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LECTURE 23: DISSECTION OF GENE FUNCTION I: GENETIC FINE STRUCTURE

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1 LECTURE 23: DISSECTION OF GENE FUNCTION I: GENETIC FINE STRUCTURE
chapter 16 bead theory phage cross gene = unit of structure? gene = unit of change? gene = unit of function? summary problems

2 BEAD THEORY bead theory: chromosome = linear (1-D) array of genes
genes are defined by mutant alleles that ... affect single characters / traits map to single locus on chromosome result in mutant phenotypes when individuals are homozygous recessive show Mendelian ratios in progeny of crosses

3 BEAD THEORY testable bead theory hypotheses:
1. gene as fundamental unit of structure... indivisible by crossing over 2. gene as fundamental unit of change... mutations change alleles from one form to another; there are no smaller units within genes that can change 3. gene as fundamental unit of function... parts of genes cannot function alone in tests of complementation

4 PHAGE CROSS Benzer (50’s) studied rII gene of T4 bacteriophage infecting E. coli hosts to test the bead theory... began as physicist (like Delbrück, Brenner & others) looking for physical properties unique to living matter most important & influential geneticist (personal bias) rigorous reductionist approach from physics made most important link between classical / Mendelian genetics & modern molecular biology now looks for genes to extend lifespan (in flies)

5 PHAGE CROSS Benzer (50’s) studied rII gene of T4 bacteriophage infecting E. coli hosts to test these hypotheses...

6 PHAGE CROSS Benzer (50’s) studied rII gene of T4 bacteriophage infecting E. coli hosts to test these hypotheses... rII mutants are conditional... grow in E. coli B  B is permissive host

7 PHAGE CROSS Benzer (50’s) studied rII gene of T4 bacteriophage infecting E. coli hosts to test these hypotheses... rII mutants are conditional... grow in E. coli B but not K  B is permissive host, K is restrictive host

8 PHAGE CROSS Benzer (50’s) studied rII gene of T4 bacteriophage infecting E. coli hosts to test these hypotheses... large, round small, ragged

9 GENE = UNIT OF STRUCTURE?
hypothesis #1: gene is fundamental unit of structure... indivisible by crossing over ?

10 GENE = UNIT OF STRUCTURE?
hypothesis #1: gene is fundamental unit of change... indivisible by crossing over ? PFU on B = total, PFU on K = ½ of recombinants recomb. frequency (RF) = 2(PFU on K) / PFU on B

11 GENE = UNIT OF STRUCTURE?
hypothesis #1: gene is fundamental unit of structure... indivisible by crossing over ? PFU on B = total, PFU on K = ½ of recombinants recomb. frequency (RF) = 2(PFU on K) / PFU on B

12 GENE = UNIT OF STRUCTURE?
what is the smallest unit of recombination detectable? phage system can detect 1 mutation in 109 progeny recombination frequency (RF) = 1 x 10–9  smallest distance = 1 x 10–7 cM if 1 cM  5 x 105 bp (on average, in flies)  bp are separated by 2 x 10–6 cM phage system ~20x more powerful than needed to detect smallest possible distance (which we now know is adjacent base pairs) phage is the ultimate genetic system ... resolution!!

13 GENE = UNIT OF STRUCTURE?
hypothesis #1: gene is fundamental unit of structure... indivisible by crossing over ? ...

14 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? same experimental protocol as for #1

15 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? same experimental protocol as for #1

16 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? same experimental protocol as for #1 mutants from #1 were deletions when they did not ... recombine with some other mutants ever revert back to wild type deletions used to map positions of mutational sites

17 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? all survive on... B only

18 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 + + 5

19 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 + + 5

20 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 5 survive on... B only K & B + +

21 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 +

22 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 + survive on... B only K & B

23 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 +

24 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? 4 +

25 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? no recombination 4 + survive on... B only

26 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? D1 D2 D3 D4

27 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? D1 D2 D3 D4 A B C D E F G

28 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ?

29 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene ? ...

30 GENE = UNIT OF CHANGE? hypothesis #2: gene is fundamental unit of change... mutations change alleles from one form to another; there are no smaller mutable units within a gene...  point mutations (= revert to wild type at low frequency) mapped to regions defined by deletion mutations point mutations in the same regions that did not recombine with each other were identical sites distribution of rII point mutations was not random...

31 GENE = UNIT OF CHANGE? distribution of rII point mutations was not random... hot spots & cold spots

32 GENE = UNIT OF CHANGE? Poisson distribution predicted missed cold spots observed hot spots (e.g.) site = nucleotide base pair

33 GENE = UNIT OF CHANGE? summary of fine structure mapping of rII region in T4

34 GENE = UNIT OF FUNCTION? hypothesis #3: gene is fundamental unit of function... parts of genes cannot function in complementation tests ?

35  GENE = UNIT OF FUNCTION?
hypothesis #3: gene is fundamental unit of function... parts of genes cannot function in complementation tests ?... mutants fell into two functional groups... 2 genes mutations fail to complement others in the same group

36 SUMMARY complementation or recombination ? complementation...
protein level, mixing of gene products no change in genotypes relative to parents requires 1 generation of crosses to investigate recombination... DNA level results in new genotypes relative to parents requires 2 generations of crosses to investigate

37 SUMMARY complementation or recombination?
test single phage from E. coli K lysate (F1) for infection on E. coli B & E. coli K (F2)

38  SUMMARY if you are dealing with complementation (only)...
or high F count no F1 all F1 F2 plaques on E. coli B but all still mutant,  no F1 F2 plaques on E. coli K

39 but all recombinant F1 F2 plaques on E. coli B
SUMMARY if you are dealing with recombination (only)... low F1 count but all recombinant F1 F2 plaques on E. coli B

40 only ½ recombinant F1 F2 plaques on E. coli K
SUMMARY if you are dealing with recombination (only)... low F1 count only ½ recombinant F1 F2 plaques on E. coli K

41 all F1 F2 plaques on E. coli B
SUMMARY reality... recombination & complementation ... or high F count low F1 all F1 F2 plaques on E. coli B

42  SUMMARY reality... recombination & complementation ...
or high F count low F1 all F1 F2 plaques on E. coli B only ½ recombinant F1 F2 plaques on E. coli K

43     SUMMARY testable bead theory hypotheses:
1. gene as fundamental unit of structure... indivisible by crossing over 2. gene as fundamental unit of change... mutations change alleles from one form to another; there are no smaller units within genes that can change 3. gene as fundamental unit of function... parts of genes cannot function alone in tests of complementation

44 PROBLEMS stay tuned...

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