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20.1a History of DNA and Structure Cell Division, Genetics, Molecular Biology
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DNA Deoxyribonucleic acid (DNA) Found in nucleus of all organisms (within chromosomes) DNA only molecule capable of replicating itself Contains instructions that ensure continuity of life - coded within chemical messages of DNA - regulates the production of proteins Ability to change due to mutations and new combinations of genes
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Frederich Miescher 1869 – extracted viscous white substance from bandages of wounded soldiers - slightly acidic, phosphorus & nitrogen rich - called it nuclein Nuclein composed of acidic portion (nucleic acid) and alkaline portion (protein) Single nucleic acid was later shown to be 2 nucleic acids - deoxyribonucleic acid (DNA) - ribonucleic acid (RNA) DNA material of heredity: early focus was on proteins
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Joachim Hammerling Acetabularia: green algae, 3 distinct regions (cap, stalk, foot) Nucleus in foot: cut off cap and new cap regenerated, cut off foot, no new foot regeneration Suggested hereditary material located in nucleus
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Frederick Griffith Lab Exercise pg 644 Streptococcus pneumoniae – 2 forms - virulent: S-form (coated) - harmless: R-form S-form cells heated and killed, injected into mice and they lived Heated cells mixed with R-form cells, killed mice Concluded there must be something chemical altering the living cells: transformation - transformed into virulent cells
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Avery, McCarty, MacLeod Lab Exercise pg 645 1944 – experiments with Streptococcus pneumoniae in test tubes Treated heat-killed virulent bacteria with a protein- destroying enzyme: transformation still occurred Treated heat-killed virulent bacteria with DNA-destroying enzyme: transformation DID NOT occur Concluded DNA was “transforming principle” - likely source of hereditary information
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Alfred Hershey & Martha Chase 1952 – used bacteriophages (virus) that infect bacterial host (2 components: DNA and protein coat) Infects by injecting DNA into it, virus multiplies within and then bursts out, killing the cell Hershey & Chase concluded that only the DNA, not protein coat, enters bacteria - tagged viral proteins with isotope of sulfur (not component of DNA) - tagged viral DNA with isotope of phosphorus (component of DNA) Allowed tagged bacteriophage to infect bacterial cell Cells blended to remove protein coats and centrifuged to isolate virus from bacteria
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Bacterial cells found to contain isotope of phosphorus, not isotope of sulfur Isotope of sulfur found in culture medium Conclusion! DNA was hereditary material
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James Watson & Francis Crick Known that DNA comprised of chains of nucleotides - consist of 5-carbon cyclic ring: deoxyribose sugar - one of 4 nitrogenous bases attached to 1’ carbon - phosphate group attached to 5’ carbon 4 bases: adenine (A), guanine (G), thymine (T), cytosine (C) - A & G: purines (double ring) - C & T: pyrimidines (single ring) Evidence from Edwin Chargaff: calculated that amount of adenine always equal to amount of thymine (same for guanine and cytosine). Observed for almost all species Evidence from Rosalind Franklin: x-ray diffraction, photograph taken - shows that DNA was a helix, likely double-stranded
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James Watson & Francis Crick All the evidence compiled, Watson & Crick created a 3D model Portrayed relationship between bases as well as bond angles and spacing of atoms - consistent with observations from other researchers to that point Won Nobel Prize in 1962 along with Maurice Wilkins (researcher in charge of Rosalind Franklin’s work) Rosalind Franklin left out – she died prior to 1962
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DNA Structure 2 strands of nucleotides Each nucleotide contains: - deoxyribose sugar - phosphate group - nitrogenous base Covalently bonded into double helix like a twister ladder - hydrogen bonds keep helix together Base pairs are rungs, sugar/phosphate backbones are struts Complementary base pairing to form rungs - A pairs with T - C pairs with G
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DNA Structure
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Opposite strand always have the complementary sequence of bases 5’ – ATGCCGTTA – 3’ 3’ – TACGGCAAT – 5’ Antiparallel: run parallel but in opposite directions - one strand has 5’ carbon & phosphate group at one end and 3’ carbon & hydroxyl group of deoxyribose sugar at other end - other strand runs opposite 3’ to 5’ Direction important to enzymes interacting with DNA - only read or copy DNA in one direction DNA Structure
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Nobel Prize - DNA
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