Abstract

TET2 mutations (TET2MT) occur in up to 40% of myeloid neoplasms and increase linearly with age. That these lesions are founding hits can be concluded from clonal architecture and from the presence of subclinical TET2MT clones in healthy individuals at risk for subsequent MDS. Though TET2MT are heterogeneous, most disrupt TET2 catalytic domain dioxygenase activity; these widespread LOF mutations implicate TET2 as a bona fide tumor-suppressor gene (TSG). As downstream targets have not been identified as being associated with TET2MT, the precise mechanisms of TET2MT in leukemogenesis remains unclear. We studied whether TET2MT predispose cells to acquiring additional oncogenic mutations through faulty DNA repair to produce clonally acquired mutator phenotypes.

In WES analyses of 435 myeloid neoplasia patient (pt) samples, we identified 95 with somatic TET2MT enriched vs controls in the ExAC database, and used 6 bioinformatics tools to predict the effect on protein function based on algorithms incorporating sequence homology, amino acid properties, sequence context, and similarity to Mendelian diseases. Most pts (63) were predicted to have damaging TET2MT in 3+ out of six of these tools.

To validate TET2MT clinical relevance, we established an in-vitro 2D-UPLC-MS/MS assay to assess levels of the TET2-dependent DNA oxidation products 5hmC, 5fC, and 5CaC. While TET2 +/- knockout mouse samples had nonsignificant differences in 5hmC (1.2-fold lower levels vs TET2WT, p=.23) and 5fC (1.4-fold increase vs TET2WT, p=.07), they had significantly lower 5CaC (2.4-fold decrease vs TET2WT, p<.0001). TET2 -/- mouse samples had significantly lower 5hmC (1.6-fold reduction vs TET2WT, p<.0001), 5fC (1.3-fold reduction vs TET2WT, p=.011), and 5CaC (2.4-fold reduction vs TET2 WT, p<.0001). Human MOLM-13 TET2 -knockdown (TET2 kd) cells also had 1.6-fold lower levels of 5hmC (p<.0001). Reassuringly, eight samples from TET2MT patients also had lower 5hmC (5/8 samples, peak 2.9-fold reduction vs TET2WT, p<.0001), 5fC (6/8 samples, peak 8.2-fold reduction vs TET2WT, p<.0001), and 5CaC (5/8 samples, peak 2.6-fold reduction vs TET2 WT, p<.0001), and all 8/8 TET2MT pt samples had significant declines in at least one of the three TET2-dependent oxidation vs TET2WT samples.

To test whether TET2MT predisposed cells to acquiring additional genomic mutations, we measured the total number of single nucleotide variants (SNV) in the entire exome in each pt sample, excluded pts with mutations in known DNA repair proteins, and compared the median WES SNV of TET2MT pts to TET2WT pts. Consistent with our theory, TET2MT pts had a 1.5-fold increase in median WES SNV (p<.0001), particularly at 5hmC sites. Pts with a TET 2MT variant allele frequency>50% had a 2.1-fold increase in median WES SNV (p=.03), consistent with a gene-dose effect.

TET2 -/- knockout mice had 1.4-fold increased mutagenicity at TET2-dependent active demethylation sites, in a manner suggestive of defective mismatch repair (MMR). HeLa TET2 kd cells also had a 24-fold increase in spontaneous mutations, reversed with TET2 cDNA knock-in. MMR gene expression (MSH2, MSH3, MSH6, and MLH1) was equivalent among 20 TET2MT MDS pts, 71 TET2WT MDS pts, and 17 controls, indicating MMR downregulation was not responsible for the hypermutagenicity. Five pts with TET2MT were microsatellite-stable (MSS) at 5 TET2-independent poly-dA microsatellite loci, suggesting that hypermutagenicity was not driven by global MMR dysfunction and may occur only at CpG-containing microsatellites.

By overexpressing Flag/V5-tagged TET2 in mouse-MEL cells and subjecting them to protein affinity purification, we identified MSH6 as a novel TET2 binding partner. TET2:MSH6 interactions were validated in co-immunofluorescence experiments in MEL and MOLM-13 cells, and TET2kd altered MSH6 nuclear co-localization. MOLM-13 TET2kd increased PARP inhibitor sensitivity by almost 3-fold, suggesting that TET2kd renders cells vulnerable to perturbations in DNA repair pathways.

In sum, we uncovered novel connections among TET2, MSH6, epigenetic modifications, and genomic instability. Given that MSH6 is known to preferentially bind 5hmC, TET2 may target MSH6 to TET2-dependent DNA loci. Genomic instability due to TET2 dysfunction may allow therapeutic targeting of DNA repair proteins in the subset of hematologic malignancy pts with TET2MT.

Disclosures

Greenberg: Oisin Biotechnologies: Consultancy; Acetylon Pharmaceuticals Inc.: Patents & Royalties: Treatment of Protein Degradation Disorders. Makishima: Yasuda Medical Foundation: Research Funding. Sekeres: Celgene: Membership on an entity's Board of Directors or advisory committees. Maciejewski: Alexion Pharmaceuticals, Inc.: Consultancy, Membership on an entity's Board of Directors or advisory committees, Other: Speaker Fees; Apellis Pharmaceuticals: Consultancy; Ra Pharma: Consultancy.

Author notes

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Asterisk with author names denotes non-ASH members.