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Molecular Biology I. Introduction A. History

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1 Molecular Biology I. Introduction A. History
1. J. Meischer (1868) found a consistent band rich in acid-phosphates from cellular samples. 2. F. Griffith (1928) showed that protein was not the inherited molecule.

2 3. E. Chagraff (1942) showed that in DNA T=A and G=C.
4. S. Luria, M. Delbrook, A. Hershey, and M. Chase (1952) found that DNA was the inherited molecule. Figure 11.4

3 6. J. Watson & F. Crick (1953) built a model of DNA.
5. R. Franklin (1952) found that DNA had a uniform diameter, helical shape, and repeatable sequences.. 6. J. Watson & F. Crick (1953) built a model of DNA. Figure 11.4

4 II. DNA Replication A. Definition and When? B. Rules
1. Directional: build DNA 5’ to 3’ read 3’ to 5’ 2. Semi-conservative Figure 11.5 Figure 11.6

5 C. Process by Enzyme Players
1. DNA Helicase Un-winds DNA to form replication bubbles. 2. RNA Primase lays down short RNA sequences against DNA. Figure 11.7

6 3. DNA Polymerase III reads 3’ to 5’ direction and lays down 5’ to 3’ direction. Leading edge vs. Lagging edge (Okasaki fragments). 4. DNA Polymerase I edits, excises, and DNA Ligase folds the strands together (new to old).

7 III. Genetic Code A. DNA  RNA  Protein Why? B. Triplet Code
Figure 11.9

8 C. Specific Codes = Start, Stops, and Special
Figure 11.10

9 IV. Transcription A. Definition & Players B. Process
1. Initiation  transcription factors attach, unwind, and orient RNA polymerase along the DNA strands. Figure 11.11

10 2. Elongation  RNA polymerase reads DNA and lays down bases.
Which direction? 3. Termination  initiation factors recognize and release the RNA polymerase 4. Modification of RNA Which direction? Figure 11.12

11 V. Translation A. Definition & Players B. Process
1. Initiation == rRNA reads start codon on mRNA and attaches, first tRNA lands to match it’s anti-codon to codon. Figure 11.14

12 2. Elongation  matching tRNA’s anti-codon to mRNA’s codons within the ribosome as the ribosome (rRNA) slides along the mRNA. Figure 11.15 Codon Chart Figure 11.10

13 4. Modification  cutting and folding of new protein.
3. Termination  ribosome reads a stop codon, protein is released from the last tRNA, release tRNA, and remove ribosome. 4. Modification  cutting and folding of new protein. Figure 11.16

14 C. Organelles Nucleus & Ribosomes!
1. Intracellular What organelles are involved in building proteins which are to be used by the cell? Nucleus & Ribosomes! 2. Extracellular What organelles are involved in building proteins which are to be put into vacuoles for shipping or retention? Nucleus, Ribosomes, rER, Golgi, & Vacuoles!

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