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Welcome to Genetics: Unit 8 Seminar! Please feel free to chat with your classmates!. Agenda. Brief Review of Unit Material Self Assessment Questions Question. 12 Molecular Mechanisms of Mutation and DNA Repair. Mutations . A mutation is any heritable change in the genetic material
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Welcome to Genetics: Unit 8 Seminar! Please feel free to chat with your classmates!
Agenda • Brief Review of Unit Material • Self Assessment Questions • Question
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 • 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
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
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
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.
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
Discussion Question 1 • Please give an example of a transition mutation?
Discussion Question 1 • Please give an example of a transition mutation? • G -> A; purine -> purine • C -> T; pyrimidine -> pyrimidine
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
Discussion Question 2 • Please give an example of a transversion mutation?
Discussion Question 2 • Please give an example of a transversion mutation? • G -> T; purine -> pyrimidine • C -> A; pyrimidine -> purine
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
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
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
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 n-equals-one.com
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 staff.jccc.net
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
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
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
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
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
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
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
13 Molecular Genetics of Cell Cycle and Cancer
The Cell Cycle • There are two major parts in the cell cycle: Interphase: G1 = gap1S = DNA synthesis G2 = gap2 Mitosis: M • There are two essential functions of the cell cycle: • To ensure that each chromosomal DNA molecule is replicated only once per cycle • To ensure that the identical replicas of each chromosome are distributed equally to the two daughter cells
The Cell Cycle • The cell cycle is under genetic control • A fundamental feature of the cell cycle is that it is a true cycle: it is not reversible • Many genes are transcribed during the cell cycle just before their products are needed • Mutations affecting the cell cycle have helped to identified the key regulatory pathways
Key Mutational Targets • Many cancers are the result of alterations in cell cycle control, particularly in control of the G1-to-S transition • These alterations also affect apoptosis through their interactions with p53 • The major mutational targets for the multistep cancer progression are of two types: Proto-oncogenes Tumor-suppressor genes
Key Mutational Targets • The normal function of proto-oncogenes is to promote cell division or to prevent apoptosis • The normal function of tumor-suppressor genes is to prevent cell division or to promote apoptosis
Oncogenes • Oncogenes are derived from normal cellular genes called proto-oncogenes • Oncogenes are gain-of-function mutations associated with cancer progression • Oncogenes are gain-of-function mutations because they improperly enhance the expression of genes that promote cell proliferation or inhibit apoptosis
Tumor-Suppressor Genes • Tumor-suppressor genes normally negatively control cell proliferation or activate the apoptotic pathway • Loss-of-function mutations in tumor-suppressor genes contribute to cancer progression.