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Transcript
DNA Reading Assignment: • Read pages 287-290 and prepare to discuss. • If you complete that before we are ready to discuss, please read through the rest of the section, page 294. Questions: • What organelle is known as the “control center” of the cell? ▫ Nucleus • What structures are found in the nucleus? ▫ Chromosomes (Chromatin, DNA) • What are located on chromosomes? ▫ Genes • What are chromosomes composed of? ▫ DNA (wound around proteins) • How do genes and chromosomes control the activity of a cell? ▫ By producing proteins that regulate the cellular functions or become part of the cell structure. Vocabulary • Transformation • Bacteriophage • Nucleotide • Base pairing What was Griffith trying to do? • Trying to learn whether or not a toxin produced by the bacteria was the cause of pneumonia. • What are some questions he could ask? Look at figure 12-2, page 288 • What was Griffith trying to learn when he set up this experiment? ▫ How bacteria caused pneumonia • How did Griffith show that the disease-causing bacteria were killed by the heat? ▫ He tried to grow them in a petri dish. If the bacteria didn’t grow, then he knew he had killed it. • What result was Griffith expecting when he injected the mixture of live harmless bacteria and the heat-killed disease-causing bacteria? ▫ The mouse to live. Immunizations • How many of you remember getting immunizations? • How do immunizations work? ▫ Immunizations are toxoids or inactivated toxins from the toxins that are produced by the bacteria that make us sick. • Why do you think it’s important to learn how bacteria cause disease? ▫ To find a cure for the disease, or a means to prevent it. • This was what Griffith was doing! • He was showing how a toxin that is produced by the bacteria causes pneumonia. • Then Avery expanded upon his work… He wanted to know what was most important for this transformation to occur. ▫ He isolated items and destroyed them, till he found the one item, that when destroyed …. Transformation no longer occurred. ▫ What was that item? DNA Hershey-Chase Experiment • A Bacteriophage is a virus that infects and kills a bacteria. Hershey-Chase Experiment How did they get the parts of the Bacteriophage radioactive? • They soaked the bacteriophages in the radioactive isotopes – Because DNA has Phosphorus already, it incorporated the radioactive Phosphorus. • They did the same with another set of bacteriophages with ulfur, and because the protein coat already contains sulfur, it incorporated the radioactive sulfur. DNA History • Griffith – ▫ Experiment: Using mice, he observed transformation – Live harmless bacteria transformed into disease causing bacteria. ▫ Live, Disease Causing Bacteria ▫ Live, Harmless Bacteria ▫ Dead (Heat Killed) Disease Causing Bacteria ▫ Dead (Heat Killed) Disease Causing Bacteria mixed with Live Harmless Bacteria Griffith Experiment (Pneumonia) More DNA History • Avery– • Experiment: Concluded that the genetic material in bacteria was DNA not proteins ▫ Repeated Griffith’s experiments with enzymes • • • • • Destroy proteins Destroy lipids Destroy carbohydrates Destroy RNA Destroy DNA • Hershey - Chase– ▫ Experiment: Used Bacteriophages to show that DNA is what stores and transmits the genetic information from one generation to the next. ▫ P32 (Phosphorus 32) Radioactive marker attached to DNA inside of Bacteriophage ▫ S35 (Sulfur 35) Radioactive marker attached to protein coat of Bacteriophage The Discovery of DNA • Rosalind Franklin – made x-ray of DNA • J. Watson & F. Crick – made the 1st model of the structure of DNA! (using R. Franklin’s x-ray) Watson & Crick DNA Watson & Crick – created the double helix model for DNA. Structure of DNA • DNA is a long molecule made up of units called nucleotides. • Each nucleotide is made up of three parts: ▫ a 5-carbon sugar called deoxyribose, ▫ a phosphate group, and ▫ a nitrogenous base (Nitrogen Containing). • The backbone of DNA: sugar and phosphate groups • The nitrogenous base stick out from the sides and can be joined together in any order, meaning that any sequence of bases is possible. Nitrogenous Bases • There are four kinds of nitrogenous bases. • They are divided into two classes: purines and pyrmidines ▫ Purines – Adenine and Guanine ▫ Pyrimidines – Cytosine and Thymine Structure of DNA Shape = Double Helix Made up of nucleotides: deoxyribose, phosphate group, and a nitrogenous base (A, T, C, or G) Chargaff’s Rules • Chargaff discovered how the nitrogenous bases bond together. • He discovered that Adenine always bonds with Thymine and that Cytosine always bonds with Guanine. Double Ring Single Ring The Nucleotides Phosphate – sugar “backbone” The sugars also attach to the bases. Bases attach to each other by a weak hydrogen bond. The 2 strands are “complementary” to each other. (base pair rule!!!) What is the base pair rule? Adenine (purine) connects to Thymine (pyrimidine) A-T Guanine(purine) connects to Cytosine (pyrimidine) G-C Prokaryotes & DNA • In prokaryotes, DNA molecules are located in the cytoplasm of the cell. • Most prokaryotic DNA is a single circular molecule that contains nearly all the cell’s genetic information. Eukaryotes & DNA • Many eukaryotes have 1000 times as much DNA as prokaryotes. • DNA is located in the nucleus in the form of chromosomes. • Chromosomes are DNA wound tightly around proteins called histones. DNA Length • E. Coli have about 4,639,221 base pairs. It is about 1.6mm in length. This sounds small until you realize the bacteria is only 1.6µm in diameter. • Thus DNA must be wrapped tightly to fit into cells. Imagine fitting 900 yards (300m) of rope into a backpack. DNA replication…… • Occurs during S phase of Interphase during the cell cycle. • Makes an exact copy of all DNA. DNA replication…… • Is “semiconservative” – 1 strand is “old” & the other strand is “new”. DNA Replication • The DNA molecule separates into two strands • Then produces two new complimentary strands following the rules of base pairing (Chargaff Rules). • Each strand of double helix of DNA serves as a template, or model, for the new strand. How It Occurs • DNA replication is carried out by a series of enzymes. • The enzymes unzip the DNA molecule creating two strands that serve as templates. • Complimentary bases are added to the strands ▫ Example: ATTCGAG . TAAGCTC. What is needed for replication? • Replication requires enzymes: 1) Helicase – unwinds . DNA 2) DNA polymerase . – puts new nucleotides . in place & proofreads Replication Review • Each new DNA molecule has one new strand and one strand from the original molecule. ▫ What is this called? ▫ Semi-conservative • The enzyme DNA polymerase, the principal enzyme, “proofreads” the new DNA strands, helping to maximize the odds that each molecule is a perfect copy of the original. ▫ This is what I call: “The Police” The process of DNA replication 1) DNA unwinds & unzips – uses Helicase 2) Replication fork forms (area where 2 strands separate) * there are several replication forks at the same time. 3) DNA polymerase adds new nucleotides to each DNA strand, following the base pair rule!
