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Mutation 2014
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L14 Mutation
Forward Geneticsdepends on phenotypic variation as an index of
genetic variation: its inheritance or transmission-genetic pattern; howtransmission is related to chromosome variation; how character andphenotype differences depend on metabolic pathways involving severalgenes that may or may not be functional; how they replicate, expresspeptides and how this expression is regulated, but not source(s) of mutation .
Scale of mutation: this can range from a change in a single base (substitution),through several bases (insertiondeletion), to a chromosome fragment.
Mutation rate is lowWhat really governs mutation rate is the efficiency ofrepair mechanisms. Regardless, the rate is never 0, some base changes(1) goun-repaired, or, (2) repair mechanisms introduce a mutantvariant.
If one of these (1 or 2) occurs in a germ cell (sperm,eggs) which happens tosegregate and produce an embryo, it will be passed on to descendentgenerations.
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Viruses and Prokaryotes the averagebase mutation rate decreasedisometrically (slope ~-1) with
increasing genome size -
Multicellular eukaryotes- the basemutation rate increases with
genome size - a tradeoff with speedand the efficiency of repairmechanisms or drift ?
M. Lynch.2012.Evolution ofthe mutation
rate.Trends inGenetics. V26 pp 345-362
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Mutations are:(1)potentiallypermanent(mutations in somatic cells), and
(2)possibly inheritedchanges in DNA sequence (mutations in germ cells).
Classify:
(A)spontaneous- occurring in the absence of known mutagensor
(B)induced mutations- require an known agent that increases themutation rate significantly above the spontaneous rate.
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Spontaneous mutations
Tautomeric or keto-enol,amino - imino shiftssuggested by Watson &Crick (1953), involve:
(1)the migration of a H-bond ,
(2)
the switch of adjacentsingle and double bonds
Depurination -covalent
bond between sugar andpurine is less stable thansugar-pyrimidine.= rare single base loss
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Rare tautomers
Spontaneous mutations
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Spontaneous (single strand) mutations in germcells may be inherited, if a mutant gameteforms a viable zygote that survives toreproduce.
5Note this tautomeric shift must happen during the process, justbefore/as DNA replicates.
An apurinic site - any complementary base could be substituted
during replication.
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Faithful, but not perfect
spontaneous mutations during replication
Copy errors in replication could cause heritable changes to a DNAsequence.
There are 3 error - checking steps in DNA replication: (1) base selection(2) proof reading (3) mismatch repair
(1) Base selectionif the correct base is not chosen, the polymerase site in theholoenzyme will not be activated.
(2) Proof reading: 3-5exonuclease activity (DNA pol III)
(3)Mismatch repair after replication, the wrong nucleotide will not generallypair correctly, it causes a bulge in the helix, mismatch repair enzymes (Mut S, L
and MutH) scan for bulges, if found soon after replication, non-methylatedstrands are repaired based on its methylated complement. See fig 15-26
If both strands are methylated, the mutation may be inherited (pp 536-538).
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Mutations and their molecular basis (15.3)
High energy radiation causetransitions and transversions.
Transitions- replacement of a base by the other base in the samechemical category (purine/purine A-G, pyrimidine/ pyrimidine (C-T). e.g.
tautomeric shift (pp 520)
Transversions- replacement of a base of one category with a basefrom a different category
Base analogues(pp 526) cause transitions or transversions in thefirst replication. E.g. 5 bromouracil
Intercalating agents(pp 528) cause indels-insertions and deletions.
?conservative - chemically similar neutral mutation?non-conservative- chemically different
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Rare, but frequentcompared to the enolform of thymine.
5 bromouracil is an analogue ofthymine
It forces a tautomericshift
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Intercalating agents mimic base pairs and insertthemselves between them (intercalate) usuallycausing an indel mutation- an insertion ordeletion of one or more bases
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Point Mutations - summary Fig 15-2
1. Point mutations base substitutions,
- synonymous or silent
- missense mutations,
- nonsense mutations- sense mutations
2.
Point mutations -Frame shift mutation -indel mutants
- insertion or deletionof nucleotides,-insertion or loss of one or two nucleotides
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Classify by scale, whether spontaneous or induced
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Point mutations :Synonymous mutations are changes orsubstitutions in a nucleotide sequencethat do not cause a change in
amino acid sequence.
DNA: 3
TAC GCT CCT CTT GGT GCT
Protein Met- Arg- Gly- Glu- Pro- Arg-
Mutant
DNA: 3
TAC GCT CCT CTT GGT GCG
Protein Met- Arg- Gly- Glu- Pro- Arg-
Synonymous mutations have no effect on the protein function
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Point mutations:Missense mutations change a codon, and itmutates to a different amino acid, it is potentially non-silent, it may
be chemically similar, it may be chemically different , thus having anon neutral effect on a character expression. The effect of the amino
acidsubstitutionmay be conservative (similar chemical properties) or
non conservative.
Wild type
DNA: 3
TAC GCT CCT CTT GGT GCT CTA
Protein Met- Arg- Gly- Glu- Pro- Arg- Asp-
Mutant
DNA: TAC GCT CCT CTT GGT CCT CTA
Protein Met- Arg- Gly- Glu- Pro- GLY- Asp-
Some point mutations are very deleterious those that change
critical amino acids in a protein.
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Point mutations:Nonsense mutations change a codon to aSTOP codon
Sense mutations- change a protein coding or
a stop codon to a START codon.
WT
DNA: 3
TAC GCT CCT CTT GGT GCT CTA
Protein Met- Arg- Gly- Glu- Pro- Arg- Asp-
Mutant
DNA: TAC GCT ACT CTT GGT GCT CTA
Protein Met- Arg
Non sense mutations produce truncated proteins and are nearly
always deleterious except those at the extreme carboxyl end.
STOP
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Nonsense mutations change a codon to a STOP
codon.
Sense mutationschange a stop codon to a proteincoding codon.
Same - sense mutationmay be a synonomousmutation which may be silent or noisy synonomous mutation affecting a splice site, anRNAi site or a binding site ( no longer apalindrome)
Missense mutation- change protein coding
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Frame shift mutation - the addition or loss of 1 or 2
nucleotides:
Frame shift mutations change all the amino acid sequence
after the mutation and often introduce stop codons
WT
DNA: 5
ATG CGA CCTGAA GGT GCT CTAProtein Met- Arg- Gly- Glu- Pro- Arg- Asp-
Mutant
DNA: ATG CGA CCTCGA AGG
Protein Met- Arg- Gly- Arg - Arg.
Frame shift mutations are deleterious
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C
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Frame shift mutations can be corrected
by a second mutation up or downstream and
nearby. The negative effect increases with the
size of the frame-shifted sequence.
All amino acids encoded between the two mutations
will be changed. Sometimes short stretches of changed
amino acids will not inactivate a protein.
A 3 base pair addition or deletion mutation
will add or delete one amino acid. In this case the effect
depends on the chemical similarity of the protein with orwithout one of hundreds of amino acids.Any addition or
deletion notdividable by 3will cause a frame shift.
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WT
DNA: 5
ATG CGA CCTGAA GGT GCT CTA
Protein Met- Arg- Gly- Glu- Pro- Ala- Leu-
Mutant
DNA: ATG CGA CCTCGA AGG..
Protein Met- Arg- Gly- Arg - Arg.
2ndMutation
DNA: ATG CGA CCTCGA AGT GCT CTA
Protein Met- Arg- Gly- Arg - Arg Ala- Leu-
Frame shift correction by 2ndindel mutation:
C addition
G deletion
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Forward Genetic Analysis is only possible with genetic
differences: mutants, variants, polymorphisms etc..
The most useful mutations for research are conditional
(lethal) mutations:
(a) Auxotrophic mutants- unable to synthesize essential
metabolites- e.g Beadle & Tathum
(b)
Temperature sensitive mutations-grow or express at one
temperature .
(c) Suppressor-sensitive mutantsare viable when a second
genetic factor a suppressor is present , inviable in the
absence of the suppressor
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Large Sequence Alterations
Large -scale changes in chromosomestructure. See fig 16.19
1.Gene Duplications2.Deletions
3.Inversions4.Translocations
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Human
Normal
Karyotype
Karyotype
from
cancer cell.Note extra copies
lost copies
translocations
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Duplications
A B C D E F G H I J
A B C C D E F G H I J
A B C D E C D E F G H I J
Duplications could create an imbalance in the number
of genes.Evolutionarily, it is clear that duplications give rise to
extra
copies that can evolve to produce novel genes
(paralogs Haemoglobin , ).
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Duplication of globin molecule
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Human chromosome 11, 5 - epsilon gammaG gammaA delta beta - 3.
Human chromosome 16 : 5- zeta - pseudozeta - mu - pseudoalpha-1 -alpha-2 - alpha-1 - theta - 3
Molecularorder (5- 3)
reflects their orderof expression.
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Same gene, different functions, probablyevolved through an inactive duplication
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1.Duplications
2. Deletions of genes or a large portion of its sequence
3.
Inversions
4.
Translocations Many mutations occur in meiosis
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Deletions:
A B C D E F G H I J
A B C E F G H I J
Deletions are usually deleterious they are the lossof genes. They may exist in a heterozygous state. But, (1)imbalance in gene
number can be deleterious. (2) they can uncoverdeleterious recessive
allelesthat may not otherwise be expressed (3) probably due to slippage duringreplication, mispairing in meiosis breakage, deletion & duplication.
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1. Duplications
2. Deletions
3. Sequence inversions of many bases to several genes.
4.
Translocations
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A B C D E F G H I J
A B C F E D G H I J
Inversions either include the centromere or not
Paracentric inversion:- no recombinant offspring (normal & inverted)
A B C G F E D H I J
Pericentric inversion no recombinant offspring, includes thecentromere (normal & inverted)
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In both, recombinants are not viable
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inversion heterozygotes are never recovered
If inversions lead to reduction of numbers of
surviving offspring from crossovers in the inversion
region , what effect do they have on map distance of genesin the region of the inversion ?
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Recombinants are inviable, thus
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1. Duplications
2.
Deletions
3. Inversions
4.
Translocations of chromosome segments
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Reciprocaltranslocations-
break and reciprocal fusion
of non-homologous
chromosomes.
Meiosis I:
Alternate segregation - bothpairs have a complete gene
set - fine
Adjacent segregation pattern
produces inviable gametes
Thus translocation
heterozygotes are semisterile
(fig. 16.30)
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Figure 4-14 Molecular Biology of the Cell ( Garland Science 2008)
Mutjac deer are found in ChinaSE asia and India. While thesespecies are morphologicallysimilar, they are cytogenetically
distinct.
The Chinese muntjac(Muntiacus reevesi) has a 2nnumber of 46in bothSexes.
The Indian muntjac,Muntiacusmuntjak, possesses the lowestdiploid chromosomalnumber in mammals (2n = 6 for
females and 7 for males).
However, these two species,
can produce viable F1hybrids(2n = 27) in captivity, andpartial spermatogenesis wasobserved in hybrids .