Identification of tipifarnib sensitivity biomarkers in T-cell acute lymphoblastic leukemia and T-cell lymphoma.

Patients diagnosed with T-cell leukemias and T-cell lymphomas (TCLs) still have a poor prognosis and an inadequate response to current therapies, highlighting the need for targeted treatments. We have analyzed the potential therapeutic value of the farnesyltransferase inhibitor, tipifarnib, in 25 TCL cell lines through the identification of genomic and/or immunohistochemical markers of tipifarnib sensitivity. More than half of the cell lines (60%) were considered to be sensitive. Tipifarnib reduced cell viability in these T-cell leukemia and TCL cell lines, induced apoptosis and modified the cell cycle. A mutational study showed TP53, NOTCH1 and DNMT3 to be mutated in 84.6%, 69.2% and 30.0% of sensitive cell lines, and in 62.5%, 0% and 0% of resistant cell lines, respectively. An immunohistochemistry study showed that p-ERK and RelB were associated as potential biomarkers of tipifarnib sensitivity and resistance, respectively. Data from RNA-seq show that tipifarnib at IC50 after 72 h downregulated a great variety of pathways, including those controlling cell cycle, metabolism, and ribosomal and mitochondrial activity. This study establishes tipifarnib as a potential therapeutic option in T-cell leukemia and TCL. The mutational state of NOTCH1, p-ERK and RelB could serve as potential biomarkers of tipifarnib sensitivity and resistance.

A single nucleotide deletion resulting in a frameshift in exon 4 of TAB2 is associated with a polyvalular syndrome.

OBJECTIVE: Polyvalvularmyxomatous degeneration is a rare clinical condition. A 51-year-old male patient presented at our centre with all four heart valves with myxomatous degeneration and severe mitral and aortic regurgitation due to leaflet prolapse. The patient referred five further family members with valvular heart disease at different stages of presentation. The aim of this study was to investigate the genetic basis of this familial polyvalvularmyxomatous degeneration which was associated with mild dysmorphic facial anomalies and short stature. DESIGN: A detailed family history was recorded. Nine members of the family, affected or not by valvular heart disease, were studied clinically, echocardiographically and by detailed genetic analyses. RESULTS: Six of the nine family members had echocardiographic features of different degrees of degenerative heart valve disease. In addition, the affected subjects shared similar mild dysmorphic facial anomalies and short stature. Exome sequencing identified a rare heterozygous single nucleotide deletion in the TAB2 gene in all affected family members, which was absent in the unaffected members. CONCLUSIONS: A variant in the TAB2 gene is proposed as the cause of syndromic congenital heart disease, displaying congenital myxomatous degenerative heart valve disease, mild dysmorphic fascial anomalies and short stature in this family.

Tissue factor-enriched vesicles are taken up by platelets and induce platelet aggregation in the presence of factor VIIa.

We investigated the interactions of vesicles containing human tissue factor (TF) with platelets and evaluated responses induced by rFVIIa using standard aggregometry, ultrastructural and flow-cytometry techniques. Washed platelets were exposed to a preparation of placental human TF (pTF) or to a relipidated formulation of recombinant human TF (rTF). Under stirring conditions, pTF induced reversible aggregation with platelets returning to their resting state after 5 minutes. This reversible response to pTF was partially inhibited by antibodies against CD62-P, but not by antithrombin agents, and was not observed with rTF. Sequential ultrastructural studies revealed uptake of both TF preparations by platelets involving traffic of vesicles through channels of the open canalicular system (OCS). Immunocytochemical studies on cryosections identified TF in the OCS, and occasionally in the alpha-granules of the platelets. These processes were faster with pTF than with rTF, but both TF preparations accumulated in platelets at the end of incubation periods. Flow cytometry studies revealed the presence of other cellular antigens (CD62-P, CD14 and CD45) associated to the pTF. Addition of rFVIIa to washed platelets exposed to pTF or rTF, caused a thrombin dependent irreversible platelet aggregation. Our studies demonstrate that platelets possess mechanisms to capture and incorporate TF-rich vesicles. These processes are accelerated by the presence of other cellular antigens in the vesicles. Our findings may explain the hemostatic action of rFVIIa in severely hemodiluted patients, but are also relevant for the understanding of potential implications of TF-associated to platelets in the propagation of thrombus.

G-CSF increases the expression of VCAM-1 on stromal cells promoting the adhesion of CD34+ hematopoietic cells: studies under flow conditions.

OBJECTIVE AND METHODS: The knowledge of the mechanisms underlying the adhesive processes that lead to homing and/or mobilization of hematopoietic progenitor cells, and the influence of blood rheology, is still limited. We analyzed the impact of flow conditions on the adhesion of CD34+ peripheral blood progenitor cell (PBPC) to the adhesive proteins fibronectin, laminin, and collagen, and to stromal cells. RESULTS: Under static conditions, all the adhesive substrata assayed promoted adhesion of CD34+ PBPC, being higher on the stromal cells. Under flow conditions, adhesion of CD34+ PBPC was remarkable on stromal cells while insignificant onto the purified proteins. Exposure of stromal cell monolayers to granulocyte colony-stimulating factor (G-CSF) further enhanced PBPC adhesion. This effect correlated with the activation of p38 MAPK and with an increase in the expression of VCAM-1 on stromal cells exposed to G-CSF. In inhibitory assays, both an antibody to the G-CSFR and a specific inhibitor of the p38 MAPK blocked the effects induced by the cytokine. CONCLUSION: Our results provide direct evidence that in stromal cells G-CSF activates the signaling protein p38 MAPK, inducing expression of the adhesion receptor VCAM-1. This mechanism seems to promote adhesion of CD34+ cells on stromal cells and could play a potential role in homing events.

TRAP induces more intense tyrosine phosphorylation than thrombin with differential ultrastructural features.

We have analyzed modifications on platelet ultrastructural morphology, cytoskeletal assembly, and tyrosine phosphorylation developing in platelets activated by both thrombin and the thrombin receptor-activating peptide (TRAP). Washed platelets exposed to various concentrations of thrombin or TRAP, for different periods, were: fixed and examined by electron microscopy, or lysed and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Under similar activating conditions, thrombin and TRAP induced different sequences of activation causing distinctive morphological and biochemical changes. Platelets exposed to thrombin showed centralized organelles encircled by constricted microtubule coils and granules secreting their contents through narrow channels of the open canalicular system. In contrast, activation by TRAP induced swelling of the open canalicular system with organelles remaining randomly dispersed and microtubules peripherally distributed. Compared to thrombin activation, TRAP induced higher rates of actin polymerization; increased association of actin-binding protein, myosin, and alpha-actinin; and higher association of tyrosine-phosphorylated proteins with the insoluble cytoskeletal fraction. Secretion of intragranule substances, measured as expression of P-selectin and lysosomal integral membrane protein at the surface level, were similar for both agonists at equivalent concentrations. Our biochemical observations indicate that TRAP causes more intense changes in signaling through tyrosine phosphorylation of proteins associated with the cytoskeletal fraction than thrombin. However, as derived from ultrastructural observations, TRAP seems to be less efficient in triggering cytoskeletal assembly and internal contraction in an organized manner in contrast with the natural protease.