1. Genes: Structure, Replication, & Mutation  Nucleic Acid Structure  DNA Replcation  Mutations  Detection & Isolation of Mutants  DNA Repair

2. Nucleic Acid Structure  Nucleic acids are polymers of nucleotides  Nucleotides consist of a pentose sugar, a nitrogenous base, and a phosphate group

3. Nucleic Acid Structure  DNA: Deoxyribonucleic acid  Pentose sugar: 2’-deoxyribose  Nitrogenous bases: Adenine and guanine (purines) Cytosine and thymine (pyrimidines)  Structure is typically a double-stranded helix Nucleotide sequences of the strands are complementary to each other, A pairing with T and C pairing with G

4. Nucleic Acid Structure  RNA: Ribonucleic acid  Pentose sugar: Ribose  Nitrogenous bases: Adenine and guanine (purines) Cytosine and uracil (pyrimidines)  Structure is typically single-stranded Often there are internal complementary regions within the strand that can form double-stranded “hairpin loops” (C to G; A to U)

5. DNA Replication  Helicases unwind the DNA double helix, starting at a site called the origin of replication. As the helix is unwound, the strands are kept separated by DNA single-stranded binding proteins. Topoisomerases (such as E. coli DNA gyrase) prevent the DNA from supercoiling).

6. DNA Replication  Synthesis of new strands begins with the synthesis of short RNA primer strands, by the enzyme primase. The new DNA strands are synthesizes by enzymes called DNA polymerases. Nucleotides are added to the growing DNA strands using the old strands as templates, following base-pairing rules (A to T, C to G). In E. coli, DNA polymerase III is responsible for most of the DNA strand synthesis.

7. DNA Replication  Primers are excised, and the gaps filled in with DNA nucleotides, by DNA polymerase enzymes. In E. coli, DNA polymerase I is responsible for most of this activity. In addition, DNA polymerases “proofread” the new strands during replication, oftentimes (but not always) excising mismatched bases and thereby correcting mistakes to prevent mutation

8. DNA Replication  Fragments of the new strands are joined together by DNA ligase, which adds the final bond connecting adhacent fragments in a strand.

9. Mutations: Definitions  Mutations result from alterations in the nucleotide sequence in a gene  Lethal mutation: results in death of the cell, and therefore cannot be propagated or studied  Conditional mutation: One that is expressed only under certain environmental conditions; for example, a temperature-sensitive mutation

10. Mutations: Definitions  Biochemical mutations: result in change in a biochemical pathway of the cell; for example, an auxotrophic mutation  Spontaneous mutation: one that arises spontaneously due to error during DNA replication  Induced mutation: one that has been caused by damage resulting from chemical or radiation treatment (mutagen)

11. Mutations: Definitions  Adaptive or directed mutation: The concept that some bacteria have an increased mutational frequency as an adaptive response to certain environmental or nutritional factors (for example, E. coli regaining the ability to use lactose, or hypermutation: activation of mutator genes in nutrient-starved cultures).

12. Mutations: Chemical Mutagenic Action  Chemical Mutagenic Action  Base analogs  A chemical similar in structure to one of the bases and can substitue for it but doesn’t base pair normally  For example, 5-bromouracil substitutes for thymine, but it frequently pairs with a G instead of A

13. Mutations : Chemical Mutagenic Action  Chemical Mutagenic Action (cont)  Specific Mispairing  When a mutagen changes a base’s structure and thereby alters its base pairing  For example: nitrosoguanidine adds a methyl group to guanine, causing it to pair with T instead of C.

14. Mutations : Chemical Mutagenic Action  Chemical Mutagenic Action (cont)  Intercalating agents  Examples include acridine orange and ethidium bromide  Flat, planar, aromatic molecules that can fit between the stacked bases (intercalate) in the center of a DNA double helix and distort its geometry  The distortion somehow induces single nucleotide insertions or deletions

15. Mutations : Chemical Mutagenic Action  Chemical Mutagenic Action (cont)  Bypass of replication  Chemical change or damage to bases is so severe that the bases can no longer base pair at all, and cannot serve as a template  Example: formation of thymine dimers by UV irradiation; these cannot hydrogen bond at all  Normally this would be lethal, but there are repair mechanisms that can bypass the damaged template, although many of these repair mechanisms are error-prone so generate a high frequency of mutations

16. Mutations: Types of Mutations  Forward mutation: A mutation in the wild type, causing some notable change in phenotype  Reversion mutation: A change causing a mutant to appear to revert back to the wild type phenotype  Back mutation: A reverse mutation in which the mutant nucleotide sequence has truly reverted back to exactly its original wild type nucleotide sequence.  Suppressor mutation: A reverse mutation in which a mutation in a second gene overcomes the first mutation and restores the wild phenotype  Intragenic supression: A second mutation within the same gene, but not restoring the original sequence, restores the phenotype.

17. Mutations: Types of Mutations  Point mutation: Substitution of one base for another  Silent mutation: A point mutation that results in no change in the amino acid sequence of the protein encoded, due to redundancy in the genetic code  Missense mutation: A point mutation in which there is a change in the codon of one amino acid for the codon for another amino acid, resulting in a protein with a single amino acid substitution. This could lead to anywhere from complete loss of protein activity to no change in the level of activity at all, depending on the amino acid substitution.

18. Mutations: Types of Mutations  Nonsense mutation: A point mutation in which a sense codon (encoding for an amino acid) is changed to a nonsense codon (stop codon), resulting in premature chain termination. Usually it results in loss of the protein’s function.  Nonsense suppressor mutation: A mutation in a tRNA gene that makes a mutant tRNA capable of pairing with a stop codon and thereby reversing certain nonsense mutations.  Frameshift mutation: Insertion or deletion of one or two bases within a gene which cause all of the codons downstream from the insertion or deletion to be misread, so that all of the amino acids past that point are incorrect.

19. Detection of Mutants  Screening for Auxotrophs by Replica plating on Minimal and Complete media  Potential auxotrophs are plated on both minimal and complete media; auxotrophs grow on complete medium but not on minimal medium

20. Detection of Mutants  Ames test  Used to test chemicals for potential carcinogenic properties  Based on the idea that most carcinogens are also mutagenic  Utilizes histidine auxotrophic strains of Salmonella typhimurum  Cells are plated in medium with limited histidine, duplicate plates with and without the test mutagen.  The number of histidine prototrophic revertants with and without the test mutagen are counted to determine the relative mutagenicity of the agent

21. Detection of Mutants  Ames test (cont)  Mammalian liver extract may be added to the medium, because some substances may become mutagenic only after being metabolized by the liver.  Not all carcinogens are detected by the Ames test; other tests modeled on the Ames strategy have employed either yeast cells, cultured mammalian cells, or even live mice injected with the test mutagen

22. DNA Repair  Proofreading  Immediate removal and replacement of a mismatched base during DNA replication; done by DNA polymerase  Excision repair  General system to correct damage that has caused distortions to the double helix  Endonucleases remove the wrong bases from one strand, leaving a gap of about 12 bases that is filled in by DNA polymerase I

23. DNA Repair  Direct repair of altered bases  Photoreactivation: Thymine dimers can be repaired by the enzyme photolyase, which restores the thymines  Methyl groups my be removed from alkylated bases by enzymes  Postreplication repair  Mismatch repair system: Correction enzyme scans newly replicated DNA strands; if a mismatched base is found a segment of the strand is excised from around the mismatch and replaced by DNA polymerase

24. DNA Repair  Recombination repair  Occurs when damage has been so great that there is no template remaining, as when both bases of a pair are missing  RecA protein cuts a piece of double stranded DNA from another part of the chromosome and splices it into the damaged area  SOS repair: Occurs when the damage is so great that replication stops completely, leaving many large gaps; recA protein fills in the gaps but the process is highly error prone and results in mutations.