Abstract
Childhood leukemias are heterogeneous diseases with widely differing incident rates worldwide. As circulating tumors, childhood acute leukemias are uniquely accessible, and their natural history has been described in greater detail than for solid tumors. For several decades, it has been apparent that most cases of childhood acute lymphoblastic leukemia (ALL) and acute myeloid leukemia (AML) initiate in utero. Circumstantial evidence in support of this contention includes the young age of onset and high rate of concordance among identical twins. “Backtracking” of leukemic somatic mutations, particularly gene translocations, to cord blood and dried blood spots collected during the perinatal period has provided molecular proof of prenatal leukemogenesis. Detection of a patient's leukemia translocation in easily accessible birth samples, such as dried blood spots, is straightforward with the knowledge of their idiosyncratic breakpoints. However, to translate these findings into population-based screening and leukemia prevention requires novel methods able to detect translocations at all possible breakpoints when present in a low frequency of cells. Several studies have attempted to screen for leukemic translocations, mainly the common ETV6-RUNX1 translocation, in cord blood samples from healthy children. Most studies have reported finding translocations in healthy children, but estimates of prevalence have varied widely and greatly exceed the incidence of leukemia, leading to concerns that technical artifact or contamination produced an artificially inflated estimate of translocation prevalence at birth. New generation techniques that capture the presence of these translocations at birth have the potential to vastly increase our understanding of the epidemiology of acute leukemias. For instance, if leukemic translocations are present at birth in a far higher proportion of children than eventually develop acute leukemia, what are the exposures and somatic molecular events that lead to disease? And could children with translocations present at birth be targeted for prevention of disease? These questions must be answered before large-scale newborn screening for leukemia can occur as a public health initiative. Here, we review the literature regarding backtracking of acute leukemias and the prevalence of leukemic translocations at birth. We further suggest an agenda for epidemiologic research using new tools for population screening of leukemic translocations.
Highlights
Leukemia is the most common malignancy diagnosed in childhood
Childhood forms of Acute lymphoblastic leukemia (ALL) and acute myeloid leukemia (AML) are distinct from those occurring in adulthood with respect to molecular features, demographic characteristics, risk factors, leukemogenic susceptibility associated with certain exposures, and prognosis
Advances in understanding of immunology and molecular/genetic features of the childhood acute leukemias along with laboratory improvements in immunophenotyping and cytogenetic characterization have led to the recognition of molecularly defined subtypes of ALL and AML, targeted therapeutics, and recognition of distinct prognostic groups [4]
Summary
Leukemia is the most common malignancy diagnosed in childhood. Acute lymphoblastic leukemia (ALL) comprises approximately 80% of all leukemia diagnoses among children age 0–19 years, and acute myeloid leukemia (AML) represents ∼15–20%. Backtracking Studies The observations from twin studies led to a series of “backtracking” studies providing further support for an in utero origin for preleukemic clones In these studies, leukemia cells collected at the time of diagnosis were evaluated for cytogenetic and molecular abnormalities, including the exact patient-specific sequence of any gene translocations specific to the leukemia. Leukemia cells collected at the time of diagnosis were evaluated for cytogenetic and molecular abnormalities, including the exact patient-specific sequence of any gene translocations specific to the leukemia Using this information, researchers examined each patient’s DNA from dried blood spots (DBS) collected at birth for the purposes of newborn screening. Nr, not reported; FISH, fluorescence in situ hybridization. *Among sorted CD19+ cells
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