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Chapter 18 Microbial Models: The Genetics of Viruses and Bacteria
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What is a virus? u An infectious particle consisting of nucleic acid enclosed in a protein coat.
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Virus Characteristics 1. Small size 2. Infectious 3. Reproduction 4. Alcohol Resistance 5. Crystallization
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Size u Large - barely visible with the light microscope. u Small - down to 20nm. u Comment - Much smaller than cells including bacteria.
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Infectious u Viruses cause many diseases. They can be spread from one organism to another.
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Reproduction u Can not reproduce without a host. u Viruses are obligate parasites.
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Alcohol Resistance u Not immediately killed by alcohol like cells are. u Reason - resistant to dehydration by osmosis.
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Crystallization u Can form crystals. u Cells can't do this.
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Viral Structure 1. Genome - the genetic information. 2. Capsids and Envelopes - the outer covering.
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Viral Genomes u Are used to classify virus types. u I - ds DNA u II - ss DNA u III - ds RNA u IV-VI - ss RNA
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Capsid u Protein shell that encloses the viral genome. u Made from a large number of protein subunits. u Number of kinds of subunits usually small. u Often geometric in shape.
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Envelopes u Membranes cloaking the capsids of some viruses. u Made from host membrane, but may have virus originated glycoproteins added.
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General Steps for Viral Replication 1. Cell Entry 2. Genome Replication 3. Capsid Protein formation 4. Self-assembly of offspring 5. Exit from Host
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Cell Entry u Locate host by "Lock-and- Key” fit between virus proteins and cell receptor molecules. u Infection - Begins when viral genome enters the cell.
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Genome Replication u Host is reprogrammed to copy virus genome. u Use host DNA polymerase. u Use virus enzymes to copy RNA to DNA. u Use host's resources to make copies.
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Capsid Protein Formation u Host's protein synthesis machinery used to make virus proteins.
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Self-Assembly of Offspring u genome + capsid -----> virus u Particles usually assemble spontaneous.
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Exit From Host u Host cell may burst or lyse, releasing the virus. u May "bud-off" host membrane, forming envelopes around the capsids.
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Bacterial Viruses u Best understood of all viruses. u May show two types of virus life cycles: u Lytic Cycle u Lysogenic Cycle
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Lytic Cycle u Virus reproductive cycle that kills the host cell. u Note - the previously described virus life cycle was a Lytic Cycle.
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Ex: T4 Virus on E. coli u Uses Lytic Cycle. u Example of an Virulent Virus (a virus that only uses the lytic cycle). u Has about 100 genes. u Completes cycle in 20-30 minutes.
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Lysogenic Cycle u Virus reproduction that doesn't immediately kill the host cell. u Viral DNA is inserted into the host DNA, but not expressed.
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Movie – Lysogenic Cycle
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Temperate Viruses u Viruses with both lytic and lysogenic cycles. phage - Temperate virus on E. coli. = Lambda )
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Prophage u Virus DNA inserted into the host's DNA. u Viral DNA is reproduced with host DNA. u "Timebomb" for lytic cycle.
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Lytic Mode Triggers u Switches the host from Lysogenic to Lytic Cycles u ex: radiation, chemicals, stress
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Animal Viruses u Belong to several viral classes. u Specific Interests: 1. Viruses with envelopes 2. RNA viruses
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Envelopes made with Host Membranes from: 1. Plasma Membrane 2. Nuclear Membrane
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Herpes Viruses u Use nuclear membrane. u Viral DNA integrated into Host DNA as a provirus. u Shows both lytic and lysogenic life cycles.
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RNA Viruses u Classes III - VI u Class VI - Retrovirus - use Reverse Transcriptase to make DNA from an RNA template.
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Human Immunodeficiency Virus u HIV - causes AIDS. u Retrovirus from chimps. u Destroys the body’s immune system, allowing other diseases to kill.
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Movie - HIV
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Other Viral Diseases u Measles u Polio u Smallpox u Influenza
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Treatments for Viruses u Vaccines (preventative). u Some Drugs u Ex: Ara-A Acyclovin u Comment - some treatments are working on the reverse transcriptase.
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Problem u Since viruses work within a host cell, they are very difficult to treat. u Best Treatment - prevention.
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Viruses u Can also cause cancer u Ex: HTLV-1 Papilloma Viruses
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Plant Viruses u Can be an important agricultural problem. u Ex: Tobacco Mosaic Virus Tulip Flower Breakage
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Viroids u Infectious particles of naked RNA. u Similar to viruses, but lack a capsid. u Ex: u Coconut Blight u Chrysanthemum Wilt
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Viroids u Sequences are similar to Introns. u Connection?
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Prions u Infectious protein particles. u Cause “mad-cow” and Creutzfeldt-Jakob disease. u Protein folding problem?
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Prion Action
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Bacteria Genomes u DNA circle (Chromosome). u Plasmids. - Small circle of DNA that is independent of the chromosome. u Carries a small number of traits.
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E. coli Mutations u Binary Fission is not always perfect. Mistakes or mutations are made. u Rate: 1x10 -7 cell divisions. u Rare, but impact is high with the short generation time.
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Importance u Mutations are the prime source of new alleles in bacteria.
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Bacterial Genetic Recombinations 1. Transformation 2. Transduction 3. Conjugation 4. Plasmids 5. Transposons Be able to discuss a few of these methods.
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Genetic Recombination u Mixes the genetic material into new combinations. u Will move new mutations through a population.
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Transformation u Alteration of a cell's DNA by the uptake of foreign DNA. u Ex: Griffith's experiment and our lab last semester.
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Transduction u Transfer of genes through phage infections.
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Conjugation u Direct transfer of genetic material between two bacterial cells. u Bacterial "sex”. u Used to map genetic sequences in bacteria.
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Plasmids u Small circular piece of DNA. u Carry many important traits. u Ex: Fertility Factor Antibiotic Resistance (R Plasmids)
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Episome u Plasmid that has been incorporated into the bacterial chromosome.
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Transponsons u Transposable genetic elements. u Also called "Jumping Genes”.
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Transposons u May change locations within the chromosome, or they may copy into a new location. u Don't usually attach to DNA at specific locations, allowing them to scatter genes throughout the genome.
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Gene Expression in Eukaryotes u Important for cellular control and differentiation. u Understanding “expression” is a key area in Biology. u More details in a future chapter.
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General Mechanisms 1. Regulate Gene Expression 2. Regulate Enzyme Activity
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Operon Model u Jacob and Monod (1961) - Prokaryotic model of gene control. u Always on the national AP Biology exam !
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Operon Structure 1. Regulatory Gene 2. Operon Area a. Promoter b. Operator c. Structural Genes
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If Lactose is absent
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Regulatory Gene u Makes Repressor Protein which may bind to the operator.
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Promoter u Attachment sequence on the DNA for RNA polymerase.
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Operator u The "Switch”, binding site for Repressor Protein. u If blocked, will not permit RNA polymerase to pass, preventing transcription.
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Structural Genes u Make the enzymes for the metabolic pathway.
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Lac Operon u For digesting Lactose. u Inducible Operon - only works (on) when the substrate (lactose) is present.
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If no Lactose u Repressor binds to operator. u Operon is "off”, no transcription, no enzymes made
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If Lactose is absent
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If Lactose is present u Repressor binds to Lactose instead of operator. u Operon is "on”, transcription occurs, enzymes are made.
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If Lactose is present
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Enzymes u Digest Lactose. u When enough Lactose is digested, the Repressor can bind to the operator and switch the Operon "off”.
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Net Result u The cell only makes the Lactose digestive enzymes when the substrate is present, saving time and energy.
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trp Operon u Makes Tryptophan. u Repressible Operon.
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If no Tryptophan u Repressor protein is inactive, Operon "on” Tryptophan made. u “Normal” state for the cell.
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Tryptophan absent
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If Tryptophan present u Repressor protein is active, Operon "off”, no transcription, no enzymes u Result - no Tryptophan made
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If Tryptophan present
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Repressible Operons u Are examples of Feedback Inhibition. u Result - keeps the substrate at a constant level.
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CAP - positive gene regulation u Catabolite Activator Protein u Accelerates the level of transcription by working with the RNA polymerase. u Uses cAMP as a secondary cell signal.
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CAP - Mechanism u Binds to cAMP. u Complex binds to the Promoter, helping RNA polymerase with transcription.
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Result u If the amount of glucose is low (as shown by cAMP) and lactose is present, the lac operon can kick into high gear.
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Summary u Know the general structure of a virus and how a virus reproduces. u Know the components of bacteria genomes and some methods for genetic recombination.
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Summary u Know Operon theory ! u Know the difference between inducible and repressible enzymes.
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