f-box containing tubby transcription factor family daisy robinton goldberg lab spring 2006
TRANSCRIPT
F-Box Containing Tubby Transcription
Factor Family
Daisy Robinton
Goldberg Lab
Spring 2006
What is the TUBBY Protein Gene Family?• Studies have shown TUBBY-like proteins to play a vital role in the
maitenance and function of neuronal cells during postdifferentiation and development in mammals
• Members of this family have been identified in many multicellular organisms, but no single-celled organisms
• The tubby domain is highly conserved
• This data suggests that tubby proteins have fundamental biological functions
• A conserved F-box-containing domain is present in plant TUBBY-like protein members
What is this F-box Protein?
• Most F-box domains followed by specific amino acid sequences which are protein-protein interacting domains for recruiting specific proteins and targeting them for ubiquitin mediated proteolysis
• F-box proteins regulate cellular processes (cell-cycle transition, transcriptional regulation and signal transduction)
• F-box proteins regulate plant growth and development
• Serve vital functions in plants as indicated by multiple TLPs, however this may mask the effects of an individual loss-of-function allele
How is this Family Related to Arabidopsis?
• In the Arabidopsis plant there is a TUBBY-like protein gene family with 11 members (named AtTLP1-11)
• All AtTLP members (except 8) have an F-box domain (researchers are not sure, this data was obtained solely via sequencing
• Seven of the AtTLP genes are on the first chromosome
• Two genes, one gene and one gene are on chromosomes II, III and V, respectively
• All members of this family except AtTLP8 contain a conserved F-box domain
• F-box protein has been identified to play an important role during seed development
What Gene am I Working With?
• This gene is 3,029 base pairs long• It is located on the first chromosome• It encodes the F-Box protein• The size of the encoded protein is 446 amino acids
AT1G25280
5’--- ---3’UTR Intron Exon
start stop
Where is my Gene Active?
• Microarray data indicates that this gene is active in all of the above organs during seed development
• However, microarrays are not as accurate as the results obtained in RT-PCR because in RT-PCR we amplify the DNA so that the reaction is more sensitive to the presence of smaller DNA fragments
• My RT-PCR results confirm and agree with the indications from the genechip data. How do I know?
Infl
or +
RT
Infl
or -
RT
Sil +
RT
Sil
-R
T
Posi
tive
Con
trol
Neg
ativ
e C
ontr
ol
What do my RT-PCR Results Mean?
Infl
or +
RT
Infl
or -
RT
Sil +
RT
Sil -
RT
Posi
tive
Con
trol
Neg
ativ
e C
ontr
ol
Gene-SpecificExpected size: 160 bp
Control Bands
• The gene-specific bands indicate that mRNA was made in those organs during seed development, and so we know that our gene is being transcribed during that stage in that organ
Do I Have any Mutant Plants?
• 19 Plants genotyped
• 0 Heterozygous mutants
• 2 Homozygous mutants
• There are three bands in the positive control lane because Melissa’s primers and my primers are present.
Pla
nt 7
Pla
nt 8
Pla
nt 9
Pla
nt 1
0*
Pla
nt 1
2*
Pla
nt 1
1
Pla
nt 1
3
Pla
nt 1
4P
lant
15
Pla
nt 1
6P
lant
17
WT
Pla
nt
Pos
itiv
e C
ontr
ol
Neg
ativ
e C
ontr
ol
Mel
issa
’s D
NA
w/ I
nser
t
Homozygous Mutants Plants 10 and 12Predicted Size: 291 base pairs
Where is the Insert?
• The T-DNA is inserted in the forward direction, interacting with the reverse primer
• The LBb1sequencing reaction begins matching with my WT gene DNA at nucleotide 115 (of the sequencing reaction)
Actual Insertion SiteVia SequencingNucleotide 642LBb1
SALK prediction = insertion site at nucleotide 659 (difference of 17 nucleotides)
5’--- ---3’UTR Intron Exon
start stopRv
Does the Insert Disrupt Seed Development?Because I found homozygous mutants it is indicated that this knockout does not cause seed lethality.However, upon observation of seeds using the Nomarski microscope, interesting phenotypes were found.
Wild Type
Heart Stage Torpedo StageCotyledon Stage
Mutant
Globular
NONEFOUND
There were no other apparent phenotypic differences upon observing the actual plant.
Wild Type v.s. MutantTorpedo Stage
Wild Type
Mutant
When and Where does the “Promoter” Regulate the Transcription of my Gene?
• Predicted size of the cloned region: 3,166 base pairs
• Of approxiamately 97 bacteria colonies, zero were found to be blue
• Verification of colonies containing recombinant plasmids by digestion with Eco R1 yielded confirming results
Col
ony
5 Col
ony
6 Col
ony
7 Col
ony
8
Neg
ativ
e C
ontr
ol
Posi
tive
Con
trol
PCR
Pro
duct
• The T7 and SP6 sequencing seem to be reliable
Compare to Sequencing
What is my Second Gene?AT1G76900
• This gene is 2,506 base pairs long• It is located on the first chromosome• It encodes a Tubby-Like Protein• The size of the encoded protein is 456 amino acids
UTRIntron Exon
start stop
5’--- ---3’
Where is This Gene Active?
• Microarray data indicates that this gene is active in all of the above organs during seed development
• However, microarrays are not as accurate as the results obtained in RT-PCR because in RT-PCR we amplify the DNA so that the reaction is more sensitive to the presence of smaller DNA fragments
• My RT-PCR results confirm & agree with the data from the genechip for the Silique, but not the Infloresence. How do I know?
Inf.
+R
T
Inf.
-R
T
Sil.
-RT
Sil.
+R
T
Posi
tive
Con
trol
Neg
ativ
e C
ontr
ol
What do my RT-PCR Results Mean?
• Note the absence of bands in the -RT lanes (2 and 4)
• There is no gene-specific band in the Infloresence +RT. This indicates that there was no mRNA transcribed during the seed development stage in this organ.
• There is a gene-specific band in the Silique -RT. This indicates that mRNA is transcribed in this organ during seed development.
Inf.
+R
T
Inf.
-R
T
Sil.
-RT
Sil.
+R
T
Posi
tive
Con
trol
Neg
ativ
e C
ontr
ol
Control Bands
Gene-SpecificExpected Size: 498 base pairs
Are there any knockouts?
• 28 Plants genotyped• 0 Heterozygous Mutants• 0 Homozygous Mutants• The separating primers genotyping shows that the LB primer was working (Thi’s DNA
from her first gene SAIL line was used)• Because there are no bands in the other LB reactions, no mutants of any kind were
identified.• Expected Wild Type Size: 2,479 base pairs• Expected Mutant Size: 2, 495 base pairs• The separating primers attends to the problem of the similar size of expected mutant and
WT bands
Multiplex Separating Primers
Plan
t 4Pl
ant 3
Plan
t 2
Plan
t 1
Plan
t 5
Plan
t 6Pl
ant 1
1
Plan
t 12
Plan
t 13
Plan
t 14
Plan
t 15
Plan
t 16
Plan
t 17
Plan
t 18
Plan
t 19
Plan
t 20
Plan
t 21
WT
Pla
nt
Posi
ti ve
Con
t rol
Neg
ati v
e C
ont r
ol
Fw/Rv Fw/LB Rv/LB
LB
Tes
t
What is the Reason for the Absence of Knockouts?
• SALK sent all Wild-Type seeds
• The knockout causes seed lethality, and no seeds survived that contained mutant alleles (dominant mutation)
• More plants need to be grown and genotyped
• The LB was ineffective (for the last batch of genotyping)
Where was the Insert Predicted to Be?
• SALK predicts the insert is in the third exon, at nucleotide 2,151
• The insert is in the reverse direction of my gene, interacting with my forward primer
• The lack of identified mutant plants may indicate disruption in seed development
LB
UTRIntron Exon
start stopFW
5’--- ---3’
When and Where does the “Promoter” Regulate the Transcription of my Gene?
• Predicted Size of Clone Region 2,997 base pairs
• EcoR1 Digestion gel photo unavailable
• Results showed three bands in each lane: one about 3.5kB, one about 1.3kB and one about 1.05kB
• Verification of colonies containing recombinant plasmids by digestion with Eco R1 yielded confirming results
• Of approxiamately 200 bacteria colonies, approx. 75 were found to be blue
PC
R P
rodu
ct
Pos
itiv
e C
ontr
ol
Neg
ativ
e C
ontr
ol
What is the significance of these results?• Studies of the first gene, AT1G25280,
show a very interesting seed phenotype at the torpedo stage
• This phenotype may be an important clue as to the role this gene plays in the Arabidopsis plant
• Studies of the second gene, AT1G76900, have not yet provided any significant results.
• More plants need to be grown and genotyped
• More siliques and seeds should be studied for phenotypic differences
• Because the insert is in an intron, RT-PCR of the mutant should be carried out
What further research should be carried out?
AT1G25280 AT1G76900
• Get new seeds
• More plants need to be grown and genotyped
• Once/if an insert is found, the appropriate experiments should be conducted (as with the first gene)
Thanks!Thanks to SALK, who made our plants (and mixed things up so as to provide valuable learning experiences.
Thanks to Ahnthu, Ria, John and Mike for testing, retesting, explaining, teaching, reteaching, etc etc etc thanks a million times.
Thanks to Tomo, Javier, Brandon and Xingjun forbehind the scenes work and Nomarski.
Thanks to Jessica for food and pictures hahaWhat do you mean in the wrong place?
And finally, thanks to Dr. Goldberg for making it all possible. And the pictures I borrowed for my presentation. :)
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