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Apetala1 Mutant.

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Presentation on theme: "Apetala1 Mutant."— Presentation transcript:

1 Apetala1 Mutant

2 Testing the ABC floral-organ identity model: cloning the genes
Objectives: To test the validity of the ABC model for floral organ identity we will: Use the model to make predictions concerning the phenotype of double or triple loss-of function mutants and compare with the actual double mutant phenotypes. Clone and sequence the ABC genes. Look for similarities with sequenced genes already in the database. Determine the time and place of expression for each ABC gene and consider whether the expression correlates with the functional domain defined by the loss-of-function phenotype. Test regulatory interactions between ABC genes by examining how the loss-of-function of one gene affects the expression domain of another. Create gain-of-function mutants by generating transgenic plants carrying an ABC gene cDNA under the control of the CaMV35S promoter.

3 Testing the ABC floral-organ identity model: cloning the genes
Objectives: To test the validity of the ABC model for floral organ identity we will: Use the model to make predictions concerning the phenotype of double or triple loss-of function mutants and compare with the actual double mutant phenotypes. Clone and sequence the ABC genes. Look for similarities with sequenced genes already in the database. Determine the time and place of expression for each ABC gene and consider whether the expression correlates with the functional domain defined by the loss-of-function phenotype. Test regulatory interactions between ABC genes by examining how the loss-of-function of one gene affects the expression domain of another. Create gain-of-function mutants by generating transgenic plants carrying an ABC gene cDNA under the control of the CaMV35S promoter.

4 A Model For Control of Floral Organ Type
sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG)

5 Cloning the ABC genes gene method cloned protein identity
AG cloned by TDNA insertion AP3 MADS-box transcription factor

6 Deficiens Mutant of Antirrhinum (snapdragon)

7 AP3 and PI have orthologues in Antirrhinum majus (snap dragon)
AP3 = Deficiens (Def) Deficiens was cloned by transposon tagging. Deficiens encodes a MADS-box transcription factor.

8 Cloning the ABC genes gene method cloned protein identity
AG cloned by TDNA insertion AP3 cloned by homology to DEFICIENS (Deficiens hybridized to a clone from an Arabidopsis cosmid library. RFLPs Identifying that clone mapped to the AP3 locus). MADS-box transcription factor MADS-box transcription factor

9 AP3 and PI have orthologues in Antirrhinum majus (snap dragon)
AP3 = Deficiens (Def) Deficiens was cloned by transposon tagging. Deficiens encodes a MADS-box transcription factor. PI = Globosa (Glo) Globosa was cloned by homology to Deficiens. (Deficiens hybridized to a clone from a floral cDNA library and RFLPs identifying the clone mapped to the position of GLO).

10 Cloning the ABC genes gene method cloned protein identity
AG cloned by TDNA insertion AP3 cloned by homology to DEFICIENS PI cloned by homology to GLOBOSA, a Class B gene from Antirrhinum. GLO was cloned by homology to DEF. MADS-box transcription factor MADS-box transcription factor MADS-box transcription factor (GLOBOSA hybridized to a clone from an Arabidopsis floral cDNA library. RFLPs identifying that clone mapped to the PI locus).

11 Cloning the ABC genes gene method cloned protein identity
AP1 cloned by homology to AG. AP2 cloned by TDNA insertion DEFICIENS was cloned first followed by AG MADS-box transcription factor AP2 transcription factor

12 AG Blast results homology over 56 aa sequence
AGAMOUS Arabidopsis, Class C, floral organ identity gene NH2-GRGKIEIKRIENTTNRQVTFCKRRNGLLKKAYELSVLCDAEVALIVFSSRGRLYEY-COOH DEFICIENS Antirrhinum, Class B, floral organ identity gene ARGKIQIKRIENQTNRQVTYSKRRNGLFKKAHELSVLCDAKVSIIMISSTQKLHEY SERUM RESPONSE FACTOR, human, activates gene in response to growth factor hormones ARVKIKMEFIDNKLRRYTTFSKRKTGIMKKAYELSTLTGTQCLLLVASETGHVYTF MINI CHROMOSOME MAINTENANCE1, yeast, regulates mating type ERRKIEIKFIENKTRRHVTFSKRKHGIMKKAFELSVLTGTQVLLLVVSETGLVYTF What do these genes have in common?

13 Plant Type II MADS-domain protein structure
NH2 COOH N MADS I K C Region of homology shared between all MADS domain transcription factors

14 SRF DNA Binding The MADS domain binds the core DNA sequence CC[A/T]6GG = CArG box

15 Plant Type II MADS-domain protein structure
NH2 COOH N MADS I K C Region of homology shared between MADS domain transcription factors Region of homology shared between many plant MADS domain transcription factors

16 (K)eratin domain AG NH2QESAKLRQQIISIQNSNRQLMGETIGSMSPKELRNLEGRLERSITRIRSKKNELCOOH NH2QQNKVLDTKWTLLQEQGTKTVRQNLEPLFEQYINNLRRQLDSIVGERGRLDSELCOOH Keratin amino acids with nonpolar side chains: eg. Leucine(L), Methionine (M) Isoleucine (I), Tryptophan (W), Glycine (G), Valine (V) amino acids with polar side uncharged chains: eg. Serine (S), Threonine (T), Asparagine (N)

17 Protein alpha helix http://www.uic.edu/classes/phyb/phyb516/TM2.jpg

18 Interaction of amphipathic alpha helices

19 Two Proteins each with an amphipathic alpha helix can interact to form a coiled-coil

20 SRF DNA Binding

21 Prediction for MADS floral organ identity genes
Floral organ-identity MADS genes are DNA binding proteins that interact with other polypeptides.


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