Monoallelic germline variants in POT1 can lead to POT1-tumor predisposition (POT1-TPD), an autosomal dominant disorder leading to a spectrum of neoplasia, predominantly, melanoma, glioma, angiosarcoma and chronic lymphocytic leukemia (CLL). Recently, germline POT1 variants have been described to be associated with familial clonal hematopoiesis syndrome.The POT1 protein forms a part of shelterin complex, which has been implicated in DNA damage protection, telomere length regulation and chromosomal stability. The proposed mechanism of oncogenesis by POT1 variants is presumed to be secondary to increased telomere length causing genomic instability and cellular immortality. While POT1-TPD can cause CLL in adulthood, childhood leukemias have not been commonly observed. Here, we present a case of a previously healthy 12-year-old male diagnosed with Burkitt leukemia. He presented with leukocytosis and tumor lysis syndrome. Bone marrow evaluation revealed hypercellular marrow involved by Burkitt lymphoma, comprising over 90% marrow cellularity. Flow cytometry showed an abnormal lambda monotypic B-lymphoid population positive for CD10, CD19, CD20, CD22 and CD45. FISH studies demonstrated low-level MYC rearrangement (9%); negative for BCL2 and BCL6 rearrangement. EBV staining was negative. Acute leukemia NGS panel (63 genes) revealed a Tier 1 somatic variant in PHF6. RNA sequencing did not detect additional fusions. His chemotherapy course was complicated by significant toxicities including prolonged count recovery, severe peripheral neuropathy, neurotoxicity, kidney injury and several infectious complications. Given extensive family history of cancers on the maternal side including colorectal, duodenal, brain and skin cancers, a germline cancer predisposition NGS panel was sent from cultured skin fibroblast and identified two heterozygous pathogenic variants in MSH2 (c.942+3A>T) and MUTYH (c.1187G>A) and a heterozygous likely pathogenic variant in POT1 (c.233T>C). To delineate potential roles of these germline variants in oncogenesis, additional testing was performed. Immunohistochemical staining of bone marrow revealed intact nuclear expression of MLH1, PMS2, MSH2,and MSH6,suggesting microsatellite stability. Extended tumor profiling through whole exome sequencing did not identify additional somatic variants or copy loss of heterozygosity in MSH2, MUTYH and POT1 but additional somatic loss of function variants were seen in CCND3, CASP8, ARID1, and PTPRD.To assess potential functional consequences of the POT1 germline variant on DNA double-strand break (DSB) damage repair, the patient lymphocytes were exposed to 2 Gy ionizing radiation and mobilization and kinetics of DNA DSB repair was assessed at 1h and 24h post-irradiation (IR) using phosphorylation (p) of ATM, SMC1 and H2AX (gamma), and cell death and apoptosis was also assessed at 24h post-irradiation by flow cytometry. There was normal mobilization and repair of DNA DSBs in T, B and NK cells although there was a subset of CD19dim B cells that showed constitutive DNA DSBs at1h with partial repair at 24h. It is not evident that this defect can be attributed to the germline defects as they are also observed in several other clinical contexts, including post-chemotherapy. Telomere length assay from peripheral blood demonstrated telomere length at 50 th percentile in both lymphocytes and granulocytes. Children in families with adult-onset cancer predisposition syndromes may present with cancers but the potential contribution of these germline variants to these childhood cancers is unknown. Our molecular and functional studies on both germline and tumor tissues did not suggest direct contribution of these germline variants on lymphomagenesis, however there might be other mechanism of inactivation not identified from this study. This case highlights the complexities of understanding genetic susceptibility in childhood cancers. We propose a multifactorial oligogenic inheritance of cancer susceptibility in this patient through several mechanisms of genomic instability.