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Chapter 12: DNA & RNA Essential Questions: EQ: Why do you need DNA & RNA? EQ: How does the cell make protein? EQ: How do chromosomes carry traits? Georgia.

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Presentation on theme: "Chapter 12: DNA & RNA Essential Questions: EQ: Why do you need DNA & RNA? EQ: How does the cell make protein? EQ: How do chromosomes carry traits? Georgia."— Presentation transcript:

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2 Chapter 12: DNA & RNA Essential Questions: EQ: Why do you need DNA & RNA? EQ: How does the cell make protein? EQ: How do chromosomes carry traits? Georgia Performance Standards: Compare and contrast the structure and function of DNA and RNA. Explain how DNA stores and transmits cellular information.

3 Hook: Link cell organelles (nucleus-chp. 7) and macromolecules (nucleic acids- chp. 6) to DNA & RNA (chp. 12). Probing Questions –Where in the cell is DNA located for eukaryotes and prokaryotes? –DNA is what type of macromolecule? Carbohydrate Protein Lipid Nucleic Acid

4 Warm-up Review: Section 12-1 Go to Section: Macromolecules: –Carbohydrates (sugars) –Lipids –Proteins –Nucleic Acids (DNA & RNA)

5 Nucleic Acids Structure: –Contain hydrogen, oxygen, nitrogen, carbon, and phosphorus. –Monomers of nucleotides 5-carbon sugar Phosphate group Nucleotide Base Function: –Nucleic acids store and transmit hereditary, or genetic, information. Types: –Ribonucleic acid (RNA) –Deoxyribonucleic acid (DNA).

6 A Nucleotide (Monomers of Nucleic Acids):

7 DNA Nucleotides DNA is made up of a series of monomers called nucleotides. Each nucleotide has three parts: a deoxyribose molecule, a phosphate group, and a nitrogenous base. There are four different bases in DNA: Adenine & Guanine (Purines) Cytosine & Thymine (Pyrimidines)

8 The backbone of a DNA chain Formed by alternating sugar and phosphate groups of each nucleotide. The nitrogenous bases stick out sideways from the chain and are linked by hydrogen bonds. The nucleotides can be joined together in any order, meaning that any sequence of bases is possible.

9 Chargaff’s Rules Erwin Chargaff showed that the percentages of guanine and cytosine in DNA and adenine and thymine are almost equal. A=T (2 hydrogen bonds hold them together) G C (3 hydrogen bonds hold them together)

10 What Shape Does DNA Have? X-Ray Evidence –In the early 1950s, a British scientist named Rosalind Franklin began to study DNA. –She used a technique called X-ray diffraction to get information about the structure of the DNA molecule. – The angle of the X suggests that there are two strands in the structure. –Other clues suggest that the nitrogenous bases are near the center of the molecule.

11 What Shape Does DNA Have? The Double Helix Shape of DNA –Francis Crick and James Watson were trying to understand the structure of DNA by building three-dimensional models of the molecule. –Then, early in 1953, Watson was shown a copy of Franklin’s remarkable X-ray pattern. –Within weeks, Watson and Crick had figured out the structure of DNA. –Watson and Crick’s model of DNA was a double helix, in which two strands were wound around each other.

12 What is a Double Helix? A double helix looks like a twisted ladder or a spiral staircase. The double helix accounted for many of the features in Franklin’s X-ray pattern but did not explain what forces held the two strands together. Watson and Crick found the answer. They discovered that hydrogen bonds could form between certain nitrogenous bases and provide just enough force to hold the two strands together. The principle of base pairing (A-T and G-C), explained Chargaff’s rules.

13 DNA is a double helix in which two strands are wound around each other. Each strand is made up of a chain of nucleotides. The two strands are held together by hydrogen bonds between adenine and thymine and between guanine and cytosine.

14 Molecular Genetics Chapter 12

15 Molecular Genetics Orientation  On the top rail, the strand is said to be oriented 5′ to 3′.  The strand on the bottom runs in the opposite direction and is oriented 3′ to 5′. 12.1 DNA: The Genetic Material Chapter 12

16 Group Activity: Use plastic models to build a DNA structure. See WS

17 What Carries Genetic Material (DNA or Protein)? Many Experiments were carried out to verify that genetic material is carried by DNA and not protein. 1. Griffith and Transformation: DNA can be transformed (Video Clip) 2. Avery and other scientists discovered that DNA is the nucleic acid that stores and transmits the genetic information from one generation of an organism to the next. 3. Hershey and Chase used radioactive markers to label DNA & Protein, and concluded that the genetic material of the bacteriophage was DNA, not protein.

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19 Avery Repeats Griffith’s work. Why? to determine which molecule in the heat-killed bacteria was most important for transformation. If transformation required just one particular molecule, that might well be the molecule of the gene. Avery and his colleagues made an extract, or juice, from the heat-killed bacteria. He treated the extract with enzymes that destroyed proteins, lipids, carbohydrates, and other molecules, including the nucleic acid RNA. –Transformation still occurred. –Obviously these molecules were not responsible for the transformation. – If they had been, transformation would not have occurred, because the molecules would have been destroyed by the enzymes. He repeated the experiment, this time using enzymes that would break down DNA. –Transformation did not occur. –Therefore, DNA was the transforming factor.

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21 Pop Quiz 1.Describe Watson and Crick’s model of the DNA molecule. What was Rosalind Franklin’s contribution to the discovery of the shape of DNA? 2. What are the four kinds of bases found in DNA? Which ones are purines and which are pyrimadines? 3. How did Watson and Crick’s model explain why there are equal amounts of thymine and adenine in DNA? Hint: Chargaff's Rule 4. List the conclusions Griffith, Avery, Hershey, and Chase drew from their experiments. 5. Why did Hershey and Chase grow viruses in cultures that contained both radioactive phosphorus and radioactive sulfur? What might have happened if they had used only one radioactive substance?

22 12–2 Chromosomes and DNA Replication Prokaryotic cells –No nuclei and membrane-bound organelles found in eukaryotes. –DNA in the cytoplasm. –Most prokaryotes have a single circular DNA molecule called a plasmid. –The plasmid is considered the chromosome

23 Chromosome E. coli bacterium Bases on the chromosome Prokaryotic Chromosome Structure Go to Section:

24 DNA and Chromosomes Eukaryotic cells –DNA is in the nucleus –Chromosome form occurs during cell division –# of chromosomes varies from one species to the next. Humans have 46 Fruit flies have 8 –Chromosomes contain both DNA and protein, which is tightly packed together to form chromatin. Protein is called histone –The DNA and histone collectively are called nucleosomes fold long lengths of DNA into the tiny nucleus. –The nucleosomes are tightly packed to form supercoils

25 Chromosome Structure of Eukaryotes Chromosome Supercoils Coils Nucleosome Histones DNA double helix Section 12-2 Go to Section:

26 12-2 Warm-up: A Perfect Copy When a cell divides, each daughter cell receives a complete set of chromosomes. This means that each new cell has a complete set of the DNA code. Before a cell can divide, the DNA must be copied so that there are two sets ready to be distributed to the new cells.

27 12-2 Warm-up: 1.On a sheet of paper, draw a curving or zig-zagging line that divides the paper into two halves. Vary the bends in the line as you draw it. Without tracing, copy the line on a second sheet of paper. 2.Hold the papers side by side, and compare the lines. Do they look the same? 3.Now, stack the papers, one on top of the other, and hold the papers up to the light. Are the lines the same? 4.How could you use the original paper to draw exact copies of the line without tracing it? 5.Why is it important that the copies of DNA that are given to new daughter cells be exact copies of the original?

28 DNA Replication The double helical shape of DNA allows for strands to be copied. –Strands are considered to be complimentary DNA must be replicated (copied) before a cell divides. –The DNA molecule separates into 2 strands –2 new complimentary strands are produced –Each strand serves as a template for the new strand.

29 DNA Replication Section 12-2 Go to Section: Growth Replication fork DNA polymerase New strand Original strand DNA polymerase Nitrogenous bases Replication fork Original strand New strand

30 DNA Replication Prokaryotes –DNA replication begins at a single point in the chromosomes and proceeds in two directions until the entire chromosome is replicated. –Takes about 20 minutes Eukaryotes –DNA replication occurs in hundreds of places and proceeds in both directions until each chromosomes is completely copied –The sites where replication and separation occur are call replication forks.

31 How Does Replication Occur? Many enzymes are used –Some unzip the strands, some hold the strands open, some glue the strands together. –DNA Polymerase enzyme that adds the complimentary bases to each strand. Proofreads each strand –See video

32 12.2 Replication of DNA Molecular Genetics Semiconservative Replication  Parental strands of DNA separate, serve as templates, and produce DNA molecules that have one strand of parental DNA and one strand of new DNA. Chapter 12

33 Molecular Genetics Unwinding  DNA helicase, an enzyme, is responsible for unwinding and unzipping the double helix.  RNA primase adds a short segment of RNA, called an RNA primer, on each DNA strand. 12.2 Replication of DNA Chapter 12

34 Molecular Genetics Base pairing  DNA polymerase continues adding appropriate nucleotides to the chain by adding to the 3′ end of the new DNA strand. 12.2 Replication of DNA Chapter 12

35 Molecular Genetics  One strand is called the leading strand and is elongated as the DNA unwinds.  The other strand of DNA, called the lagging strand, elongates away from the replication fork.  The lagging strand is synthesized discontinuously into small segments, called Okazaki fragments. 12.2 Replication of DNA Chapter 12

36 Molecular Genetics Joining  DNA polymerase removes the RNA primer and fills in the place with DNA nucleotides.  DNA ligase links the two sections. 12.2 Replication of DNA Chapter 12

37 Checkpoint Questions: 1.Explain how DNA is replicated. 2.Where and in what form is eukaryotic DNA found? 3. How are the long DNA molecules found in eukaryotes packed into short chromosomes? 4. How are histones related to nucleosomes? 5. What is the role of DNA polymerase in DNA replication? 6. How is the structure of chromosomes in eukaryotes different from the structure of chromosomes in prokaryotes?

38 Warm-up: Compare and contrast the process of DNA replication in prokaryotes and eukaryotes. –Compare the location, steps, and end products in each kind of cell. Compare and contrast DNA in eukaryotes and prokaryotes (Structure and location) You may use a Venn diagram, a chart or table, a drawing, or write an essay.


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