Severe Mucha-Habermann-Like Ulceronecrotic Skin Disease in T-Cell Acute Lymphoblastic Leukemia Responsive to Basiliximab and Stem Cell Transplant.

A 5-year-old girl with T-cell acute lymphoblastic leukemia (T-ALL) developed a progressive eruption of crusted papules and ulcerative plaques involving 80% of her body surface area with histopathology consistent with febrile ulceronecrotic Mucha-Habermann disease (FUMHD), although multiple specimens also contained clonal leukemic cells. Her skin disease was refractory to many classic treatments for FUMHD, including methotrexate, and became so severe that concern about superinfection prevented intensification of chemotherapy for her malignancy. The addition of basiliximab promoted gradual improvement of the skin, allowing for chemotherapy intensification and subsequent bone marrow transplantation, after which the eruption resolved completely. This report describes a severe case of FUMHD-like eruption associated with clonal leukemic cells that improved with basiliximab, suggesting anti-CD25 therapy as a novel treatment for ulceronecrotic skin disease in the setting of high interleukin-2 levels.

Myc, Oncogenic Protein Translation, and the Role of Polyamines.

Deregulated protein synthesis is a common feature of cancer cells, with many oncogenic signaling pathways directly augmenting protein translation to support the biomass needs of proliferating tissues. MYC's ability to drive oncogenesis is a consequence of its essential role as a governor linking cell cycle entry with the requisite increase in protein synthetic capacity, among other biomass needs. To date, direct pharmacologic inhibition of MYC has proven difficult, but targeting oncogenic signaling modules downstream of MYC, such as the protein synthetic machinery, may provide a viable therapeutic strategy. Polyamines are essential cations found in nearly all living organisms that have both direct and indirect roles in the control of protein synthesis. Polyamine metabolism is coordinately regulated by MYC to increase polyamines in proliferative tissues, and this is further augmented in the many cancer cells harboring hyperactivated MYC. In this review, we discuss MYC-driven regulation of polyamines and protein synthetic capacity as a key function of its oncogenic output, and how this dependency may be perturbed through direct pharmacologic targeting of components of the protein synthetic machinery, such as the polyamines themselves, the eukaryotic translation initiation factor 4F (eIF4F) complex, and the eukaryotic translation initiation factor 5A (eIF5A).