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Chapter 12 Molecular Mechanisms of Mutation and DNA Repair

Chapter 12 Molecular Mechanisms of Mutation and DNA Repair. Mutations . A mutation is any heritable change in the genetic material Mutations are classified in a variety of ways Most mutations are spontaneous — they are random, unpredictable events

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Chapter 12 Molecular Mechanisms of Mutation and DNA Repair

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  1. Chapter 12 Molecular Mechanisms of Mutation and DNA Repair

  2. Mutations • A mutation is any heritable change in the genetic material • Mutations are classified in a variety of ways • Most mutations are spontaneous—they are random, unpredictable events • Each gene has a characteristic rate of spontaneous mutation, measured as the probability of a change in DNA sequence in the time span of a single generation

  3. Table 12.1 Table 12.1: Major types of mutations and their distinguishing features

  4. Mutations • Rates of mutation can be increased by treatment with a chemical mutagen or radiation, in which case the mutations are said to be induced • Mutations in cells that form gametes are germ-linemutations; all others are somatic mutations • Germ-line mutations are inherited; somatic mutations are not • A somatic mutation yields an organism that is genotypically a mixture (mosaic) of normal and mutant tissue

  5. Mutations • Among the mutations that are most useful for genetic analysis are those whose effects can be turned on or off by the researcher • These are conditional mutations: they produce phenotypic changes under specific (permissive conditions) conditions but not others (restrictive conditions) • Temperature-sensitive mutations: conditional mutation whose expression depends on temperature

  6. Mutations • Mutations can also be classified according to their effects on gene function: • A loss-of-function mutation (a knockout or null) results in complete gene inactivation or in a completely nonfunctional gene product • A hypomorphic mutation reduces the level of expression of a gene or activity of a product • A hypermorphic mutation produces a greater-than-normal level of gene expression because it changes the regulation of the gene so that the gene product is overproduced • A gain-of-function mutation qualitatively alters the action of a gene. For example, a gain-of-function mutation may cause a gene to become active in a type of cell or tissue in which the gene is not normally active.

  7. Mutations • Mutations result from changes in DNA • A base substitution replaces one nucleotide pair with another • Transition mutations replace one pyrimidine base with the other or one purine base with the other. There are four possible transition mutations

  8. Mutations • Transversion mutations replace a pyrimidine with a purine or the other way around. There are eight possible transversion mutations • Spontaneous base substitutions are biased in favor of transitions • Among spontaneous base substitutions, the ratio of transitions to transversions is approximately 2:1

  9. Mutations • Mutations in protein-coding regions can change an amino acid, truncate the protein, or shift the reading frame: • Missense or nonsynonymous substitutions result in one amino acid being replaced with another • Synonymous or silent substitutions in DNA do not change the amino acid sequence • Silent mutations are possible because the genetic code is redundant

  10. Mutations • A nonsense mutation creates a new stop codon • Frameshift mutations shift the reading frame of the codons in the mRNA • Any addition or deletion that is not a multiple of three nucleotides will produce a frameshift

  11. Sickle-cell anemia • The molecular basis of sickle-cell anemia is a mutant gene for b-globin • The sickle-cell mutation changes the sixth codon in the coding sequence from the normal GAG, which codes for glutamic acid, into the codon GUG, which codes for valine • Sickle-cell anemia is a severe genetic disease that often results in premature death • The disease is very common in regions where malaria is widespread because it confers resistance to malaria

  12. Trinucleotide repeats • Genetic studies of an X-linked form of mental retardation revealed a class of mutations called dynamic mutations because of the extraordinary genetic instability of the region of DNA involved • The molecular basis of genetic instability is a trinucleotide repeat expansion due to the process called replication slippage

  13. Figure 12.6: Model of replication slippage

  14. Fragile-X Syndrome • The X-linked condition, is associated with a class of X chromosomes that tends to fracture in cultured cells that are starved for DNA precursors • They are called fragile-X chromosomes, and the associated form of mental retardation is the fragile-X syndrome • The fragile-X syndrome affects about 1 in 2500 children • The molecular basis of the fragile-X chromosome has been traced to the expansion of a CGG trinucleotide repeat present at the site where the breakage takes place

  15. Fragile-X Syndrome • Normal X chromosomes have 6–54 tandem copies of CGG, whereas affected persons have 230–2300 or more copies • An excessive number of copies of the CGG repeat cause loss of function of a gene designated FMR1(fragile-site mental retardation-1) • Most fragile-X patients exhibit no FMR1 mRNA • The FMR1 gene is expressed primarily in the brain and testes

  16. Figure 12.5: Dynamic mutation

  17. Dynamic Mutations and Diseases • Other genetic diseases associated with dynamic mutation include: • The neurological disorders myotonic dystrophy (with an unstable repeat of CTG) • Kennedy disease (AGC) • Friedreich ataxia (AAG) • Spinocerebellar ataxia type 1 (AGC) • Huntington disease (AGC)

  18. Transposable Elements • In a 1940s study of the genetics of kernel mottling in maize, Barbara McClintock discovered a genetic element that could move (transpose) within the genome and also caused modification in the expression of genes at or near its insertion site. • Since then, many transposable elements (TEs) have been discovered in prokaryotes and eukaryotes • They are grouped into “families” based on similarity in DNA sequence

  19. Transposable Elements • The genomes of most organisms contain multiple copies of each of several distinct families of TEs • Once situated in the genome, TEs can persist for long periods and undergo multiple mutational changes • Approximately 50% of the human genome consists of TEs; most of them are evolutionary remnants no longer able to transpose

  20. Transposable Elements • Some transposable elements transpose via a DNA intermediate others via an RNA intermediate • A target-site duplication is characteristic of most TEs insertions, and it results from asymmetrical cleavage of the target sequence • A large class of TEs called DNA transposons transpose via a cut-and-paste mechanism: the TE is cleaved from one position in the genome and the same molecule is inserted somewhere else

  21. Figure 12.8: The sequence arrangement of a cut-and-paste transposable element and the changes that take place when it inserts into the genome

  22. Transposable Elements • Each family of TEs has its own transposase—an enzyme that determines distance between the cuts made in the target DNA strands • Characteristic of DNA TEs is the presence of short terminal inverted repeats • Another large class of TEs possess terminal direct repeats, 200–500 bp in length, called long terminal repeats, or LTRs

  23. Transposable Elements • TEs with long terminal repeats are called LTR retrotransposons because they transpose using an RNA transcript as an intermediate • Among the encoded proteins is an enzyme known as reverse transcriptase, which can “reverse- transcribe,” using the RNA transcript as a template for making a complementary DNA daughter strand • Some retrotransposable elements have no terminal repeats and are called non-LTR retrotransposons

  24. Figure 12.10: Drosophila melanogaster

  25. Transposable Elements • TEs can cause mutations by insertion or by recombination • In Drosophila, about half of all spontaneous mutations that have visible phenotypic effects result from insertions of TEs • Genetic aberrations can also be caused by recombination between different (nonallelic) copies of a TE

  26. Spontaneous Mutations • Mutations are statistically random events—there is no way of predicting when, or in which cell, a mutation will take place • The mutational process is also random in the sense that whether a particular mutation happens is unrelated to any adaptive advantage it may confer on the organism in its environment • A potentially favorable mutation does not arise because the organism has a need for it

  27. Spontaneous Mutations • Several types of experiments showed that adaptive mutations take place spontaneously and were present at low frequency in the population even before it was exposed to the selective agent • One experiment utilized a technique developed by Joshua and Esther Lederberg called replica plating • Selective techniques merely select mutants that preexist in a population

  28. Figure 12.13: Replica plating

  29. Mutation Hot Spots • Mutations are nonrandom with respect to position in a gene or genome • Certain DNA sequences are called mutational hotspots because they are more likely to undergo mutation than others • For instance, sites of cytosine methylation are usually highly mutable

  30. Mutagenes • Almost any kind of mutation that can be induced by a mutagen can also occur spontaneously, but mutagens bias the types of mutations that occur according to the type of damage to the DNA that they produce Table 12.3: Major agents of mutation and their mechanisms of action

  31. DNA Repair Mechanisms • Many types of DNA damage can be repaired • Mismatch repairfixes incorrectly matched base pairs • The AP endonuclease system repairs nucleotide sites at which the base has been lost • Special enzymes repair damage caused to DNA by ultraviolet light • Excision repair works on a wide variety of damaged DNA • Postreplication repair skips over damaged bases

  32. Mismatch Repair • Mismatch repairfixes incorrectly matched base pairs: a segment of DNA that contains a base mismatch excised and repair synthesis followed • The mismatch-repair system recognizes the degree of methylation of a strand and preferentially excises nucleotides from the undermethylated strand • This helps ensure that incorrect nucleotides incorporated into the daughter strand in replication will be removed and repaired.

  33. Mismatch Repair • The daughter strand is always the undermethylated strand because its methylation lags somewhat behind the moving replication fork Figure 12.27: Mismatch repair

  34. Mismatch Repair • The most important role of mismatch repair is as a “last chance” error-correcting mechanism in replication Figure 12.26: Summary of rates of error in DNA polymerization, proofreading, and postreplication mismatch repair

  35. AP Repair • Deamination of cytosine creates uracil, which is removed by DNA uracil glycosylase from deoxyribose sugar. The result is a site in the DNA that lacks a pyrimidine base (an apyrimidinic site) • Purines in DNA are somewhat prone to hydrolysis, which leave a site that is lacking a purine base (an apurinic site) • Both apyrimidinic and apurinic sites are repaired by a system that depends on an enzyme called AP endonuclease

  36. Figure 12.28: Base-excision

  37. Excision Repair • Excision repair is a ubiquitous, multistep enzymatic process by which a stretch of a damaged DNA strand is removed from a duplex molecule and replaced by resynthesis using the undamaged strand as a template Figure 12.30: Mechanism of nucleotide excision repair of damage to DNA

  38. Postreplication repair • Sometimes DNA damage persists rather than being reversed or removed, but its harmful effects may be minimized. This often requires replication across damaged areas, so the process is called postreplication repair Figure 12.31: Postreplication repair

  39. Ames Test • In view of the increased number of chemicals used and present as environmental contaminants, tests for the mutagenicity of these substances has become important • Furthermore, most agents that cause cancer (carcinogens) are also mutagens, and so mutagenicity provides an initial screening for potential hazardous agents • A genetic test for mutations in bacteria that is widely used for the detection of chemical mutagens is the Ames test

  40. Ames test • In the Ames test for mutation, histidine-requiring (His-) mutants of the bacterium Salmonella typhimurium, containing either a base substitution or a frameshift mutation, are tested for backmutation reversion to His+ • In addition, the bacterial strains have been made more sensitive to mutagenesis by the incorporation of several mutant alleles that inactivate the excision-repair system and that make the cells more permeable to foreign molecules

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