Neurotrophin p75 receptor (p75NTR) promotes endothelial cell apoptosis and inhibits angiogenesis: implications for diabetes-induced impaired neovascularization in ischemic limb muscles.

Diabetes impairs endothelial function and reparative neovascularization. The p75 receptor of neurotrophins (p75(NTR)), which is scarcely present in healthy endothelial cells (ECs), becomes strongly expressed by capillary ECs after induction of peripheral ischemia in type-1 diabetic mice. Here, we show that gene transfer-induced p75(NTR) expression impairs the survival, proliferation, migration, and adhesion capacities of cultured ECs and endothelial progenitor cells (EPCs) and inhibits angiogenesis in vitro. Moreover, intramuscular p75(NTR) gene delivery impairs neovascularization and blood flow recovery in a mouse model of limb ischemia. These disturbed functions are associated with suppression of signaling mechanisms implicated in EC survival and angiogenesis. In fact, p75(NTR) depresses the VEGF-A/Akt/eNOS/NO pathway and additionally reduces the mRNA levels of ITGB1 [beta (1) integrin], BIRC5 (survivin), PTTG1 (securin) and VEZF1. Diabetic mice, which typically show impaired postischemic muscular neovascularization and blood perfusion recovery, have these defects corrected by intramuscular gene transfer of a dominant negative mutant form of p75(NTR). Collectively, our data newly demonstrate the antiangiogenic action of p75(NTR) and open new avenues for the therapeutic use of p75(NTR) inhibition to combat diabetes-induced microvascular liabilities.

p38MAPK delta controls c-Myb degradation in response to stress.

The c-myb gene is the progenitor of the v-myb oncogene, which causes avian myelomonocytic leukemia. Dysregulated c-myb gene expression is linked to the development of myeloid leukemia in mice and is predictive of poor prognosis in human colorectal cancer. Among the variety of post-translational modifications controlling the c-Myb protein, phosphorylation was shown to affect the transactivation activity and the rate of protein degradation. In this work we show that phosphorylation of c-Myb in response to stress led to rapid protein degradation, which occurred via a proteasome-dependent pathway. The kinases principally involved in this response were p38MAPK delta and, to a lesser extent, p38MAPK gamma. To assess whether c-Myb degradation was driven by changes in the overall level of phosphorylation or rather by phosphorylation at specific sites we systematically mutated potential sites of phosphorylation fulfilling the consensus for recognition by MAPKs (Ser/Thr-Pro). Among the point mutants examined, residues located downstream to the transactivation domain appeared to be essential for c-Myb stability. Particularly, mutation of Thr(354), Thr(486), Ser(556) and Thr(572) to Alanine conferred resistance to stress-induced degradation. The implications of c-Myb downregulation during inflammatory responses are discussed.

Mismatch repair status and the response of human cells to cisplatin.

The emergence of resistance to cisplatin is a serious drawback of cancer therapy. To help elucidate the molecular basis of this resistance, we examined matched ovarian cancer cell lines that differ in their DNA mismatch repair (MMR) status and the response to cisplatin. Checkpoint activation by cisplatin was identical in both lines. However, sensitive cells delayed S-phase transition, arrested at G(2)/M and died by apoptosis. The G(2)/M block was characterized by selective disappearance of homologous recombination (HR) proteins, which likely resulted in incomplete repair of the cisplatin adducts. In contrast, resistant cells transiently arrested at G(2)/M, maintained constant levels of HR proteins and ultimately resumed cell cycle progression. The net contribution of MMR to the cisplatin response was examined using matched semi-isogenic (HCT116+/-chr3) or strictly isogenic (293T-Lalpha(-/+)) cell lines. Delayed transition through S-phase in response to cisplatin was also observed in the MMR-proficient HCT116+chr3 cells. Unlike in the ovarian cell lines, however, both HCT116+chr3 and HCT116 permanently arrested at G(2)/M with an intact complement of HR proteins and died by apoptosis. A similar G(2)/M arrest was observed in the strictly isogenic 293T-Lalpha(-/+) cells. This confirmed that although MMR undoubtedly contributes towards the cytotoxicity of cisplatin, it is only one of several pathways that modulate the cellular response to this drug. However, our data highlighted the importance of HR to cisplatin cytotoxicity and suggested that HR status might represent a novel prognostic marker and possibly also a therapeutic target, the inhibition of which would substantially sensitize cells to cisplatin chemotherapy.

Enhanced proliferative potential of hematopoietic cells expressing degradation-resistant c-Myb mutants.

The c-myb gene encodes a transcription factor required for proliferation, differentiation, and survival of hematopoietic cells. Expression of c-Myb is often increased in hematological malignancies, but the underlying mechanisms are poorly understood. We show here that c-Myb has a longer half-life (at least 2-fold) in BCR/ABL-expressing than in normal hematopoietic cells. Such enhanced stability was dependent on a phosphatidylinositol 3-kinase (PI-3K)/Akt/GSKIIIbeta pathway(s) as indicated by the suppression of c-Myb expression upon treatment with PI-3K inhibitors or co-expression with dominant negative Akt or constitutively active GSKIIIbeta. Moreover, inhibition of GSKIIIbeta by LiCl enhanced c-Myb expression in parental 32Dcl3 cells. Compared with wild type c-Myb, three mutants (delta(358-452), delta(389-418), and L389A/L396A c-Myb) of the leucine zipper domain had increased stability. However, only expression of delta(358-452) was not affected by inhibition of the PI-3K/Akt pathway and was not enhanced by a proteasome inhibitor, suggesting that leucine zipper-dependent and -independent mechanisms are involved in the regulation of c-Myb stability. Indeed, delta(389-418) carrying four lysine-to-alanine substitutions (delta(389-418) K387A/K428A/K442A/K445A) was as stable as delta(358-452) c-Myb. Compared with full-length c-Myb, constitutive expression of delta(358-452) and delta(389-418) c-Myb in Lin-Sca-1+ mouse marrow cells increased cytokine-dependent primary and secondary colony formation. In K562 cells, expression of delta(358-452), delta(389-418), and L389A/L396A c-Myb led to enhanced proliferation after STI571 treatment. Thus, enhanced stability of c-Myb by activation of PI-3K-dependent pathway(s) might contribute to the higher proliferative potential of BCR/ABL-expressing and, perhaps, other leukemic cells.