Zohar Yagil

Semaphorin 3A and neurotrophins: a balance between apoptosis and survival signaling in embryonic DRG neurons

Large numbers of neurons are eliminated by apoptosis during nervous system development. For instance, in the mouse dorsal root ganglion (DRG), the highest incidence of cell death occurs between embryonic days 12 and 14 (E12–E14). While the cause of cell death and its biological significance in the nervous system is not entirely understood, it is generally believed that limiting quantities of neurotrophins are responsible for neuronal death. Between E12 and E14, developing DRG neurons pass through tissues expressing high levels of axonal guidance molecules such as Semaphorin 3A (Sema3A) while navigating to their targets. Here, we demonstrate that Sema3A acts as a death‐inducing molecule in neurotrophin‐3 (NT‐3)‐, brain‐derived neurotrophic factor (BDNF)‐ and nerve growth factor (NGF)‐dependent E12 and E13 cultured DRG neurons. We show that Sema3A most probably induces cell death through activation of the c‐Jun N‐terminal kinase (JNK)/c‐Jun signaling pathway, and that this cell death is blocked by a moderate increase in NGF concentration. Interestingly, increasing concentrations of other neurotrophic factors, such as NT‐3 or BDNF, do not elicit similar effects. Our data suggest that the number of DRG neurons is determined by a fine balance between neurotrophins and Semaphorin 3A, and not only by neurotrophin levels.

Mitochondrial STAT3 plays a major role in IgE-antigen–mediated mast cell exocytosis

BACKGROUND The involvement of mitochondrial oxidative phosphorylation (OXPHOS) in mast cell exocytosis was recently suggested by the finding that mitochondria translocate to exocytosis sites upon mast cell activation. In parallel, mitochondrial signal transducer and activator of transcription 3 (STAT3) was found to be involved in ATP production. However, the regulation of mitochondrial STAT3 function and its connection to mast cell exocytosis is unknown. OBJECTIVE We sought to explore the role played by mitochondrial STAT3 in mast cell exocytosis. METHODS Experiments were performed in vitro with human and mouse mast cells and rat basophilic leukemia (RBL) cells and in vivo in mice. OXPHOS activity was measured after immunologic activation. The expression of STAT3, extracellular signal-regulated kinase 1/2, and protein inhibitor of activated STAT3 in the mitochondria during mast cell activation was determined, as was the effect of STAT3 inhibition on OXPHOS activity and mast cell function. RESULTS Here we show that mitochondrial STAT3 is essential for immunologically mediated degranulation of human and mouse mast cells and RBL cells. Additionally, in IgE-antigen-activated RBL cells, mitochondrial STAT3 was phosphorylated on serine 727 in an extracellular signal-regulated kinase 1/2-dependent manner, which was followed by induction of OXPHOS activity. Furthermore, the endogenous inhibitor of STAT3, protein inhibitor of activated STAT3, was found to inhibit OXPHOS activity in the mitochondria, resulting in inhibition of mast cell degranulation. Moreover, mice injected with Stattic, a STAT3 inhibitor, had a significant decrease in histamine secretion. CONCLUSION These results provide the first evidence of a regulatory role for mitochondrial STAT3 in mast cell functions, and therefore mitochondrial STAT3 could serve as a new target for the manipulation of allergic diseases.

A Specific Epitope of Protein Inhibitor of Activated STAT3 Is Responsible for the Induction of Apoptosis in Rat Transformed Mast Cells

Protein inhibitor of activated STAT3 (PIAS3) functions in vivo as a key molecule in suppressing the transcriptional activity of both microphthalmia transcription factor (MITF) and STAT3, two transcription factors that play a major role in the development, phenotypic expression, and survival of mast cells and melanocytes. In the present study we have investigated the role played by PIAS3 in the regulation of cell cycle in mast cells and melanocytes. We have characterized the biological role of a 23-aa domain derived from PIAS3 that induces apoptosis in these cells by inhibiting the transcriptional activity of both MITF and STAT3. This PIAS3 inhibitor peptide could serve as the beginning of an in depth study for the development of peptide inhibitors for MITF and STAT3.

Semaphorin3A accelerates neuronal polarity in vitro and in its absence the orientation of DRG neuronal polarity in vivo is distorted

Axon guidance cues are critical for neuronal circuitry formation. Guidance molecules may repel or attract axons directly by effecting growth cone motility, or by impinging on neuronal polarity. In Semaphorin3A null mice, many axonal errors are detected, most prominently in DRG neurons. It has been generally assumed the repellent properties of Semaphorin3A are the cause of these erroneous axonal projections. Here we show that, in semaphorin3A-null mice, the initial trajectory of neurons in the DRG is abnormal, suggesting that Semaphorin3A may instruct neuronal polarity. In corroboration, in vitro Semaphorin3A dramatically increases neuronal polarization, as indicated by GSK3beta and Rac1 sub-cellular localization in DRG neurons. Polarization effects of Semaphorin3A are regulated by activated MAPK, as indicated by p-MAPK 42/44 polarization and the need for its activity for Rac1 and GSK3beta polarization. Taken together, our findings suggest that Semaphorin3A plays a role in the formation of neuronal polarity, in addition to its classic repellent role.

Transcription factor E3, a major regulator of mast cell–mediated allergic response

BACKGROUND Microphthalmia transcription factor, an MiT transcription family member closely related to transcription factor E3 (TFE3), is essential for mast cell development and survival. TFE3 was previously reported to play a role in the functions of B and T cells; however, its role in mast cells has not yet been explored. OBJECTIVE We sought to explore the role played by TFE3 in mast cell function. METHODS Mast cell numbers were evaluated by using toluidine blue staining. FACS analysis was used to determine percentages of Kit and FcεRI double-positive cells in the peritoneum of wild-type (WT) and TFE3 knockout (TFE3(-/-)) mice. Cytokine and inflammatory mediator secretion were measured in immunologically activated cultured mast cells derived from either knockout or WT mice. In vivo plasma histamine levels were measured after immunologic triggering of these mice. RESULTS No significant differences in mast cell numbers between WT and TFE3(-/-) mice were observed in the peritoneum, lung, and skin. However, TFE3(-/-) mice showed a marked decrease in the number of Kit(+) and FcεRI(+) peritoneal and cultured mast cells. Surface expression levels of FcεRI in TFE3(-/-) peritoneal mast cells was significantly lower than in control cells. Cultured mast cells derived from TFE3(-/-) mice showed a marked decrease in degranulation and mediator secretion. In vivo experiments showed that the level of plasma histamine in TFE3(-/-) mice after an allergic trigger was substantially less than that seen in WT mice. CONCLUSION TFE3 is a novel regulator of mast cell functions and as such could emerge as a new target for the manipulation of allergic diseases.

Importin Beta Plays an Essential Role in the Regulation of the LysRS-Ap 4 A Pathway in Immunologically Activated Mast Cells

ABSTRACT We recently reported that diadenosine tetraphosphate hydrolase (Ap4A hydrolase) plays a critical role in gene expression via regulation of intracellular Ap4A levels. This enzyme serves as a component of our newly described lysyl tRNA synthetase (LysRS)-Ap4A biochemical pathway that is triggered upon immunological challenge. Here we explored the mechanism of this enzymes translocation into the nucleus and found its immunologically dependent association with importin beta. Silencing of importin beta prevented Ap4A hydrolase nuclear translocation and affected the local concentration of Ap4A, which led to an increase in microphthalmia transcription factor (MITF) transcriptional activity. Furthermore, immunological activation of mast cells resulted in dephosphorylation of Ap4A hydrolase, which changed the hydrolytic activity of the enzyme.