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Transcript
Microbial Genetics
Flow of Genetic Information =
Terminology
ƒ Genetics: The study of what genes are, how they carry information, how information is
expressed, and how genes are replicated.
ƒ Gene: A segment of DNA that encodes a functional product, usually a protein.
ƒ Genome: All of the genetic material in a cell
ƒ Genomics: The molecular study of genomes
ƒ Genotype:
ƒ Phenotype:
DNA
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Polymer of nucleotides:
Double helix associated with proteins
"Backbone" is deoxyribose-phosphate
Strands are held together by hydrogen bonds between AT and CG.
DNA is copied by DNA polymerase
ƒ
ƒ Initiated by an RNA primer
ƒ Leading strand is synthesized continuously
ƒ Lagging strand is synthesized discontinuously
ƒ
ƒ RNA primers are removed and Okazaki fragments joined by a DNA polymerase and
DNA ligase
DNA replication is semiconservative
Transcription
ƒ DNA is transcribed to make RNA (mRNA, tRNA, and
rRNA).
ƒ Transcription begins when RNA polymerase binds to
the promotor sequence
ƒ Transcription proceeds in the 5' → 3' direction
ƒ Transcription stops when it reaches the terminator
sequence
Translation
ƒ mRNA is translated in codons (three nucleotides)
ƒ Translation of mRNA begins at the start codon:
ƒ Translation ends at a stop codon:
Regulation of Bacterial Gene Expression
ƒ Constitutive enzymes are expressed at a fixed rate.
ƒ constantly being transcribed and translated into proteins
ƒ Other enzymes are expressed only as needed.
ƒ Repressible enzymes
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1
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induction - inducible genes turned on by inducers
ƒ inducers often substrates required for catabolic pathways
repression - repressible genes turned off by repressors
ƒ repressors are end products of anabolic (________________) pathways - when
sufficient product is made gene gets turned off
this regulation often achieved with the operon
ƒ group of genes that can be induced or repressed
Lac Operon
ƒ Bacteria such as E. coli that can utilize lactose require a lag time during which lac operon
becomes induced.
ƒ If medium contains glucose (preferred sugar) and lactose, lac operon not induced
until / unless glucose all used up.
ƒ
So what if glucose and lactose are present, why not metabolize lactose along with glucose?
ƒ genes for glucose metabolism are constitutive
ƒ activating other genes for more pathways requires energy
ƒ therefore, bacteria conserve energy by using
glucose first, then any other energy sources
Mutation
ƒ
ƒ Mutations may be neutral, beneficial, or harmful.
ƒ Mutagen:
ƒ Spontaneous mutations: Occur in the absence of a mutagen
ƒ Base substitution (_________________________)
ƒ
Missense mutation
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Change in one base
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Results in change in amino acid
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Nonsense mutation
Results in a nonsense codon
ƒ
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Frameshift mutation
Insertion or deletion of one or more nucleotide pairs
ƒ
Ionizing radiation (_________________________) causes the formation of ions that can
react with nucleotides and the deoxyribose-phosphate backbone.
Nucleotide excision repairs mutations
ƒ
ƒ
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Light-repair separates thymine dimers.
ƒ
Is there such a thing as a healthy tan?
ƒ
Should food be irradiated to destroy microbes and increase shelf life?
The Frequency of Mutation
ƒ Spontaneous mutation rate = 1 in 109 replicated base pairs or 1 in 106 replicated genes
ƒ Mutagens increase to 10–5 or 10–3 per replicated gene.
2
Genetic Transfer and Recombination
ƒ Vertical gene transfer: Occurs during reproduction between generations of cells.
ƒ Horizontal gene transfer: The transfer of genes between cells of the same generation.
Transformation
ƒ Purpose of transformation?
ƒ mechanism of transfer of genetic info among bacteria
ƒ occurs naturally with linear pieces of DNA
ƒ under laboratory conditions certain bacteria can be made “competent” and take up
plasmids
ƒ once inside, DNA can undergo recombination with
host chromosome and be inserted
Conjugation
ƒ
ƒ transfer of DNA from one bacterial cell to another
ƒ gram (-) requires pilus
ƒ
ƒ
Gram (-)
ƒ donor cells contain F plasmid (______________) F+
ƒ recipient cells do not contain F plasmid Fƒ if plasmid is extrachromosomal, then F+
ƒ if plasmid is integrated in host chromosome, then Hfr (high frequency of
recombination)
ƒ
ƒ sex pilus from F+ or Hfr cell attaches to F- cell, pilus contracts pulling F- close
ƒ
contrary to text diagram, DNA transfer does not go through the pilus, rather pilus pulls cells
close together, cell walls interact and by as yet unknown mechanism, DNA transferred
recipient cell becomes F+ if donor was F+
recipient cell remains F- if donor was Hfr
bacterial genes get transferred, fertility factor is last thing to transfer
pairing of cells is fragile, usually break apart before end of transfer, therefore recipients
remain F-
ƒ
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Gram (+)
ƒ
ƒ other plasmids involved, mechanism unclear
Transduction
• Bacteriophage (__________) mediated transfer of DNA from one bacterial cell (_______)
to another bacterial cell (_________________).
Genetic Recombination
ƒ Exchange of genes between two DNA molecules
ƒ Crossing over occurs when two chromosomes break and rejoin
Plasmids
ƒ Conjugative plasmid: Carries genes for sex pili and transfer of the plasmid
ƒ Dissimilation plasmids: Encode enzymes for catabolism of unusual compounds
ƒ R factors:
3
Transposons
ƒ Segments of DNA that can move from one region of DNA to another
(__________________________________).
ƒ Contain insertion sequences for cutting and resealing DNA (___________________).
ƒ Complex transposons carry other genes.
ƒ In bacteria, transposons jump between the chromosome and plasmids.
So What?
ƒ Implications of gene transfer among bacteria?
ƒ
All three types of gene transfer can be manipulated by us. Most important is
transformation. We can engineer plasmids to carry a variety of genes and insert them into
bacteria with relative ease.
Study Objectives
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4.
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15.
Define gene, genetics, genome, genomics, genotype, phenotype.
Describe the overall process of DNA replication in prokaryotes and contrast it with
eukaryotic replication.
Describe the process of transcription. How is prokaryotic transcription different from
eukaryotic transcription?
Briefly describe translation.
Compare and contrast gene induction with gene repression.
Compare and contrast inducible operons with repressible operons.
Describe the Lac operon. Why is it inducible and why aren’t those genes constitutively
expressed?
Describe the types of mutations that occur and their possible consequences.
Describe how UV and ionizing radiation damage DNA and cause mutations.
Compare and contrast horizontal and vertical gene transfer.
Describe in detail: transduction, transformation, and conjugation. Differentiate between
generalized and specialized transduction.
Describe how each of the above methods of gene transfer can be exploited by scientists to
manipulate DNA.
Compare and contrast the three types of plasmids discussed here.
Describe transposons.
What are the implications of gene transfer among bacteria?
4