Bilateral adrenal hemorrhage and severe anemia in a neonate.

Summary: Neonatal adrenal hemorrhage (NAH) occurs in up to 3% of infants and is the most common adrenal mass in newborns. The most common presentation of NAH is an asymptomatic palpable flank mass which resolves over time without intervention. In rare cases, NAH can present as hemorrhage, shock, or adrenal insufficiency. This case describes a preterm infant born with severe anemia in the setting of bilateral adrenal hemorrhages with resulting adrenal insufficiency. The infant was successfully treated with blood transfusions and steroids. This is a unique presentation of NAH as it was bilateral, presented with severe anemia, and resulted in prolonged adrenal insufficiency. Learning points: Consider adrenal hemorrhage for cases of severe anemia at birth. Adrenal insufficiency is a rare complication of adrenal hemorrhage. Adrenal recovery can take months, if not years.

Mitoxantrone in combination with an inhibitor of DNA-dependent protein kinase: a potential therapy for high risk B-cell chronic lymphocytic leukaemia.

Defects in the DNA damage response pathway [e.g. del(17p)] are associated with drug-resistant B-cell chronic lymphocytic leukaemia (CLL). We previously demonstrated that over-expression of DNA-dependent protein kinase (DNA-PK) correlates with chemo-resistance and that inhibition of DNA-PK sensitizes CLL cells to chemotherapeutics. Here, we investigated expression of DNA-PK and other proteins that impact on drug resistance, and evaluated the effects of a DNA-PK inhibitor (NU7441) on mitoxantrone-induced cytotoxicity in CLL cells. NU7441 sensitized cells from 42/49 CLL samples to mitoxantrone, with sensitization ranging from 2- to 200-fold Co-culture of CLL cells in conditioned stromal medium increased chemoresistance but did not reduce sensitization by NU7441. Mitoxantrone treatment induced γH2AX foci and NU7441 increased their longevity (24 h). NU7441 prevented mitoxantrone-induced autophosphorylation of the DNA-PK catalytic subunit (DNA-PKcs) at Ser 2056, confirming that DNA-PK participates in repair of mitoxantrone-induced DNA damage. del(17p) cases were more resistant to mitoxantrone than del(13q) cases, but were resensitized (7-16 fold) by co-incubation with NU7441. Expression of DNA-PKcs, Ku80, P-glycoprotein and topoisomerase IIß were significantly higher in del(17p) cases. PRKDC mRNA levels correlated with DNA-PKcs protein expression, which predicted shorter survival. These data confirm the potential of DNA-PK as a therapeutic target in poor prognosis CLL.

Duplication 6q24: More Than Just Diabetes.

Chromosome 6q24-related transient neonatal diabetes mellitus is characterized by intrauterine growth restriction and low birth weight, with neonatal hyperglycemia resolving by 18 months and an increased risk for type 2 diabetes in adulthood. Molecularly, it is caused by overexpression of the 6q24 imprinted chromosomal region due to a duplication, uniparental disomy, or abnormal methylation. Conventional testing for this condition analyzes methylation patterns at the 6q24 locus but does not evaluate for the presence of other surrounding chromosomal abnormalities. We report a female with a history of neonatal hyperglycemia due to a paternally inherited duplication at chromosomal location 6q24. She subsequently presented to the pediatric genetics clinic at 15 months of age with developmental delay and abnormal balance. Microarray analysis identified a larger 14 Mb chromosomal duplication from 6q24 to 6q25.2, consistent with a diagnosis of duplication 6q syndrome. This case highlights the clinical importance of pursuing further genetic evaluation in patients diagnosed with chromosome 6q24-related neonatal hyperglycemia via targeted methylation-specific multiplex ligation-dependent probe amplification analysis identifying a duplication in this region. Early identification and intervention can improve developmental outcomes for patients with larger chromosome 6q duplications.