Post on 20-Jun-2015
Cleft lip and palate:Examining variations on the ZEB1 gene
Jingwen ZhangThomas Worthington High School ‘14Research Institute: Murray Lab, University of Iowa
Cleft lip and palate: Background
Cleft lip with or without cleft palate (CL/P) is a common birth defect Affects 0.5-2.5% of live births CL/P cases have high morbidity rates due to feeding difficulties,
speech impairment, surgical and dental care, etc. Develops in a variety of phenotypes
Dixon MJ, Marazita ML, Beaty TH, Murray JC. 2011. Cleft lip and palate: synthesizing genetic and environmental influences. Nat Rev Genet 12(3):167-178.
Cleft lip and palate: Background
5-7% CL/P cases syndromic, or mendelian, caused by specific chromosomal malformation patterns
Can affect parts of body other than palate and lip
Van der Woude Syndrome caused by mutations on IRF6
Most cases non-syndromic, caused by variety of genetic and environmental factors interacting to onset CL/P
ZEB1: Background
Zinc finger E-box-binding homeobox 1 Gene on chromosome 10 Plays vital role in epithelial-to-mesenchymal transition (EMT) Expression of ZEB1 decreases expression of epithelial markers such as E-
cadherin, increases mesenchymal markers
E-cadherinα-cateninγ-catenin
CollagenSmooth muscle actinFibronectin
ZEB1 in present experiment
ZEB1: candidate gene for involvement in CL/P development Look for variations within the gene that may be related to CL/P Find mutations that merit further investigation into ZEB1 gene as
potentially involved in CL/P
Predicted: That new variations relating to CL/P would be found in ZEB1 That information regarding previously known SNPs will also be found to
be significant and aid future research in CL/P.
Methods
Experiment: DNA from CL/P cases in the Philippines and Iowa (studied separately) Polymerase chain reactions (PCR), amplified exons and sections of
nearby introns; gel electrophoresis Send plates away for sequencingAnalysis: Analyze clear, successfully sequenced reads on Phred and Phrap Consed
server Look for variations from control genome (obtained from NCBI dbSNP) Check for novelty of SNP mutation on UCSC Genome Browser, Exome
Variant Server, 1000 Genomes Browser. Assess predicted damage of missense mutations on PolyPhen-2.
Results: Total variants found
Exon 1 Exon 2 Exon 3 Exon 4 Exon 6 Exon 9
Iowa 31,610,234 (A/T)
rs7918614 (D64D)
31,784,572 (T/C) (4x)
rs2839664 (A/G) (24x)
-------- 31,815,588 (C/G)
rs12217419 (G91R) (G/A)
rs41289011 (A/G) (8x)
Phil 31,610,282 (T/A)31,610,320 (G/T)31,610,515 (C/G)31,610,638 (C/T)31,610,687 (A/T)
31,750,166 (R87A) (A/G)
rs41289011 (A/G) (6x)
-------- rs220060 (A/G)
31,816,261 (A/G)
rs7918614 (D64D) (10x)
Explanation
13 new mutations found on 10 locations in gene. Indicated by position numbers, as they have not been documented in browsers/servers yet.
Known SNPs found in 7 locations in gene. Indicated by rs numbers. Also indicated: Base change, amino acid change (if any), number of
appearances of mutation
Results: Minor allele count
rs7918614 rs7918614 rs41289011 rs12217419 rs2839664 rs2200600
5
10
15
20
25
30 Minor allele count of known SNPs
CL/P casesControl
Results: SNP minor allele ct. significance
Pop. SNP p-valuePhil rs7918614 0.01
Iowa rs7918614 0.22Iowa rs41289011 0.40Iowa rs12217419 0.88Iowa rs2839664 0.03Phil rs220060 0.35
Results: Total variants found
Exon 1 Exon 2 Exon 3 Exon 4 Exon 6 Exon 9
Iowa 31,610,234 (A/T)
rs7918614 (D64D)
31,784,572 (T/C) (4x)
rs2839664 (A/G) (24x)
-------- 31,815,588 (C/G)
rs12217419 (G91R) (G/A)
rs41289011 (A/G) (8x)
Phil 31,610,282 (T/A)31,610,320 (G/T)31,610,515 (C/G)31,610,638 (C/T)31,610,687 (A/T)
31,750,166 (R87A) (A/G)
rs41289011 (A/G) (6x)
-------- rs220060 (A/G)
31,816,261 (A/G)
rs7918614 (D64D) (10x)
Explanation
Compared the Minor Allele Counts of known SNPs in cases studied to the minor allele counts from the control population (control data obtained from NCBI dbSNP).
In several of these SNPs, the minor allele counts of cases were significantly higher (p<0.05).
One of these SNPs is located in the Iowan population, the other in the Filipino population, suggesting that CL/P in these isolated populations may have developed with different mechanisms.
Results: Variant on exon 2
R87 R87
A G A
G87 87
G G AExon 2 Exon 3
Explanation
Only one new mutation was found in a coding section of the gene. Changes arginine to glycine.
Amino acid is split over exons 2 and 3 Predicted by PolyPhen-2 to be benign, but could possibly affect splicing.
Results: New variations MAF
31610234
31610282
31610320
31610515
31610638
31610687
31784572
31815588
31816261
317501660.000
0.005
0.010
0.015
0.020
0.025
New SNP MAF
MAF
Explanation
Minor Allele Frequencies of new SNPs found. New; most are very rare.
Results: Orthologous conservation
Human
Rhesus
MouseDog
Elephant
Opossum
Chicken
X_tropicalis
Zebrafish
Conserved in: 5/7 7/7 5/5 6/8 8/8 8/9 2/2 6/7 6/9
SNP conservation
Rhesus
Explanation
Shows orthological conservation (conservation between species) of the locations of the gene in which new SNPs were found.
Green = conserved; Orange = not conserved; Gray = no data given Orthological conservation important in speciation and evolutionary
studies; the more conserved a region is through more species, the more importance it may have.
Summary of results
13 new variants – 10 locations 1 new SNP in coding region split across 2 exons 7 locations of known SNPs Higher minor allele count of known SNPs (rs7918614, rs2839664) in
CL/P cases than in unaffected controls.– Statistically significant (p<0.05)– rs2839664 significant in Iowa pop., rs7918614 significant in Filipino pop.
Some new non-coding variations located in conserved regions of introns
Future research
Research non-coding SNPs – TF binding sites and gene expression Explore possible link between frequently recurring known SNPs and
development of CL/P Research CL/P in a geographical context, exploring how isolated
pathways developed independently Examine interaction of new genetic factors with environmental factors
and how the two work together to cause CL/P Broaden scope of experiment
Acknowledgements
Dr. Jeff MurrayFor giving me the opportunity and resources for this research project
Maria A. MansillaFor mentoring me throughout the experiment and analysis processes
Elizabeth LeslieFor helping to answer my technical questions
The Murray LabFor their welcome and support