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DNA: The Molecule of Heredity How did scientists discover that genes are made of DNA? • By the late 1800s, scientists knew that genetic information existed as distinct units called genes. • By the early 1900s, studies suggested genes were part of chromosomes, protein and DNA complexes. Chapter 11 How did scientists discover that genes are made of DNA? • In 1928, a British medical officer, Frederick Griffith, worked to create a vaccine against Streptococcus pneumoniae. – The bacteria that causes pneumonia in mammals. Two strains of the same bacteria. Nonpathogenic strain (harmless) Pathogenic strain (disease causing) Pathogenic Strain Griffith’s Experiment Heat Killed Mixed with Non-Pathogenic Strain Some Harmless Cells Became Pathogenic Non-Pathogenic Non-Pathogenic Mouse Remains Healthy Pathogenic Pathogenic Mouse Dies of Pneumonia Injected into Mice Injected into Mice Heat Killed Pathogenic Heat Killed Pathogenic Mouse Remains Healthy Heat Killed Pathogenic and Non-Pathogenic Heat Killed Pathogenic and Non-Pathogenic Mouse Dies of Pneumonia Non-Pathogenic (N) Pathogenic (P) Injected into Mice Heat Killed Pathogenic Heat Killed Pathogenic and Non-Pathogenic Mouse Remains Healthy N does not cause pneumonia. Mouse Dies of Pneumonia P causes pneumonia. Mouse Remains Healthy Heat killed P cells do not cause disease. Mouse Dies of Pneumonia Dead P cells transformed N cells into pathogens. Bacterial Transformations • Conclusions from Griffith’s Experiment – DNA was not destroyed in the heat-killed bacteria. – The bacteria’s information still made mice sick. • Bacterial transformations are the incorporation of foreign genetic information into the cell’s chromosome. Bacterial Transformations • Conclusions from Griffith’s Experiment – DNA was not destroyed in the heat-killed bacteria. – The bacteria’s information still made mice sick. • Bacterial transformations are the incorporation of foreign genetic information into the cell’s chromosome. It wasn’t until 1943 that researchers discovered the transformed material was DNA. What is DNA? • Deoxyribose Nucleic Acid • There are 4 different nucleotides, nucleic acid bases. Adenine (A) Guanine (G) Thymine (T) Cytosine (C) What is DNA? • Deoxyribose Nucleic Acid • Chain of nucleic acids that contain the genetic blueprint (molecular make-up) of all organisms. • A set of DNA molecules make up a gene. • A set of genes make up a chromosome. DNA is a Double Helix What is DNA? • Deoxyribose Nucleic Acid • In the 1940s, Erwin Chargaff observed the amounts of the nucleotides. Chargaff’s Rule: - Equal amounts of adenine and thymine. • Maurice Wilkins & Rosalind Franklin – Used a technique called X-ray diffraction to study molecular structure. • Rosalind Franklin thymine adenine - Equal amounts of guanine and cytosine. guanine – Produced the first picture of the DNA molecule using this technique. cytosine DNA is a Double Helix DNA is a Double Helix • James Watson and Francis Crick analyzed Wilkins and Franklin’s data and determined: X-ray Diffraction bombards X-rays at a sample and analyzes the pattern of scattering. From the X-ray diffraction pattern, they concluded that DNA: – Has a uniform diameter of 2nm. – Is helical. – Consists of repeating subunits. – The DNA molecule consists of two separate DNA polymer strands. – Within each strand, the phosphate of one nucleotide binds to the sugar of the next one, producing a sugarphosphate backbone. – All nucleotides face the same direction in the DNA strand. Nobel Prize for Medicine, 1962 DNA is a Double Helix • Awarded to Watson, Crick, and Wilkins for their discovery of the structure of DNA. • Should have been awarded to Franklin as well. Phosphate – Can be awarded no more than 3 individuals. – Cannot be awarded to someone after their death. – Rosalind Franklin died in 1958. DNA is a Double Helix Covalent bonding creates a Sugar-Phosphate backbone. Sugar DNA is a Double Helix DNA consists of two separate strands facing the same direction, antiparallel. The two strands are held together by hydrogen bonds. Numbering Nucleotides • All carbons in the nucleotide are numbered. Numbering Nucleotides • All carbons in the nucleotide are numbered. • The 3’ carbon always bonds with the phosphate group of the next base. • DNA strands are always read 5’ to 3’ end Numbering Nucleotides • All carbons in the nucleotide are numbered. • The 3’ carbon always bonds with the phosphate group of the next base. Numbering Nucleotides • DNA strands are always read 5’ to 3’. – A free phosphate group marks the 5' end of a DNA sequence. – A free sugar marks the 3' end. DNA is a Double Helix Three Possible DNA Helices B-DNA DNA Replication • When cells divide, the DNA must be copied so each daughter cell receives an exact copy. • A cell must: – Replicate its DNA exactly one time before division – Divide after DNA replication – Have energy to do both A-DNA Parent Cell – A-DNA is found in RNA-RNA and RNADNA helices. – Z-DNA is only found in certain sequences. How does DNA Replication occur? A T T A G C C Daughter Cells Z-DNA • Three possible helices can be constructed from the four nucleotides. • B-DNA is the form found in all cells. • A- and Z-DNA have alternate spacing of the helices and are found in certain circumstances. G G C How does DNA Replication occur? A Template strand T How does DNA Replication occur? A T T A Complimentary strand G C C C C G G A G C C Parental Strand T T A G C G G A T G G C C New Daughter Strand How does DNA Replication occur? 1. H-bonds separate between N-bases, forming two single helices. 2. Each helix makes a complementary strand using the parental strand as a template. 3. Two double helices are produced. How does DNA Replication occur? • Semi-conservative replication: each new strand contains one conserved parent strand and one newly synthesized strand. Enzymes of Replication Enzymes of Replication • DNA Topoisomerase • Unwinds DNA supercoiled structures. • DNA Helicase • Separates the DNA double helix by removing H-bonds holding nucleotide bases together. – The DNA helix is coiled upon itself for compact storage, called supercoiling. Enzymes of Replication Enzymes of Replication • DNA Polymerase • Moves along each separate parental DNA strand and matches bases with complementary free nucleotides. • Synthesizes the new daughter strand from the 3’ to 5’ end. DNA • DNA ligase • Ties daughter pieces together. • Connects segments of discontinuous DNA synthesis. DNA Replication, in detail • After the topoisomerase unwinds the DNA, the DNA helicase creates replication bubbles throughout the strand to be copied. DNA Replication, in detail • DNA polymerase copies by either continuous or discontinuous synthesis. DNA Replication, in detail • DNA polymerase binds at the replication fork and begins copying. DNA Replication, in detail • Continuous synthesis: – Complete synthesis of the leading daughter strand moving toward the helicase. • Discontinuous synthesis: – Synthesis of the lagging daughter strand in segments as the helicase closes the replication bubble. – Requires the DNA ligase to join segments. Leading Strand Lagging Strand 5’ 3’ 3’ 5’ DNA Replication, in detail • Continuous synthesis: • Continuous synthesis: – Complete synthesis of the leading daughter strand moving toward the helicase. • Discontinuous synthesis: Leading Strand – Synthesis of the lagging daughter strand in segments as the helicase closes the replication bubble. – Requires the DNA ligase to join segments. Leading Strand 5’ 3’ 5’ 3’ 3’ 5’ 3’ 5’ Lagging Strand Lagging Strand DNA Replication, in detail • Continuous synthesis: DNA Replication, in detail • Continuous synthesis: – Complete synthesis of the leading daughter strand moving toward the helicase. • Discontinuous synthesis: – Complete synthesis of the leading daughter strand moving toward the helicase. • Discontinuous synthesis: – Synthesis of the lagging daughter strand in segments as the helicase closes the replication bubble. – Requires the DNA ligase to join segments. Leading Strand 3’ Lagging Strand – Complete synthesis of the leading daughter strand moving toward the helicase. • Discontinuous synthesis: – Synthesis of the lagging daughter strand in segments as the helicase closes the replication bubble. – Requires the DNA ligase to join segments. 5’ DNA Replication, in detail – Synthesis of the lagging daughter strand in segments as the helicase closes the replication bubble. – Requires the DNA ligase to join segments. Leading Strand 3’ 5’ 5’ 3’ Lagging Strand DNA Replication, in detail • DNA ligase stitches daughter strands together, produced by discontinuous synthesis of the complimentary strand. • Synthesis continues until the entire parental template strand is synthesized. DNA Replication, in detail • Helicase = Blue • Polymerase = Green http://www.wehi.edu.au/education/wehi-tv/dna/ Mistakes and Mutations in DNA Replication • Mutations are changes in the DNA sequence that lead to defective genes. • DNA polymerase mismatches every 1/10,000 bases. – Due to the speed of replication: 50 nt/sec in humans, 1000 nt/sec in some bacteria. • DNA polymerase is capable of proofreading, increasing accuracy to 1 mistake per 1 billion base pairs. Mistakes and Mutations in DNA Replication Mistakes and Mutations in DNA Replication Mistakes and Mutations in DNA Replication • Most mistakes are deleterious, or harmful. - Changes to a protein’s sequence almost always renders the protein useless and unable to fold properly. • Sometimes mutations are neutral, or have no effect. • Very rarely, mutations can have a beneficial effect. - These are favored by natural selection and are the basis for the evolution of life. Mistakes and Mutations in DNA Replication Homework • What types of mutations can occur during DNA replication that result in a newly-synthesized DNA strand of the same length as the template strand? • Assume that in the process of creating a replication bubble during DNA replication, the helicase causes a substitution in the complimentary strand only. The mutation was not caught by proof-checking machinery and replication continued. – After two rounds of DNA replication (this first replication bubble starts the first round), how many strands of DNA carry the mutation (each half of the DNA double helix counts as one strand)?