DNA stands for Deoxyribonucleic Acid. DNA stands for Deoxyribonucleic Acid. DNA. DNA is often called the blueprint of life. The way that DNA controls the cell (and your body) is by determining what proteins to make and how they are built. This process is called Protein Synthesis. This process is called Protein Synthesis. 2 DNA Background

DNA is found in the nucleus of eukaryotic cells and in the cytoplasm of prokaryotic cells. DNA is found in the nucleus of eukaryotic cells and in the cytoplasm of prokaryotic cells. When viewed under a microscope, the DNA appears as long, dark strands or coils called chromosomes A chromosome is a tightly coiled strand of a long piece of DNA. (Like a spool of string) A chromosome is a tightly coiled strand of a long piece of DNA. (Like a spool of string) 3 DNA Background

DNA is a polymer that is incredibly long. The monomer of DNA is the nucleotide. DNA is a polymer that is incredibly long. The monomer of DNA is the nucleotide. The average human chromosome (long coiled strand of DNA) has 260 million nucleotides. The average human chromosome (long coiled strand of DNA) has 260 million nucleotides. Because of the incredible length of a strand of DNA, it is necessary to coil it into a chromosome structure to fit it within the cell’s nucleus. Each cell contains about 2 meters (6 feet) of DNA if it were stretched out into a long strand. Each cell contains about 2 meters (6 feet) of DNA if it were stretched out into a long strand. The combined length of DNA in the human body would stretch to the moon and back 170 times. The combined length of DNA in the human body would stretch to the moon and back 170 times. 4 DNA Structure

To understand DNA’s overall structure, you must understand the monomer structure (nucleotides). To understand DNA’s overall structure, you must understand the monomer structure (nucleotides). A nucleotide has 3 parts A nucleotide has 3 parts Phosphate group Phosphate group Pentose sugar Pentose sugar Nitrogen base Nitrogen base In drawings, the phosphate is usually round and symbolized with a letter P. In drawings, the phosphate is usually round and symbolized with a letter P. The pentose sugar should be drawn as a pentagon and usually labeled S, sugar, or pentose sugar. The pentose sugar should be drawn as a pentagon and usually labeled S, sugar, or pentose sugar. The nitrogen bases are Adenine (A), Thymine (T), Guanine (G), and Cytosine (C). The nitrogen bases are Adenine (A), Thymine (T), Guanine (G), and Cytosine (C). 5 DNA Structure

Copy the drawing in the space provided on your notes. Copy the drawing in the space provided on your notes. 6 Nucleotide Structure Label the Phosphate, Sugar, and Base Label the Phosphate, Sugar, and Base

The ribose sugar is a carbohydrate and is called a pentose sugar because it contains 5 carbon atoms, labeled 1’ through 5’. The ribose sugar is a carbohydrate and is called a pentose sugar because it contains 5 carbon atoms, labeled 1’ through 5’. The name of the entire DNA molecule comes from the ribose sugar. The name of the entire DNA molecule comes from the ribose sugar. Deoxyribose Deoxyribose Is missing an oxygen atom Is missing an oxygen atom Ribose Ribose Has an oxygen atom Has an oxygen atom Deoxyribose is the sugar used in DNA (Deoxyribonucleic acid), and ribose is the sugar used in RNA (Ribonucleic acid). Deoxyribose is the sugar used in DNA (Deoxyribonucleic acid), and ribose is the sugar used in RNA (Ribonucleic acid). The 5’ carbon connects to the first phosphate and the 3’ end connects to the second phosphate. The 5’ carbon connects to the first phosphate and the 3’ end connects to the second phosphate. 7 Nucleotide Structure

The phosphate is a compound that is built around a phosphorous atom. The phosphate is a compound that is built around a phosphorous atom. The phosphate’s job is to help hold the DNA molecule together. The phosphate’s job is to help hold the DNA molecule together. The phosphate plus the pentose sugar is referred to as the backbone of DNA. The phosphate plus the pentose sugar is referred to as the backbone of DNA. 8 Nucleotide Structure Phosphate Backbone

There are 2 types of nitrogen bases: Purines and Pyrimidines. Any of the bases can be used in a nucleotide There are 2 types of nitrogen bases: Purines and Pyrimidines. Any of the bases can be used in a nucleotide The Purines are called “double ring” bases and the Pyrimidines are called “single ring” bases. The Purines are called “double ring” bases and the Pyrimidines are called “single ring” bases. The bases are usually abbreviated as a single letter (A, T, C, or G) (U for Uracil comes later). The bases are usually abbreviated as a single letter (A, T, C, or G) (U for Uracil comes later). 9 Nucleotide Structure

The completed nucleotide monomer (Phosphate, Sugar, Base) bonds with many other nucleotides in order to form the entire DNA molecule (polymer). The completed nucleotide monomer (Phosphate, Sugar, Base) bonds with many other nucleotides in order to form the entire DNA molecule (polymer). The phosphate-sugar backbone is formed when the 3’ carbon on the sugar grabs a phosphate from another nucleotide. The phosphate-sugar backbone is formed when the 3’ carbon on the sugar grabs a phosphate from another nucleotide. Once each backbone (side) is assembled, the nitrogen bases join together. Once each backbone (side) is assembled, the nitrogen bases join together. 10 DNA Structure

The nitrogen bases join together with hydrogen bonds. (drawn with dashed lines) The nitrogen bases join together with hydrogen bonds. (drawn with dashed lines) For hydrogen bonding, purines only bond with pyrimidines and vice versa. For hydrogen bonding, purines only bond with pyrimidines and vice versa. Once the nucleotide has bonded with other nucleotides to make the backbone and hydrogen bond, it has become part of a DNA polymer. Once the nucleotide has bonded with other nucleotides to make the backbone and hydrogen bond, it has become part of a DNA polymer. 11 DNA Structure

The Purines only bond with Pyrimidines. This is due to the number of available bonds on each nitrogen base. The Purines only bond with Pyrimidines. This is due to the number of available bonds on each nitrogen base. Adenine and Thymine have 2 hydrogen bonds available while Guanine and Cytosine have 3. Adenine and Thymine have 2 hydrogen bonds available while Guanine and Cytosine have DNA Structure

The sugar-phosphate backbone is in an anti-parallel direction. The sugar-phosphate backbone is in an anti-parallel direction. The 5’ and 3’ ends of the backbone are on opposite sides. The 5’ and 3’ ends of the backbone are on opposite sides. Each side of a DNA molecule is actually running in the opposite direction. Each side of a DNA molecule is actually running in the opposite direction. All DNA molecules are built from 5’ to 3’. All DNA molecules are built from 5’ to 3’. 13 DNA Structure

The 5’ to 3’ direction makes the bases assemble in opposite directions. The 5’ to 3’ direction makes the bases assemble in opposite directions. Adenine pairs with Thymine (A-T) Adenine pairs with Thymine (A-T) Guanine pairs with Cytosine (G-C) Guanine pairs with Cytosine (G-C) 14 DNA Structure Copy the four nucleotide segment into the space provided in your notes.

Once the entire strand of DNA has been assembled, it coils into chromosomes. Once the entire strand of DNA has been assembled, it coils into chromosomes. DNA in eukaryotes is found coiled in chromosomes in the nucleus DNA in eukaryotes is found coiled in chromosomes in the nucleus DNA in prokaryotes is found coiled in the cytoplasm (nucleoid). DNA in prokaryotes is found coiled in the cytoplasm (nucleoid). 15 DNA Structure

The classic shape of a fully assembled DNA molecule is a double helix. The classic shape of a fully assembled DNA molecule is a double helix. Sometimes we will call it a “twisted ladder”. Sometimes we will call it a “twisted ladder”. DO NOT call DNA a spiral staircase! DO NOT call DNA a spiral staircase! (that is RNA and is another unit) (that is RNA and is another unit) DNA twists because the chemical bonds within the molecule twist it like a rope. DNA twists because the chemical bonds within the molecule twist it like a rope. 16 DNA Structure

Watson and Crick (1953) were the first scientists to discover the structure of DNA. Watson and Crick (1953) were the first scientists to discover the structure of DNA. They coined the term “Double Helix” to describe the twisted ladder shape of DNA and also named the new molecule DNA after the deoxyribose sugar within it. They coined the term “Double Helix” to describe the twisted ladder shape of DNA and also named the new molecule DNA after the deoxyribose sugar within it. Watson and Crick’s discovery was based on the work of several other scientists. 17 DNA Structure Discovery & History

Frederick Griffith In 1928, while working on a vaccine for pneumonia, Griffith discovered that when harmless bacteria and a virulent (disease-causing) bacteria were mixed some of the harmless bacteria became virulent, he called this transformation. ( )

Avery continued Griffith’s experiments and tried to find out what substance caused the transformation, he determined it was DNA that caused the transformation. ( ) Oswald Avery Avery demonstrated that an injection of DNA into a living cell could change the offspring of that cell.

In 1949, Chargaff discovered that the amount of Adenine in in a cell always equaled the amount of Thymine & the amount of Guanine always equaled the amount of Cytosine. When he discovered this, the complimentary base pairing rules were formed. They are sometimes called Chargaff’s Rules. Chargaff’s Rules: A pairs with T (A-T) G pairs with C (G-C) Complimentary bases pair together (A goes with T and C goes with G) Erwin Chargaff

In 1952, just prior to Watson and Crick’s discovery, Franklin used x-rays to find that a DNA molecule resembled a tightly coiled spring (helix). Rosalind Franklin

Franklin’s Experiment

In 1953, using the discoveries of the other scientists, Watson and Crick, completed the first model of DNA. They also found that the bases were joined by hydrogen bonds. Named the new molecule DNA after the deoxyribose sugar within it. Named the new molecule DNA after the deoxyribose sugar within it. Described the shape of the molecule as a double-helix. Described the shape of the molecule as a double-helix. Watson and Crick