DNA Structure, Genetic Information, and Gene Concept

Chapter 15 EXPRESSION of BIOLOGICAL INFORMATION

DNA & Genetic Information Objectives • to describe the structure of DNA based on the • Watson & Crick model • to explain DNA as the carrier of genetic • information • to explain the concept of one gene one • polypeptide

DNA STRUCTURE • Watson and Crick Model • Monomer : NUCLEOTIDE • Component : Deoxyribose (pentose sugar) Phosphate group Nitrogenous base : Adenine (A) Thymine (T) Guanine (G) Cytosine (C) *Base pairing rule : A-T and C-G

DNA NUCLEOTIDE

WATSON AND CRICK MODEL • DNA : 2 polynucleotide chain • Arrange in double helix • Antiparallel (3’ to 5’) and (5’ to 3’) • Each polynucleotide chain attach to another • polynucleotide chain by hydrogen bond • Nucleotide link by alternating sugar-phosphate • backbone : phosphodiester bond

DNA as carrier of genetic information • Experiments are conducted by Frederick Griffith • (1928) and Avery(1944) • Griffith: Identify transformation process • Avery et.al. : identify the transformation agent

DNA: The Carrier of Genetic Information • Griffith (1928) • - studied Streptococcus pneumoniae; • bacterium that causes pneumonia to mammals • two strains (varieties) of S. pneumoniae: • R (rough) strain • mutant strain • non-capsulated • non-virulent (non-pathogenic) • S (smooth) strain • capsulated • virulent (pathogenic / causing disease)

DNA: The Carrier of Genetic Information 2 1

DNA: The Carrier of Genetic Information 3 4 Transformation occur

DNA: The Carrier of Genetic Information • transformation occur; live R strain is transformed • into live S strain by hereditary material obtained • from the dead strain-S cells • the hereditary substance was unknown • the transformed bacteria reproduce forming • S strain daughter cells (heritable)

DNA: The Carrier of Genetic Information Definition • a change in genotypes and phenotypes of an • individual • due to the assimilation of foreign DNA by a cell. S strain R strain

DNA: The Carrier of Genetic Information Transformation agent • In 1944, Oswald Avery, Maclyn McCarty and • Colin McLeod proved that DNA was the • transforming substance. • Two models of the experiment were carried • out.

DNA: The Carrier of Genetic Information Transformation agent • Experiment 1 • heat-killed the S strain bacteria culture • purify the culture; removeproteins, • carbohydrates, lipids, RNA and DNA • add proteins, carbohydrates, lipids, RNA and • DNA to different cultures of living R strain Observation : After a few days, colonies of S strain grew in the R strain culture that was added with DNA

15.1 DNA: The Carrier of Genetic Information Transformation agent • Experiment 1 The observation • After a few days, colonies of the S strain • grew in the R strain culture which had • DNA added.

DNA: The Carrier of Genetic Information Transformation agent S colonies extracts are added to different cultures of R strain carbohydrate lipid protein RNA DNA no change no change no change no change S strain found Transformation

DNA: The Carrier of Genetic Information Transformation agent • Experiment 2 Enzyme Treatment The Procedures • The purified DNA of the S strain bacterium • was mixed with the R strain colonies. 2. Different enzymes were added to the different mixture. 3. Bacteria colony was grown in different culture.

DNA: The Carrier of Genetic Information Transformation agent • Experiment 2 Procedures The enzymes added: • protease - degrades proteins • ribonuclease - RNase - degrades RNA • deoxyribonuclease - DNase - degrades DNA

Experiment 2 R Strain R colonies DNA from heat-killed S cells no colonies Serum that precipitates R cells from mixture DNA from heat-killed S cells + + Living R Strain S colonies (transformation)

Experiment 2 S colonies 1 transformation Serum that precipitates R cells from mixture DNA from heat-killed S cells + + + protease R strain 2 transformation Serum that precipitates R cells from mixture DNA from heat-killed S cells + + RNase + R strain S colonies 3 Serum that precipitates R cells from mixture DNA from heat-killed S cells + + DNase + R strain NO colonies

DNA: The Carrier of Genetic Information Transformation agent • Experiment 2 The Inferences • The protease and the RNasefailed to stop • the transformation of the R strain into the • S strain by the purified DNA. • The DNase destroyed the transforming • activity of the purified DNA preparation.

DNA: The Carrier of Genetic Information Transformation agent • Experiment 2 The Conclusion • DNA is the carrier of genetic information • DNA from the capsulated bacteria (S strain) • carries the gene that encode the production of • capsule • During transformation, the DNA is assimilated by • DNA of R strain; enables R strain to synthesize • capsule

Gene concept: One-Gene-One-Polypeptide • George Beadle and Edward Tatum (1941) • study the relationship between genes and • enzymes • by using Neurosporacrassa(bread mold) • fungi (Ascomycota / sac fungi) Fungi that produce spores in structures called sacs

Gene concept: One-Gene-One-Polypeptide Beadle & Tatum experiment Medium needed: Minimal medium consists of agar, glucose, inorganic salts and vitamin biotin Complete medium consists of agar, glucose, inorganic salts, vitamin biotin and 20 amino acids.

Gene concept: One-Gene-One-Polypeptide Procedures • some conidia (asexual spores) were exposed • to X-ray; to induce mutation

Gene concept: One-Gene-One-Polypeptide Procedures • conidia (mutant) were transferred to complete • mediumand grown; mycelia formed • mycelia (from mutant conidia) were crossed with • mycelia (from wild type conidia). • wild type conidia are NOT exposed to X-ray

Gene concept: One-Gene-One-Polypeptide • producing asci (sin. ascus) that consist of eight • ascospores(four ascospores from each parental • mycelia – mutant and wild type)

Gene concept: One-Gene-One-Polypeptide Procedures • the ascospores were dissected out and • transferred to complete medium. • ALL grew and formed mycelia • mycelia were placed • on minimal medium • NO growth occur

Gene concept: One-Gene-One-Polypeptide • mycelia which did no grow were unable to • synthesize certain amino acids • to determine which amino acids were • synthesized, mycelia were transferred to minimal • media each containing a different amino acid • amino acid test

Gene concept: One-Gene-One-Polypeptide Observations • the medium in which growth occur, contain the • amino acid which the mutantNeurospora • unable to synthesize

Gene concept: One-Gene-One-Polypeptide Conclusion • the mutantNeurospora was defective in • biochemical pathway to synthesize arginine • does not have the enzyme to synthesize arginine • due to lacks ofgene that encodes the enzyme • results in the mutant could ONLY grow with the • supply of arginine “ One GENE ; One ENZYME ”

Restatement • NOT all proteins are enzymes • e.g keratin (structural protein) • insulin (peptide hormone) • proteins that AREN’T enzymes also encoded by • genes  “ One GENE ; One PROTEIN ” • proteins are composed of different polypeptide • chains (e.g hemoglobin) • each polypeptide chain is encoded by gene  “ One GENE ; One POLYPEPTIDE ”

Gene concept: One-Gene-One-Polypeptide From further experiments Beadle and Tatum concluded that • the defect is in the biochemical pathways • that normally synthesize arginine

DNA Structure, Genetic Information, and Gene Concept

DNA Structure, Genetic Information, and Gene Concept

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Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

CHAPTER 15

Chapter 15

Chapter 15

chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15:

Chapter 15-

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15