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RARE Germline variability in pediatric leukemia.

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Sequencing of the CFTR gene was initiated. ... ATM CDKN1A CYP1A1 CYP3A5 IKZF1 MDM2 MLL MTHFR NAT2 NQO1 PAX5 PTPN11 TCF3 TPMT Overexpressed genes: ... – PowerPoint PPT presentation

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Title: RARE Germline variability in pediatric leukemia.


1
RARE Germline variability in pediatric leukemia.
  • Cancer Biology Series
  • January 29, 2013
  • Todd Druley, MD, PhD
  • Assistant Professor of Pediatric and Genetics

2
Presenter Disclosure InformationTodd E. Druley,
M.D., Ph.D.Druley Lab / WUSM CGSSB
In compliance with ACCME policy, WU requires the
following disclosures to the session audience
Research Support/P.I. No relevant conflicts of interest to declare
Employee No relevant conflicts of interest to declare
Consultant No relevant conflicts of interest to declare
Major Stockholder No relevant conflicts of interest to declare
Speakers Bureau No relevant conflicts of interest to declare
Scientific Advisory Board No relevant conflicts of interest to declare
3
Why study rare variation?
  • Whole genomes show 2-4 million variants PER
    PERSON!
  • Only about 25 33 of these are common (gt2
    MAF).
  • There are roughly 22,000 human genes
  • This equals 40,000,000 nucleotides total for all
    of our genes.
  • 1.5 of the entire genome
  • If 2 individual genomes differ by
  • 2M x 0.67 1,340,000 nucleotides
  • There are 1.8 x 1012 possible combinations
    between the two genomes!!

4
Common vs. Rare Variants
  • Critical differences between common and rare
    variant analysis include
  • Rare variants have greater effect sizes average
    OR3.7 (Bodmer Nat Genet
    2008)
  • Disruptive rare variants are more likely to act
    dominantly (Fearnhead Cell Cycle
    2005)
  • Rare variants are individually rare, but
    collectively common when collapsed (binned)
    within a genetic locus or metabolic pathway
    (Cohen Science 2004 Ji Nat
    Genet 2008)

5
Antonarakis SE et al. Nature Rev Genet 2009.
Private
6
Antonarakis SE et al. Nature Rev Genet 2009.
Were operating here
Private
7
Example
  • Cystic Fibrosis
  • Originally thought that only the ?F508 mutation
    was causative for CF.
  • Sequencing of the CFTR gene was initiated.
  • Now over 1000 mutations in CFTR have been
    documented.
  • Cause various severities of cystic fibrosis.

http//www.ccb.sickkids.ca/index.php/cystic-fibros
is-mutation-database.html
8
Complex diseases demonstrating increased rare
variation
AJHG 80, 779-791 2007
  • Obesity
  • High Cholesterol
  • Sequenced two groups of 128 individuals each
  • Psychiatric illness, cancer, autoimmune
    disorders, heart disease, height,
  • extreme longevity, many others

9
What about pediatric cancer?
  • Early onset cancer defined as cancer lt50
    years old
  • Germline cancer causing gene alleles (TP53,
    APC, BRCA1) average age of disease onset is
    20s
  • Cannot explain the incidence of pediatric cancer
    by somatic mutation.
  • Epi studies have failed to explain exposures
    causing these cancers.
  • Almost all pediatric cancer patients have a
    negative family history.
  • So why do we see 3 children/week with a new
    cancer??

10
Infant acute leukemia worst outcomes
  • 50 mortality, 67 with MLL-rearrangements
  • MLL regulates developmental transcription (HOX
    genes)
  • Survivors often left with developmental problems
  • COG AE24 Epidemiology of Infant Leukemia
  • Largest case-control study to date looking for
    pre/perinatal exposures associated with infant
    leukemia
  • Topoisomerase II inhibitor exposure during
    pregnancy
  • Only associated with AML, but didnt impact
    survival
  • Ross JA, J Nat Cancer Inst Monogr 2008

11
Pilot exome sequencing experiment
  • GERMLINE exome sequencing from 25 pairs of
    mothers and infants with MLL-negative acute
    leukemia
  • Julie Ross, PhD (PI) and Amy Linabery, PhD.
  • We are looking at genes with rare variants in
    affected infants, but also inherited from mothers
  • These parents typically dont have leukemia or
    other cancers.
  • We hypothesize a combinatorial effect from
    parental variants contributes to the early
    onset/short latency of leukemia.

12
Demographics
25 pairs of Caucasian mothers and infants 12
ALL, 13 AML
13
Validated bioinformatics
  • We analyzed exome data using a validated
    bioinformatic pipeline
  • Align using Novoalign
  • Call variants with SAMtools
  • Sensitivity 97
  • Specificity 99.8

14
Variant calls in COSMIC genes
  • Prioritize by comparing our variant calls in
    genes already associated with hematologic
    malignancies in the COSMIC database.
  • http//www.sanger.ac.uk/genetics/CGP/cosmic/
  • ALL (126 ALL-associated genes)
  • Infants 695 total variants (481 known, 214
    novel)
  • Mothers 728 total (588 known, 140 novel 65)
  • AML (657 AML-associated genes)
  • Infants 5517 total (3961 known, 1556 novel)
  • Mothers 4735 total (4264 known, 471 novel 30)

15
Permutation testing
Average ALL 5 variant genes/infant, AML
6 variant genes/infant
Null distribution
Null distribution
Both sets of infants have a statistically
significant (Plt10-7) enrichment of novel,
non-synonymous, deleterious germline variants in
genes associated with hematopoietic malignancies
(COSMIC).
Mark Valentine
16
Validation
  • No significant enrichment in randomly chosen gene
    sets in infants
  • No significant enrichment in random or leukemia
    gene sets in Caucasian unaffected exomes
  • Unlikely to see the same novel variant in only
    related mother infant pairs by chance.
  • 45 in ALL 23 in AML
  • Consistent with maternal totals of 65 30,
    respectively
  • Sanger validation of other variants is ongoing

17
micro-RNA regulation?
  • Many variant candidate genes are regulated by
    MIRs independently associated with leukemia and
    cell cycle regulation

Nick Sanchez
18
Pathway Analysis
  • ABC transporters
  • Developmental defects
  • Chloride channel regulator activity
  • Transcription factor dysregulation
  • YYI, Cdx, HNF1, MAF, EA2
  • TDG glycosylase mediated binding and cleavage of
    a thymine, uracil or ethenocytosine opposite a
    guanine

19
Implications / Conclusions
  • Supports the hypothesis that infants with
    leukemia are born with a putatively functional
    enrichment of variation in genes associated with
    leukemogenesis.
  • Infants with AML have an excess of novel,
    nonsynonymous, deleterious variation not from
    mother.
  • Paternal age de novo mutation during
    spermatogenesis?
  • De novo mutation during embryogenesis?
  • Can we identify discreet biological/developmental
    and regulatory mechanisms leading to early onset
    leukemia?
  • MIRs
  • ABC transporters
  • Specific transcription factors

20
Future work
  • SHORT TERM
  • Complete the bioinformatic analysis
  • Compare to existing data (TARGET and PCGP)
  • Exome sequencing of 25 MLL-positive pairs
  • LONG TERM
  • Validate results in a second cohort of triads
  • Establish model systems to study complex genetic
    interactions
  • Integrate information into clinical trials?

21
High-risk pediatric ALL Pooled sequencing
  1. Patient germline (N96)
  2. Patient leukemia (N96)
  3. Unaffected controls (N93)

55 genes per pool
22
Candidate genes for pooled sequencing
  • 55 genes selected for pooled sequencing
  • All genes have been published in relation to
    pediatric ALL
  • 43 were identified near significant tagged-SNPs
    on the prior array (asterisks)
  • Various cellular functions

23
Pooled sequencing pilot project
  • Sequenced 94.5 of coding regions from all three
    pools.
  • 420 kb per person 1.2 x 108 total bases covered

Total Variants Coverage/Allele
Unaffected 4209 80-fold
Germline 3929 86-fold
Leukemia 3822 101-fold
24
  • Validation at 384 base positions by custom
    Illumina GoldenGate array

25
Overlap
  • 49 of called variants are unique to the ALL
    Germline pool
  • Only 2.5 of Leukemia variants were NOT seen in
    the Germline pool (97.5 overlap)
  • Somatic mutations

Germline pool NOT in Unaffected Leukemia pool NOT in Germline
Total variants 1915 (49) 96 (2.5)
Coding substitutions 233 (12) (20) 22 novel mutations in UTRs 5 within putative splice site
Novel 175 (75) 15 (79)
Non-synonymous Synonymous 162 (70) 71 14 (74) 5
Damaging (per SIFT) 89 (38) 84 missense 5 nonsense 9 (47) all missense
Coding Insertions/Deletions 9 7 11 in UTR or splice site
Causes protein dysfunction (per SIFT)? 6 3 MLL, 1 ATM, 1 PAX5, 1 LEF1 7 6 MLL, 1 TCF3
26
Visualizing the dataset
Leukemia SNPs (x)
Germline SNPs ()
Amplicons
Control SNPs (?)
High
Conservation Across Species
Low
Joe Giacalone Mark Valentine
27
Visualizing the dataset
Leukemia SNPs (x)
Germline SNPs ()
Amplicons
Control SNPs (?)
High
Conservation Across Species
Low
  1. No variants in control group
  2. Multiple variants in affected germline
  3. Overlap with highly conserved region

Joe Giacalone Mark Valentine
28




Mark Valentine
29
Exome variant server overlay
Drew Hughes
30
  • All looking at known ancestral polymorphisms and
    the incidence of acute leukemia.
  • None involve sequencing to demonstrate novel/rare
    variants in the same genes.

31
Overexpressed genes
  1. ATM
  2. CDKN1A
  3. CYP1A1
  4. CYP3A5
  5. IKZF1
  6. MDM2
  7. MLL
  8. MTHFR
  9. NAT2
  10. NQO1
  11. PAX5
  12. PTPN11
  13. TCF3
  14. TPMT

32
Overexpressed genes
  1. ATM
  2. CDKN1A
  3. CYP1A1
  4. CYP3A5
  5. IKZF1
  6. MDM2
  7. MLL
  8. MTHFR
  9. NAT2
  10. NQO1
  11. PAX5
  12. PTPN11
  13. TCF3
  14. TPMT

6 of 14 overexpressed genes (43) are involved in
drug metabolism.
33
Additional gene expression profiles
  • Similar expression differences in 18 additional
    genes (5 overexpressed CYPs).
  • All genes possess 1 novel coding variant in
    P9906 patients.
  • No clear connection between genetic variation and
    gene expression.

Drew Hughes
34
Implications / Conclusions
  • Overexpression of specific genes involved in
    metabolism of anti-leukemia agents identifies a
    subgroup of children with inferior EFS.
  • Private sequence variation in drug/energy
    metabolism genes is not coupled to expression
    profiles, but may predispose to leukemia or
    modulate therapeutic response through defective
    metabolism.
  • Pathogenesis vs. pharmacogenomics?
  • Therapeutic implications
  • Can look for these genomic signatures at
    diagnosis existing precedent
  • Dose modification or direct to bone marrow
    transplant

35
Future work
  • Validation and identification of individual
    profiles.
  • Delve more into the underexpressed genes as well.
  • Analyze sequencing results of 700 additional
    drug/energy metabolism genes.
  • Functional iPSC-based assays from patient
    fibroblasts.
  • Introduction into immune-deficient mice for
    functional study.

36
Acknowledgements Funding
  • Wash U
  • Bob Hayashi
  • Alan Schwartz
  • Rob Mitra
  • F. Sessions Cole
  • COG
  • Julie Ross
  • Logan Spector
  • Mignon Loh
  • Rick Harvey
  • Druley Lab
  • Nick Sanchez
  • Mark Valentine
  • Joe Giacalone
  • Drew Hughes
  • Andrew Young

1K08CA140720-01A1
Eli Seth Matthews Leukemia Foundation
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