the history of dna structure discovery
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The History of DNA Structure Discovery. 1869 – Friedrich Miescher. Studied the nuclei of white blood cells Isolated the material using HCl (aq) and digestive proteins Named the substance nuclein Found the material was rich in nitrogen and phosphorus. 1919 – Pheobus Levene. - PowerPoint PPT PresentationTRANSCRIPT
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1869 – Friedrich MiescherStudied the nuclei of white
blood cells Isolated the material using
HCl(aq) and digestive proteins
Named the substance nuclein
Found the material was rich in nitrogen and phosphorus
![Page 3: The History of DNA Structure Discovery](https://reader035.vdocuments.site/reader035/viewer/2022062500/56814f73550346895dbd27dc/html5/thumbnails/3.jpg)
1919 – Pheobus LeveneDiscovered that DNA
was made up of chains of nucleotides
ACID
DEOXYRIBOSE
NITROGENRICH
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1920 – DNA vs Protein
thought that 4 nucleotides were connected in the same repeated pattern
protein have 20 amino acids which could be combined in many combinations
RNA DNA
sugar
location
bases
RNA DNA
sugar ribose deoxyribose (one less oxygen)
location
bases
RNA DNA
sugar ribose deoxyribose (one less oxygen)
location mainly outside nucleus mainly inside nucleus
bases
RNA DNA
sugar ribose deoxyribose (one less oxygen)
location mainly outside nucleus mainly inside nucleus
bases AGCU AGCT
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Nucleotide Pattern
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1928 – Frederick Griffithstudied two strains of
pneumococcus bacteria
rough strain = nonvirulentinjection into mouse did not
result in death
smooth strain = virulentinjection caused mouse to
die
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Griffith’s Experiment
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Griffith’s Conclusionssome “factor” from the dead, virulent smooth strain
“transformed” the living, non-virulent rough strain
non-virulent rough strain picked up DNA to become virulent
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1930 – Joachim Hammerling
nucleus at bottom of stalk
Acetabularia – type of alga
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Hammerling’s Experiment
Hereditary information is stored in the nucleus.
no regrowth
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1940s – Joshua Lederbergdemonstrated
bacterial conjugationbacteria can exchange
DNA
bacteria have no nucleus or chromosomes
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1940s – Edwin Chargafffor all organisms
A = T and G = C
Chargaff’s Rule
organisms with more Gs and Cs tend to be more complex
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1952 – Hershey & Chaseconducted
experiments to definitively show that DNA is the hereditary material
bacteriophage used to infect bacteriabacterial virus
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CH2CH
OH
O
CHO
CH2
CH2 NH3+ C-O CH2
O
CH2SSCH2
CH
CH3
CH3
H3C
H3C
Hydrophobic interactions and van der Waalsinteractions Polypeptid
ebackbone
Hyrdogenbond
Ionic bond
CH2
Disulfide bridge
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X-ray Crystallographyphysics approach to examining biological molecules
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Rosalind Franklin’s X-raysThe photo indicated:1. Backbone of alternating phosphate and sugars
2. Backbone is a helical structure
3. Double helix structure (molecule is a uniform helix)
4. Nitrogenous bases are in the middle of the molecule
5. Bases are at right angles to the backbone
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Base Pairing
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1953 – James Watson & Francis Crickinspired by alpha-helix model of proteins
determined how A + T and G + C bonded together
width of purine + pyrimidine bonds fit perfectly between the sugar-phosphate backbone (DNA width = 2 nm)
the double helix model offered an easy method for replication
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DNA Backbonealternating sugar-
phosphate backbonesugar and phosphate
backbone attached by a phosphodiester bond
DNA is said to be read from 5’ to 3’
opposing backbones are antiparallel
5’
3’
1’
2’
4’
1’
2’
4’
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Complementary Base PairingChargaff’s Rule
adenine : thymine (1:1)guanine : cytosine (1:1)
the diameter of a base pair is 2 nm
3 H-bonds between G&C2 H-bonds between A&T
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Overall DNA Structureright handed helix
0.34 nm between adjacent base pairs
one turn of the helix is 10 base pairs (3.4 nm)
0.34 nm
3.4 nm
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HomeworkAnswer questions pg. 209 #1-4Read section 4.2Answer questions pg. 216 #1-9