FULL TEST BANK Brock Biology Of Microorganisms, Global Edition 16th Edition By Michael Madigan Questions & Answers With Rationales (Chapter 1-34) New 2024 100% Graded A+
Test Bank Brock Biology of Microorganisms 16th Edition Madigan | Latest Update
TEST BANK FOR BROCK BIOLOGY OF MICROORGANISM 16TH EDITION BY MICHAEL T. MADIGAN A+
9.1 Mutations and Mutants
Bacteria can exchange genes
Horizontal gene transfer = movement of genes between cells other than reproduction
Mutation = heritable change in genome
- can lead to a change in properties of an organism
- some beneficial, some detrimental, most have no effect
● Exponential growth in Prok accumulates mutations quickly
● Horizontal gene transfer (genetic exchange) generates much larger changes
● Mutations and genetic exchange fuel evolution
Genomes of cells: double-stranded DNA
Viral genomes (virus): double or single stranded DNA or RNA
Wild type strain = isolated from nature (naturally occurring form)
- wild type can also refer to just one gene
Mutant
● a cell or virus derived from wild type that carries a nucleotide sequence (genotype)
change
- genotype designated by 3 lowercase letters (followed by capital) (e.g. hisC)
- mutations designated hisC1, hisC2, etc
● Observable properties (phenotype) may also be altered
- phenotype designated by capital letter and 2 lowercase letters, then +/-
(e.g. His+)
- the hisC gene of E. coli encodes a protein called HisC that functions in
biosynthesis of the amino acid histidine
- +/- refers to if the property is present or absent
● Can be obtained from either wild-type or parental strain (derived from wild-type)
,Isolation of Mutants: screening versus selection
● Selectable mutations confer an advantage on organisms possessing them
- under certain environmental conditions, progeny cells outgrow and replace
parent
- example: antibiotic resistance
→ : An antibiotic-resistant mutant can grow in the presence of an antibiotic
that inhibits or kills the parent
- Relatively easy to detect
- powerful genetic tool
● Non Selectable mutations do not confer an advantage, even though they may lead
to phenotypic change
- example: color loss in a pigmented organism
- requires laborious, time consuming screening (examining large numbers and
looking for differences)
a) antibiotic resistance (due to mutant)
b) non selectable mutation
UV radiation-induced non pigmented mutants
c) colonies of mutants
pink is wild type
top is mutant
- understanding physiology is key to designing genetic screens
- selection is preferred whenever possible
Isolation of Nutritional Auxotrophs
● Replica plating screens for nutritionally defective mutants
- transfer colonies from master plate
- Inability of colony to grow medium lacking a nutrient indicates mutation
- colony on master plate is picked, purified and characterized
● Auxotroph has an additional nutritional requirement for growth above that of the wild
type or parental strain from which it was derived → compared with prototroph (wild
type/parental strain)
→ extra nutrient requirement is His if it is His–
● Complementation = isolation of several strain followed by comparative genetic
analyses
● Selection: The term "selection" is used in various contexts, such as natural selection in biology, selection
of candidates for a job, or selection of materials for a specific purpose.
● Screening: "Screening" is often used in the context of evaluating or examining a group to identify those
that meet certain criteria, whether it's in genetics, medical tests, or job applications.
,9.2 Molecular Basis of mutation
Spontaneous or Induced:
Spontaneous mutations
- occur without external intervention
- most result from occasional errors by DNA polymerase during replication
Induced mutations
- caused due to environment or deliberately (intentionally)
- can result from exposure to natural radiation or chemicals that chemically modify
DNA
Point mutations
- change only 1 base pair
- occur via single base-pair substitution
- phenotypic change depends on location of mutation
Base-pair Substitutions: Missense, Nonsense and Silent
- not all mutations change polypeptides
Point mutations
= change in a single base pair
● involves base substitution
●
● Transition = change of a pyrimidine (C,T) to another pyrimidine OR a purine to
another purine (A,G)
→ more common
Pyrimidine → single ring structure (C,T,U)
Purines → double ring structure (A,G)
● Transversion = change of pyrimidine to a purine or vice versa
Silent mutation = those that do not alter the amino acid sequence
even though base seq has changed
, Missense mutation = base substitution where 1 amino acid change results → inhibitory or
neutral effect
- Sickle cell disease → mutation in B globin gene → change in 6st amino acid →
glutamic to valine → alters structure/function of hemoglobin protein → under
conditions of low oxygen, red blood cell has sickle shape
- not all lead to nonfunction
Nonsense mutation = Involve change from codon that results in a STOP sign → inhibitory
effect
- typically results in truncated (incomplete) protein that lacks normal activity
Frameshift mutation = addition or deletion of number of nucleotides that is not divisible by 3
→ shifts the reading frame → completely different amino acids
- often complete loss of gene function
- can be lethal
- may arise from errors during genetic recombination
- large insertions may be due to transposable elements
Neutral mutation = when a missense mutation has no effect on protein function / also silence
mutations
9.3 Reversions and Mutation rates
Mutation rates depend on frequency of DNA changes and efficiency of DNA repair
Reversions (back mutations) and Suppressors
Wild Type → relatively prevalent genotype → most frequent
Forward mutation → changes WT genotype into some new variation
Reverse mutation / Reversion → changes a mutant allele back to the WT
- occurs because point mutations are typically reversible
- Revertant = strain in which original phenotype is restored
● Same-site revertant: Mutation is at the same site as original mutation
● Second-site revertant: Mutation is at a different site in the DNA that restores
wild-type if functions as suppressor mutation compensating for the original
effect
- mutation somewhere else in the same gene that restores the function
- mutation in another gene that restores function
- mutation in another gene that results in production of an enzyme to
replace a nonfunctional gene
Suppressor mutations = this type of mutation acts to suppress the phenotypic effects of
another mutation
- different than reversion → because it occurs at a different site in DNA from the first
mutation
Suppressors best illustrated by tRNA mutations
● Nonsense mutations can be suppressed by changing anticodon sequence to
recognize stop code (suppressor tRNA)
The benefits of buying summaries with Stuvia:
Guaranteed quality through customer reviews
Stuvia customers have reviewed more than 700,000 summaries. This how you know that you are buying the best documents.
Quick and easy check-out
You can quickly pay through credit card or Stuvia-credit for the summaries. There is no membership needed.
Focus on what matters
Your fellow students write the study notes themselves, which is why the documents are always reliable and up-to-date. This ensures you quickly get to the core!
Frequently asked questions
What do I get when I buy this document?
You get a PDF, available immediately after your purchase. The purchased document is accessible anytime, anywhere and indefinitely through your profile.
Satisfaction guarantee: how does it work?
Our satisfaction guarantee ensures that you always find a study document that suits you well. You fill out a form, and our customer service team takes care of the rest.
Who am I buying these notes from?
Stuvia is a marketplace, so you are not buying this document from us, but from seller kayvolders. Stuvia facilitates payment to the seller.
Will I be stuck with a subscription?
No, you only buy these notes for $9.16. You're not tied to anything after your purchase.