👤 Valentina Pierini

Tofacitinib, a Janus kinase inhibitor, has been associated with increased cardiovascular (CV) risk in rheumatoid arthritis (RA). This study evaluated tofacitinib's effects on lipid parameters and the impact of prior biological agents' therapy in RA patients. Thirty female RA patients starting tofacitinib were assessed at baseline and after 3 months. Clinical assessments, health assessment questionnaire (HAQ), disease activity score 28 (DAS28), inflammatory markers, lipid profile, oxidized low-density lipoprotein (LDL), activities of paraoxonase 1 (PON 1), lipoprotein-associated phospholipase A After 3 months, HAQ and DAS28 scores improved significantly. Total cholesterol (TC), HDL-C, non-HDL-C, and HDL capacity to acquire free cholesterol from TGRL increased, while enzyme activities and cholesterol efflux capacity remained unchanged. At baseline, patients with prior biological therapy (n = 19) had lower triglycerides, TC, non-HDL-C, and apolipoprotein (apo) B compared to biologic-naïve patients (n = 11). This group exhibited no lipid changes after tofacitinib, whereas biologic-naïve patients showed atherogenic increases in TC, LDL-C, non-HDL-C, apo B, Lp-PLA Tofacitinib improved disease activity and functional status in RA patients with minimal lipid changes. Patients previously treated with biological agents experienced no significant lipid alterations, while biologic-naïve patients showed atherogenic lipid changes and increased PON 1 activity. Prior biologic therapy may confer a more favorable CV profile before and after tofacitinib treatment. Show less

The MLLT10 gene, located at 10p13, is a known partner of MLL and PICALM in specific leukemic fusions generated from recurrent 11q23 and 11q14 chromosome translocations. Deep sequencing recently identified NAP1L1/12q21 as another MLLT10 partner in T-cell acute lymphoblastic leukemia (T-ALL). In pediatric T-ALL, we have identified 2 RNA processing genes, that is, HNRNPH1/5q35 and DDX3X/Xp11.3 as new MLLT10 fusion partners. Gene expression profile signatures of the HNRNPH1- and DDX3X-MLLT10 fusions placed them in the HOXA subgroup. Remarkably, they were highly similar only to PICALM-MLLT10-positive cases. The present study showed MLLT10 promiscuity in pediatric T-ALL and identified a specific MLLT10 signature within the HOXA subgroup. Show less

Patients with various hematologic malignancies, including acute lymphoblastic leukemia (ALL), acute myeloblastic leukemia (AML), diffuse histiocytic lymphoma, and granulocytic sarcoma, have sometimes been shown to carry the PICALM-MLLT10 fusion gene (alias CALM-AF10) by various cytogenetic methodologies. Cases with the PICALM-MLLT10 fusion gene can involve a diagnostic dilemma for the following reasons: (1) the fusion gene occurs very rarely, (2) the cases do not have a distinct myeloid or lymphoid morphology and cells often appear immature, (3) cases usually have a mixed T-cell and myeloid phenotype, and (4) cases often have a mixed clinical presentation (e.g., mediastinal mass in a patient with AML). A 27-year-old woman was diagnosed with AML with the PICALM-MLLT10 fusion gene. The patient was treated on an AML regimen and achieved a complete remission. Although the reported treatment of these patients varies greatly, outcome remains very poor in the vast majority. Furthermore, central nervous system involvement at diagnosis and relapse are reported in pediatric populations. Routine acute leukemia fluorescence in situ hybridization panels do not include a probe for the PICALM-MLLT10 fusion gene, and therefore diagnosis can be made only when karyotyping is available; that delay can result in initial misdiagnosis and mistreatment. The case report and literature review here (including discussion of the poor prognosis and of management, including CNS prophylaxis) are intended to raise awareness and to inform about PICALM-MLLT10 in acute leukemia. Show less