Lineage-specific trisomy 21 in a neonate with resolving transient myeloproliferative syndrome

Risk factors for early death in transient myeloproliferative disorder without phenotypic features of Down syndrome: a case report and literature review

Not only in newborns with Down syndrome, but newborns without phenotypic features of Down syndrome also develop transient myeloproliferative disorder (TMD). In these cases, trisomy 21 and related chromosomal abnormalities are either constitutionally mosaic or limited to blood cells. Risk factors for early death of these patients are unknown so far. We here report a fatal case of TMD without phenotypic features of Down syndrome and review literature to identify risk factors associated with early death. Not only are gestational age and white blood cell count risk factors for early death in TMD with Down syndrome, but they also appear to be risk factors in TMD without Down syndrome.

Transient myeloproliferative disorder associated with trisomy 21

Transient myeloproliferative disorder (TMD) is a spontaneously resolving condition affecting infants born with trisomy 21 syndrome. Although TMD is rather rare among infants with trisomy 21, its ramifications can become severe enough that neonatal nurses should be aware of the condition, its manifestations, and its management. The spectrum of TMD presentation ranges from subtle blastemia in an otherwise healthy infant to severe, life-threatening expression of the disease. TMD may be a precursor to congenital leukemia—thus, the importance of nurses’ becoming aware of this condition. This article addresses the pathology of TMD, case reports in the literature, potential complications of the disorder, and nursing implications. A case study of an infant with dermatologic manifestations of TMD is presented, including history, differential diagnoses, treatment, and follow-up.

Tetrasomy 21 transient leukemia with a GATA1 mutation in a phenotypically normal trisomy 21 mosaic infant: case report and review of the literature

Infants with constitutional trisomy 21 are at increased risk of developing transient and acute megakaryoblastic leukemia (AMKL). Mutations in GATA1 have been identified in trisomy 21 patients with AMKL, and this lesion is thought to be an initial event by virtue of its presence during transient leukemia. Transient leukemia is also observed in phenotypically normal infants albeit much less commonly so. Almost all these infants are mosaic for trisomy 21, and the clinical course of transient leukemia recapitulates that observed in constitutional trisomy 21. We report a phenotypically normal infant with tetrasomy 21 transient leukemia, GATA1 mutation within exon 2, and trisomy 21 mosaicism restricted to the hematopoietic tissue. Two years after diagnosis, low levels of trisomy 21 persisted in the peripheral blood, which resolved 2.5 years after diagnosis. The GATA1 mutation was not detected at last follow-up. The literature review identified 32 phenotypically normal infants with transient leukemia. Ninety-one percent (29 of 32) were observed and three received chemotherapy at diagnosis of transient leukemia. Nineteen percent (6 of 32) developed acute leukemia, and four continued in remission (two died). Transient leukemia in trisomy 21 mosaicism recapitulates the condition observed in constitutional trisomy 21 at the biological and clinical levels. Infants should be followed for the development of acute leukemia.

Transient neonatal myeloproliferative disorder without Down syndrome and detection of GATA1 mutation

Transient myeloproliferative disorder is a form of self-limited leukemia that occurs almost exclusively in neonates with Down syndrome. The authors report an unusual case of a newborn without constitutional trisomy 21 who developed undifferentiated leukemia and subsequently achieved clinical and molecular remission without chemotherapy. Cytogenetics and molecular analysis have shown trisomy 21 and GATA1 mutation restricted to leukemic cells. G-to-T transversion was detected, which is predicted to result in a premature stop codon (c.119G>T; pGlu67X) in diagnosis samples. These findings emphasize that there must be a powerful interaction between GATA1 and trisomy 21 in leukemogenesis process.

Using fluorescence-activated cell sorting followed by fluorescence in situ hybridization to study lineage relationships: the 8;21 translocation is present in neutrophils but not monocytes in a patient with severe congenital neutropenia and a granulocyte colony-stimulating factor-responsive clonal abnormality

Severe congenital neutropenia (Kostmann syndrome) is a disorder that presents in the neonatal period, but predisposes to leukemia later in life. This report describes a 4-y-old female with a history of severe congenital neutropenia, who developed a clonal abnormality associated with the translocation (7;21;8) (q32;q22;q22) (AML-1/ETO). She had circulating peripheral blasts and bone marrow blast counts as high as 64% when she received recombinant granulocyte colony-stimulating factor (rG-CSF). Her marrow blasts decreased to 4-20% when rG-CSF was discontinued. Fluorescence in situ hybridization analysis was performed on bone marrow cell populations sorted by flow cytometry to determine which cell populations had the AML-1/ETO translocation. The translocation was found in mature neutrophils and blasts, but not in monocytes, lymphocytes or stem cells.

CONCLUSION

These findings suggest that the translocation occurred in a neutrophil progenitor, past the point in ontogeny where monocytes and neutrophils separate. The techniques described may be useful in understanding lineage relationships and leukemogenesis in other clonal abnormalities associated with myelodysplasia and leukemia.