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12–1 DNA
Slide 3 of 37
Griffith and Transformation
Griffith and Transformation
In 1928, British scientist Fredrick Griffith was trying to learn how certain types of bacteria caused pneumonia.
He isolated two different strains of pneumonia bacteria from mice and grew them in his lab.
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12–1 DNA
Slide 4 of 37
Griffith and Transformation
Griffith made two observations:
(1) The disease-causing strain of bacteria grew into smooth colonies on culture plates.
(2) The harmless strain grew into colonies with rough edges.
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12–1 DNA
Slide 5 of 37
Griffith and Transformation
Griffith's Experiments
Griffith set up four individual experiments.
Experiment 1: Mice were injected with the disease-causing strain of bacteria. The mice developed pneumonia and died. (The smooth strain is lethal)
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12–1 DNA
Slide 6 of 37
Griffith and Transformation
Experiment 2: Mice were injected with the harmless strain of bacteria. These mice didn’t get sick. (The rough strain)
Harmless bacteria (rough colonies)
Lives
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12–1 DNA
Slide 7 of 37
Griffith and Transformation
Experiment 3: Griffith heated the disease-causing bacteria. He then injected the heat-killed bacteria into the mice. The mice survived.
(Heat killed the smooth strain)
Heat-killed disease-causing bacteria (smooth colonies)
Lives
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12–1 DNA
Slide 8 of 37
Griffith and Transformation
Experiment 4: Griffith mixed his heat-killed, disease-causing bacteria with live, harmless bacteria and injected the mixture into the mice. The mice developed pneumonia and died.
Live disease-causing bacteria(smooth colonies)
Dies of pneumonia
Heat-killed disease-causing bacteria (smooth colonies)
Harmless bacteria (rough colonies)
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12–1 DNA
Slide 9 of 37
Griffith and Transformation
Griffith concluded that the heat-killed bacteria passed their disease-causing ability to the harmless strain.
Live disease-causing bacteria(smooth colonies)
Heat-killed disease-causing bacteria (smooth colonies)
Harmless bacteria (rough colonies)
Dies of pneumonia
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12–1 DNA
Slide 10 of 37
Griffith and Transformation
Transformation
Griffith called this process transformation because one strain of bacteria (the harmless strain) had changed permanently into another (the disease-causing strain).
Griffith hypothesized that a factor must contain information that could change harmless bacteria into disease-causing ones.
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12–1 DNA
Slide 11 of 37
Avery and DNA
Avery and DNA
Oswald Avery repeated Griffith’s work to determine which molecule was most important for transformation.
Avery and his colleagues made an extract from the heat-killed bacteria that they treated with enzymes.
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12–1 DNA
Slide 12 of 37
Avery and DNA
The enzymes destroyed proteins, lipids, carbohydrates, and other molecules, including the nucleic acid RNA.
Transformation still occurred.
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12–1 DNA
Slide 13 of 37
Avery and DNA
Avery and other scientists repeated the experiment using enzymes that would break down DNA.
When DNA was destroyed, transformation did not occur. Therefore, they concluded that DNA was the transforming factor.
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12–1 DNA
Slide 14 of 37
Avery and DNA
What did scientists discover about the relationship between genes and DNA?
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12–1 DNA
Slide 15 of 37
Avery and DNA
Avery and other scientists discovered that the nucleic acid DNA stores and transmits the genetic information from one generation of an organism to the next.
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12–1 DNA
Slide 16 of 37
The Hershey-Chase Experiment
The Hershey-Chase Experiment
Alfred Hershey and Martha Chase studied viruses—nonliving particles smaller than a cell that can infect living organisms.
They did this at Cold Spring Harbor labs onLong Island. See the blender picture on the wall.
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12–1 DNA
Slide 17 of 37
The Hershey-Chase Experiment
Bacteriophages
A virus that infects bacteria is known as a bacteriophage.
Bacteriophages are composed of a DNA or RNA core and a protein coat.
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12–1 DNA
Slide 18 of 37
The Hershey-Chase Experiment
When a bacteriophage enters a bacterium, the virus attaches to the surface of the cell and injects its genetic information into it.
The viral genes produce many new bacteriophages, which eventually destroy the bacterium.
When the cell splits open, hundreds of new viruses burst out.
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12–1 DNA
Slide 19 of 37
The Hershey-Chase Experiment
If Hershey and Chase could determine which part of the virus entered an infected cell, they would learn whether genes were made of protein or DNA.
They grew viruses in cultures containing radioactive isotopes of phosphorus-32 (32P) and sulfur-35 (35S).
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12–1 DNA
Slide 20 of 37
The Hershey-Chase Experiment
If 35S was found in the bacteria, it would mean that the viruses’ protein had been injected into the bacteria.
Bacteriophage withsuffur-35 in protein coat
Phage infects bacterium
No radioactivity inside bacterium
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12–1 DNA
Slide 21 of 37
The Hershey-Chase Experiment
If 32P was found in the bacteria, then it was the DNA that had been injected.
Bacteriophage withphosphorus-32 in DNA
Phage infects bacterium
Radioactivity inside bacterium
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12–1 DNA
Slide 22 of 37
The Hershey-Chase Experiment
Nearly all the radioactivity in the bacteria was from phosphorus (32P).
Hershey and Chase concluded that the genetic material of the bacteriophage was DNA, not protein.
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12–1 DNA
Slide 23 of 37
The Components and Structure of DNA
What is the overall structure of the DNA molecule?
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12–1 DNA
Slide 24 of 37
The Components and Structure of DNA
The Components and Structure of DNA
DNA is made up of nucleotides.
A nucleotide is a monomer of nucleic acids made up of a five-carbon sugar called deoxyribose, a phosphate group, and a nitrogenous base.
So 3 parts, a sugar phosphate and a base. Say it.
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12–1 DNA
Slide 25 of 37
The Components and Structure of DNA
There are four kinds of bases in in DNA:
• adenine
• guanine
• cytosine
• thymine
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12–1 DNA
Slide 26 of 37
The Components and Structure of DNA
Purines have two rings, pyrimidines have one.
Pyrimidines have the letter “Y” in them, so cytosine and Thymine are pyrimidines.
• Adenine (a purine) no “y”
• guanine (a purine) no “y”
• Cytosine a pyrimidines because it has a “Y”
• Thymine same as above
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12–1 DNA
Slide 27 of 37
The Components and Structure of DNA
The backbone of a DNA chain is formed by sugar and phosphate groups of each nucleotide.
The nucleotides can be joined together in any order.
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12–1 DNA
Slide 28 of 37
The Components and Structure of DNA
Chargaff's Rules
Erwin Chargaff discovered that:
• The percentages of guanine [G] and cytosine [C] bases are almost equal in any sample of DNA.
• The percentages of adenine [A] and thymine [T] bases are almost equal in any sample of DNA.
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12–1 DNA
Slide 29 of 37
The Components and Structure of DNA
X-Ray Evidence
Rosalind Franklin used X-ray diffraction to get information about the structure of DNA.
She aimed an X-ray beam at concentrated DNA samples and recorded the scattering pattern of the X-rays on film.
B form picture
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12–1 DNA
Slide 30 of 37
The Components and Structure of DNA
The Double Helix
Using clues from Franklin’s pattern, James Watson and Francis Crick built a model that explained how DNA carried information and could be copied.
Watson and Crick's model of DNA was a double helix, in which two strands were wound around each other.
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12–1 DNA
Slide 31 of 37
The Components and Structure of DNA
DNA Double Helix
2 hydrogen bonds 2 hydrogen bonds with an A & Twith an A & T
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12–1 DNA
Slide 32 of 37
The Components and Structure of DNA
Watson and Crick discovered that hydrogen bonds can form only between certain base pairs—adenine and thymine, and guanine and cytosine.
This principle is called base pairing.
There are two hydrogen bonds between A & T
3 Hydrogen bonds between G & C
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12–1 DNA
Slide 33 of 37
The Components and Structure of DNA
Franklin showed that the strands run in opposite directions. It is called anti parallel.
Not Uncle Joe but anti parallel.
One side runs up, one side runs down.
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Slide 35 of 37
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Avery and other scientists discovered that
a. DNA is found in a protein coat.
b. DNA stores and transmits genetic information from one generation to the next.
c. transformation does not affect bacteria.
d. proteins transmit genetic information from one generation to the next.
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Slide 36 of 37
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The Hershey-Chase experiment was based on the fact that
a. DNA has both sulfur and phosphorus in its structure.
b. protein has both sulfur and phosphorus in its structure.
c. both DNA and protein have no phosphorus or sulfur in their structure.
d. DNA has only phosphorus, while protein has only sulfur in its structure.
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Slide 37 of 37
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DNA is a long molecule made of monomers called
a. nucleotides.
b. purines.
c. pyrimidines.
d. sugars.
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Slide 38 of 37
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Chargaff's rules state that the number of guanine nucleotides must equal the number of
a. cytosine nucleotides.
b. adenine nucleotides.
c. thymine nucleotides.
d. thymine plus adenine nucleotides.
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Slide 39 of 37
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In DNA, the following base pairs occur:
a. A with C, and G with T.
b. A with T, and C with G.
c. A with G, and C with T.
d. A with T, and C with T.
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