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Ch. 18 – Microbial Models of DNA Microbes : microscopic organisms like bacteria and viruses, can include fungi and protista Bacteria : kingdoms Eubacteria and Archeabacteria (formerly Monera), Prokaryotic cell, unicellular, one circular piece of DNA and multiple plasmids Viruses : nonliving – DNA or RNA and a protein coat Usefulness • While we are familiar with disease causing bacteria and viruses (pathogens), most bacteria are harmless and actually helpful • Because the have simple systems – the study of their genetics has helped us understand more complex systems, like our own. • They have some specialized systems that have helped us study disease • They transfer genetic material between cells – an important area of genetic research. Discovery of Viruses • Late 1880’s – Mayer, Ivanowsky and Beijerinck; plants can spread disease to each other, disease is smaller than a bacteria and can be within the sap • Early 1900’s - Stanley ; crystallized TMV (tobacco mosaic virus) – Crop was still big part of economy • Actually saw virus with electron microscope Viruses • 20 nm (nanometers) – smaller than ribosome • Cells can not be crystallized • Nucleic acid plus protein – – – – – Protein called a capsid Variety of shapes…. Including the icosahedron dsDNA, ssDNA, ssRNA and dsRNA Linear or circular 4 – 100’s genes • Bacteriophages are viruses that infect bacteria – Phages named T1 – T7 Viral Reproduction • Viruses are host specific (range) – Phages only bacteria, some only E.coli – Rhinovirus (cold) only humans – Rabies – all mammals • Proteins fit with receptor cells – Some viruses of eukaryotes are tissue specific (URT) • Lytic vs lysogenic life cycles – See handouts (385 – 396) Viral Life Cycles LYTIC cycle • Virus attaches to host • Injects nucleic acid • Host reads nucleic acid and then • manufactures viral DNA and proteins • Virus is assembled • Escapes host cell • Infects other cells LYSOGENIC cycle • Same as lytic UNTIL • Cell replicates – BEFORE copying and making viral instructions • This takes along viral nucleic acids to new generations of host, as part of the host genome • At some point, lots of host offspring are triggered to start lytic cycle • “latent” phase Control of Viral Genes • Bacteria posses restriction endonucleases, which are enzymes that degrade viral DNA as it enters • Go lysogenic instead – if phage is added to a specific site within bacterial DNA then it’s a prophage and it codes for a protein that represses the other phage genes. • Some bacteria are actually more harmful because they posses phages that make toxins • Viruses can also be ‘enveloped’ by host to help them hide Retroviruses • These viruses double stranded RNA that is a template from which an enzyme called reverse transcriptionase can make DNA • “backwards” • An example is HIV Vaccines • Colds – epithelial cells in throat can repair themselves efficiently • Polio – attaches to nerve cells that cannot be repaired • 1796 – Edward Jenner – noticed that cow pox (mild) makes one immune to small pox (more harmful). • Used fluid from cow (vacca) pox blister to give people cow pox, making them immune to small pox. • Small pox has since been eradicated (WHO) • Fewer cases of polio, rubella, measles and mumps since vaccines • Rabies vaccines for pets • Newer vaccines for chicken pox (varicella) and HPV (gardasil) • Flu shots are vaccines against the flu – varies from year to year and location to location – Globalization – Evolution of viral genome – CDC and WHO Emergent Diseases • More cases, cases in new location, more deadly cases and spreading to a new host make a disease an emergent disease – – – – HIV Hantavirus Ebola The plague (emergent diseases aren’t all viral) – not currently emerging…. – Lyme disease – Asian Bird Flu – ???? Certain cancers Link between cancer and virus • Some viruses do cause cancers in animals – Example is feline leukemia • Versions of oncogenes are found in normal cells – something triggers them • Viruses may activate proto-oncogenes • Viroids = circle of RNA that only infects plants, replicate in plant cell to interfere with enzymes • Prions = infectious proteins that convert normal proteins to infectious proteins – Ex. “Mad Cow” aka Crueutzfeldt –Jacob disease History • Viral genomes often have much in common with the hosts DNA – Could have evolved as either plasmids or transposons – Plasmids are small circular pieces of DNA that replicate rapidly with in bacteria – Transposons are pieces of DNA that move from location to location with in a genome Bacterial Genetics • Bacteria are cells – prokaryotic cells with a cell membrane, cytoplasm with ribosomes, and a circular piece of DNA in the nucleoid region. May also have plasmids • Bacteria are mm, • genome is about 4300 genes which is 100 x virus and 1/1000 of a euk. Cell • DNA is 500 longer than the cell • Divide by binary fission • Adaptable – Lots of habitats and host and modes of nutrition – Natural selection happens quickly because of generation time (hours to days) Genetic Recombination • Transformation – Uptake of DNA from the environment – S. pneumonia coats • Transduction – Phages carry genes from one bacterial host to another – May have research possibilities • Conjugation – Bridge called pili between two bacteria and plasmids are transferred…. No new cells, not reproduction – Transfer resistance to antibiotics – called R factor for resistance – Conjugation requires bacteria to have F (fertility) factor • Transposons – Regions of DNA that move within a bacteria, either to a new place on the chromosome or between the chromosome and the plasmids – Originally called ‘jumping genes’ by McClintock, they moved within the genome of indian corn, turning the color genes on and off Control of Bacteria genes • Restriction endonucleases • Transposons • Feed back inhibition from OPERONS – Transcription unit – Promoter : RNA polymerase attaches – Operator : acts as switch – Regulatory gene – Repressor : keeps operator off – Inducer : lets operator be on Operons • trp operon • See pg. 338 • If no tryptophan – then operon on and making tryp. • If lots of trp – then repressor in operator, no need to make if you already have • lac operon • See pg. 339 • No lactose, no need for lactase enzyme. • Lactose actually inactivates the repressor to lactase can be made