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LECTURE 20
MUTATION, REPAIR & RECOMBINATION II
 chapter 14
 point mutations
 spontaneous mutations
 biological repair
 meiotic crossing-over
LECTURE 20
MUTATION, REPAIR & RECOMBINATION II
you need a piece of paper and a pen or pencil...
write your name and student number at the top...
give brief answers for the question(s) below...
DNA
repair
(1)
Meiotic crossing-over
is associated
double stranded DNA breakage/damage (1)
with what process?
heteroduplex DNA (½)
recombination (½)
gene conversion (½)
TUTORING
CLARK COUNTY HIGH SCHOOL STUDENTS
go to schools in person
ask to speak with the guidance councellor
Las Vegas High School
6500 E. Sahara
Dr. Patrice Johnson, Principal @ 799.0180
SPONTANEOUS MUTATIONS
 mutation frequency = mutants / population (0  1)
 generally rare
 variable ~ gene
SPONTANEOUS MUTATIONS
 mutation frequency = mutants / population (0  1)
 = 2/8 = 0.25

SPONTANEOUS MUTATIONS
 mutation frequency = mutants / population (0  1)
 = 2/8 = 0.25
 mutation rate = mutation events / gene / time...
 1 mutation event (M)
 7 cell divisions
 1/7 = 0.143







SPONTANEOUS MUTATIONS
 mutation rate = mutation events / gene / time...
SPONTANEOUS MUTATIONS
 mutation rate = mutation events / gene / time...
 1 mutation event (M)
 7 cell divisions
 1/7 = 0.143
 measurement... need
 # cell divisions

= n – initial cell #
=8–1=7


 n in cultures
 “0 class” frequency 



SPONTANEOUS MUTATIONS
 measurement... mutation rate ()
 Poisson distribution
 mutational events / cell division = 
 mutational events / culture = n
 frequency of cultures with 0
mutants = e–n
 e.g. if n = 0.2  108 cells
 0 class = e–n = 11/20 = 0.55
8)
–(0.2

10
 0.55 = e
   3  10–8 events / cell division
SPONTANEOUS MUTATIONS
 Calculate the mutation rate / cell division / resistance
gene in 108 Tons E. coli spread on 100 minimal
media plates with T1 phage where 31 of these plates
had no growth.
 n = 108 cells (–1 = # cell divisions)
 0 class = e–n = 31/100 = 0.31
 0.31 =
8)
–(10
e
  = 1.17  10–8 events / cell division / gene
SPONTANEOUS MUTATIONS
 spontaneous lesions
 depurination = loss of A or G
 deamination of C  U or 5-methyl-C  T
depurination > deamination
 oxidative damage
SPONTANEOUS MUTATIONS
 spontaneous lesions
 depurination = loss of A or G
break sugar • base glycosidic bond
mammalian cells loose ~ 104 purines / cell / gen.
error-prone SOS repair
SPONTANEOUS MUTATIONS
 spontaneous lesions
 deamination of C  U or 5-methyl-C  T
GC  AT transitions
U repairable
T not... hot spots
SPONTANEOUS MUTATIONS
 spontaneous lesions
 oxidative damage of G  8-oxodG (GO)
active O species (O2–, H2O2, OH–)
GC  TA transversions
SPONTANEOUS MUTATIONS
 replication errors  framshift mutations
 repeat DNA sequences  slipped mispairing
INDUCED MUTATIONS
INDUCED MUTATIONS
 reversion tests
 tell us about the nature of the forward mutation
 ... and action of the mutagens used
 e.g. mutagen specificity implied if it does not revert
its own forward reaction
INDUCED MUTATIONS
 reversion tests... example question, p. 479, # 27
MUTANT
1
2
3
4
5
1.
2.
3.
4.
5.
5-BU
HA (GC>AT
(transitions) transitions only)
–
–
+
–
+
–
–
–
–
+
PROFLAVIN
(frameshifts)
SPONTANEOUS
REVERSION
–
+
–
–
–
–
+
+
+
+
likely a deletion, perhaps caused by radiation as nothing will revert it
frameshift, reverted by proflavin and spontaneously
GC > AT transition, not reverted by 1-way mutagen
transversion, none of the chemical mutagens will revert it
AT > GC transition, reverted by GC > AT transitions only
BIOLOGICAL REPAIR
 error-free repair
(a) chemical repair of
DNA base damage
(b & c) 2 step process:
1. damaged DNA
deleted,
2. complementary
template strand used
to restore sequence
BIOLOGICAL REPAIR
 chemical repair of DNA base damage (a)
 photorepair with photolyase + visible light
BIOLOGICAL REPAIR
 chemical repair of DNA base damage (a)
 alkyltransferase (e.g. methyltransferase)
 removes methyl groups, e.g. added by EMS
BIOLOGICAL REPAIR
 homology-dependent repair, 2 general types
 excision repair (b)
base excision repair
nucleotide excision repair in prokaryotes
transcription-coupled repair in eukaryotes
 postreplication repair (c)
in prokaryotes
in eukaryotes
BIOLOGICAL REPAIR
 excision repair
 base excision repair
DNA glycosylases cleave basesugar bonds (different types)
 apurinic or apyrimidinic sites
enzymes: 1. AP endonuclease
2. excision exonuclease
3. DNA polymerase, 4. ligase
more ways to damage bases
than # of DNA glycosylases...
BIOLOGICAL REPAIR
 excision repair
 nucleotide excision repair (prokaryotes)
detects distortions in DNA
enzymes:
1. uvrABC exinucleases
removes 8+4 nucleotides
2. DNA pol I
3. ligase
BIOLOGICAL REPAIR
 excision repair
 transcription-coupled repair (eukaryotes)
important, many cells
terminally differentiated
& no longer dividing
no replication-repair
damage blocks
transcription
detects distortions in DNA
BIOLOGICAL REPAIR
 excision repair
 transcription-coupled repair (eukaryotes)
repairisome (>20 subunits)
7 of these part of
transcription machinery
removes ~ 30 nucleotides
preferentially repairs
template strand
bubble forms, excision,
DNA synthesis & ligation
BIOLOGICAL REPAIR
 excision repair
 postreplication-repair (prokaryotes)
replication errors
missed by proof-reading function of DNA pol
mismatch-repair system
1. recognizes mismatch
2. distinguishes incorrect
base from correct
 errors always on new
unmethylated strand
3. excise incorrect base
 repair synthesis
BIOLOGICAL REPAIR
 excision repair
 postreplication-repair
(eukaryotes)
microsatelites, some in
critical coding regions
slipped-mispairing 
replication errors
missed by proof-reading
function of DNA pol
mismatch-repair system
BIOLOGICAL REPAIR
 error-prone repair
 double stranded breaks from
reactive oxygen species
ionizing radiation (X-rays, -rays)
 unlike single stranded damage
no exact template, no error-free repair...
 error-prone repair less harmful than no repair at all
SOS (already discussed)
non-homologous end joining
homologous recombination
BIOLOGICAL REPAIR
 SOS repair
 error-prone DNA
polymerases
 translesion DNA
synthesis
 mutagenic
BIOLOGICAL REPAIR
 non-homologous end joining
 bind broken ends
 trimming
 joining
 involved in generating rearrangements of antibody
genes in mammalian immune systems
BIOLOGICAL REPAIR
 homologous recombination
 homologous sister
chromatids
 trim ends
 DNA-protein filament
 homology search &
strand invasion
 DNA synthesis
 ligation
 ~ crossing-over
MEIOTIC CROSSING-OVER
 initiated by double-stranded chromosome breakage
 between 2 homologous non-sister chromatids
 no gain or loss of genetic material
 2 steps
 double stranded breakage
 heteroduplex DNA formed, derived from non-sister
chromatids on homologous chromosomes
MEIOTIC CROSSING-OVER
 evidence first from aberrant ratios observed in fungi
 aberrant asci have > 4 copies of on genotype
 extra copies changed through gene conversion
 5:3 ratio from non-identical sister spores in meiosis
 with heteroduplex...
A
A
A
A
a
a
a
a
MEIOTIC CROSSING-OVER
 evidence first from aberrant ratios observed in fungi
 aberrant asci have > 4 copies of on genotype
 extra copies changed through gene conversion
 5:3 ratio from non-identical sister spores in meiosis
 with heteroduplex not repaired
A
A
A
a
a
a
a
a
MEIOTIC CROSSING-OVER
 evidence first from aberrant ratios observed in fungi
 aberrant asci have > 4 copies of on genotype
 extra copies changed through gene conversion
 6:2 ratio from non-identical sister spores in meiosis
 with heteroduplex repaired
A
A
a
a
a
a
a
a
MEIOTIC CROSSING-OVER
 double-stranded break model of crossing-over
MEIOTIC CROSSING-OVER
 double-stranded break model of crossing-over
MEIOTIC CROSSING-OVER
 double-stranded break model of crossing-over
MEIOTIC CROSSING-OVER
 how to think about this problem...
BRANCH MIGRATION
 conversion
 “horizontal
breakage”
ROTATE PERSPECTIVE
BREAKS
MEIOTIC CROSSING-OVER
 how to think about this problem...
BRANCH MIGRATION
 recombination
 “vertical
breakage”
ROTATE PERSPECTIVE
BREAKS
MEIOTIC CROSSING-OVER
 how to think about this problem...
BRANCH MIGRATION
thanks to Bill Engels, Univ. Wisconsin
MEIOTIC CROSSING-OVER
 how to think about this problem...
ROTATE PERSECTIVE
thanks to Bill Engels, Univ. Wisconsin
MEIOTIC CROSSING-OVER
 recombination between alleles of a gene
 intragenic recombination
 obviously, shorter distances, lower recovery rates
a1
A1+

A2+
GENE A
a2
a1 A2+
a1 a2
A1+ A2+
A1+ a2
SPEND SOME TIME ON...
 unsolved problems (p.478-80)
 1- 36
 try all of them on your own first
 then see me / TAs if you have difficulties
NEUROBIOLOGY – BIOL 475 / 604
TR 4:00 – 5:15
CBC A108
Behavioral Neurobiology: The
Cellular Organization of Natural
Behavior
by Thomas J. Carew