is Triprotic. Reacts with CHO’s or alcohols to form esters. D
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11 Phosphoric Acid & Related Compounds Phosphoric acid is Triprotic. Reacts with alcohols to form esters. As found in DNA & RNA at pH7 -
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12 The sugar may be Ribose (in RNA) or Deoxyribose (in DNA) H RiboseDeoxyribose Phosphate can covalently bond to C 3 and C 5 Bases (A,C,G,T or U) can covalently bond to C 1
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13 Bases in DNA and RNA (RNA)(DNA)
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14 A Base Joined To A Ribose Sugar Is Called A Nucleoside Pyrimidines bond at N-1 to C-1’ Purines bond N-9 to 1’ Carbon of sugar The carbons in the ribose are now designated as C prime (or C’) to distinguish them from those in the base. or H
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15 When Phosphate is Bound to a Nucleoside it is Called a Nucleotide ATP, GTP, CTP, UTP (NTPs) are substrates for RNA synthesis dATP, dGTP, dCTP, dTTP (dNTPs) are substrates for DNA synthesis
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16 Mononucleotides as they Occur in DNA & RNA DNA RNA A,C,G or T (DNA) or A,C,G or U (RNA) All nucleotides are asymmetrical
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17 5’C = Four Nucleotides With 5’ to 3’ Phosphodiester Linkages 3’C = DNA & RNA are Polymers of Nucleotides All DNA and RNA polymers are asymmetrical with 5’ to 3’ direction.
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18 Properties of DNA and RNA They may be informational eg genomic DNA, mRNA. They may be structural eg rRNA & tRNA. Retain 5’& 3’ molecular orientation due to nucleotide asymmetry. They are often single stranded (typically RNA). They may be extremely long. Movie*Movie* Two polymers (or strands) may become double stranded when certain conditions are met ie they are antiparallel & complementary in nucleotide sequence (typically nuclear DNA). * Terao et al., 2008: Lab on a chip DOI: 10.1039/b803753a
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19 Duplex DNA is Antiparallel Duplex DNA is NEVER Parallel! 5’Phosphate 3’OH 5’Phosphate or 5’ 3’ 5’ or
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20 Duplex DNA has Complementarity because of Hydrogen Bonds H bonds are weak (~1/20 th of a covalent bond): –Often allows transient contact between molecules (biological signalling systems). –May allow stable contact that can be disrupted and reformed (eg DNA).
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21 Hydrogen Bonds Form between O &/or N with H between them eg O-H … O, N … H-N or O-H … N. Are due to electrostatic forces. H is slightly +ve. O &/or N are slightly -ve. Are very weak compared to covalent bonds May be broken & reform under various chemical or physical conditions.
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22 Two representations of duplex DNA showing: H bonds between bases and, Covalently bonded Sugar Phosphate backbones. ~10 basepairs per turn of the helix. Duplex DNA width = 2nm.
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23 Double Stranded (or Duplex) DNA Is characteristic of genomic DNA. Consists of two separate nucleic acid polymers (“strands”). The two strands are Antiparallel wrt 5’& 3’ ends. They are held together by Hydrogen Bonds between the bases. H-Bond energies are weak BUT there are many of them which makes the duplex DNA very stable. Bases are Complementary such that: – A always pairs with T (2 H Bonds). – C always pairs with G (3 H Bonds). Two strands of complementary antiparallel DNA form a Double Helix eg as found in a chromosome.
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24 History of The Double Helix of DNA The structure of the double helix was found by Rosalind Franklin using X-ray crystallography and correctly interpreted by Watson & Crick in 1953 who also used Chargaff’s rule. The bases are Hydrophobic and are in the Centre of the helix where complementary bases pair via H-bonding. The Ribose Sugar and Phosphate groups are on the Outside of the helix where they can H bond to polar solvents like water.
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25 Xray diffraction pattern of DNA similar to Franklin’s data (above, 1953). Watson & Crick’s structure for DNA Key data that Watson & Crick worked with Chargaff’s Rule: there is a 1:1 ratio of purines to pyrimidines (because A=T, G C always).
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