Ioannis Charalampopoulos

Neurosteroids as modulators of neurogenesis and neuronal survival.

Neurons and glia in the central nervous system express the necessary enzymes for the synthesis of neurosteroids that are produced in concentrations high enough to exert paracrine effects. Synthesis of brain neurosteroids declines with age, during stressful conditions (including major depression, chronic psychological stress), and in chronic inflammatory and neurodegenerative diseases. Recent reports associate the decrease of brain neurosteroids to neuronal dysfunction and degeneration. This review summarizes the recent findings on how the most studied neurosteroids (dehydroepiandrosterone, pregnenolone and their sulphate esters, progesterone and allopregnanolone) affect neuronal survival, neurite outgrowth and neurogenesis; furthermore, this review discusses potential applications of these neurosteroids in the therapeutic management of neurodegenerative conditions, including that of age-related brain atrophy.

Activation of the p75 Neurotrophin Receptor through Conformational Rearrangement of Disulphide-Linked Receptor Dimers

Ligand-mediated dimerization has emerged as a universal mechanism of growth factor receptor activation. Neurotrophins interact with dimers of the p75 neurotrophin receptor (p75(NTR)), but the mechanism of receptor activation has remained elusive. Here, we show that p75(NTR) forms disulphide-linked dimers independently of neurotrophin binding through the highly conserved Cys(257) in its transmembrane domain. Mutation of Cys(257) abolished neurotrophin-dependent receptor activity but did not affect downstream signaling by the p75(NTR)/NgR/Lingo-1 complex in response to MAG, indicating the existence of distinct, ligand-specific activation mechanisms for p75(NTR). FRET experiments revealed a close association of p75(NTR) intracellular domains that was transiently disrupted by conformational changes induced upon NGF binding. Although mutation of Cys(257) did not alter the oligomeric state of p75(NTR), the mutant receptor was no longer able to propagate conformational changes to the cytoplasmic domain upon ligand binding. We propose that neurotrophins activate p75(NTR) by a mechanism involving rearrangement of disulphide-linked receptor subunits.

Neurosteroids as Endogenous Inhibitors of Neuronal Cell Apoptosis in Aging

Abstract:  The neuroactive steroids dehydroepiandrosterone (DHEA), its sulfate ester DHEAS, and allopregnanolone (Allo) are produced in the adrenals and the brain. Their production rate and levels in serum, brain, and adrenals decrease gradually with advancing age. The decline of their levels was associated with age‐related neuronal dysfunction and degeneration, most probably because these steroids protect central nervous system (CNS) neurons against noxious agents. Indeed, DHEA(S) protects rat hippocampal neurons against NMDA‐induced excitotoxicity, whereas Allo ameliorates NMDA‐induced excitotoxicity in human neurons. These steroids exert also a protective role on the sympathetic nervous system. Indeed, DHEA, DHEAS, and Allo protect chromaffin cells and the sympathoadrenal PC12 cells (an established model for the study of neuronal cell apoptosis and survival) against serum deprivation–induced apoptosis. Their effects are time‐ and dose‐dependent with EC50 1.8, 1.1, and 1.5 nM, respectively. The prosurvival effect of DHEA(S) appears to be NMDA‐, GABAA‐ sigma1‐, or estrogen receptor‐independent, and is mediated by G‐protein‐coupled‐specific membrane binding sites. It involves the antiapoptotic Bcl‐2 proteins, and the activation of prosurvival transcription factors CREB and NF‐κB, upstream effectors of the antiapoptotic Bcl‐2 protein expression, as well as prosurvival kinase PKCα/β, a posttranslational activator of Bcl‐2. Furthermore, they directly stimulate biosynthesis and release of neuroprotective catecholamines, exerting a direct transcriptional effect on tyrosine hydroxylase, and regulating actin depolymerization and submembrane actin filament disassembly, a fast‐response cellular system regulating trafficking of catecholamine vesicles. These findings suggest that neurosteroids may act as endogenous neuroprotective factors. The decline of neurosteroid levels during aging may leave the brain unprotected against neurotoxic challenges.

Urocortin 1 and Urocortin 2 induce macrophage apoptosis via CRFR2

Macrophages undergo apoptosis as a mechanism of regulating their activation and the inflammatory reaction. Macrophages express the Corticotropin‐Releasing Factor Receptor‐2 (CRFR2) the endogenous agonists of which, the urocortins, are also present at the site of inflammation. We have found that urocortins induced macrophage apoptosis in a dose‐ and time‐dependent manner via CRFR2. In contrast to lipopolysaccharide (LPS)‐induced apoptosis, the pro‐apoptosis pathway activated by urocortins involved the pro‐apoptotic Bax and Bad proteins and not nitric oxide, JNK and p38MAPK characteristic of LPS. In conclusion, our data suggest that endogenous CRFR2 ligands exert an anti‐inflammatory effect via induction of macrophage apoptosis.

Estrogen exerts neuroprotective effects via membrane estrogen receptors and rapid Akt/NOS activation

The neuroprotective role of estrogen (E2) is supported by a multitude of experimental and epidemiological data, although its mode of action is not fully understood. The present work was conducted to study the underlying mechanisms of its neuroprotective action, using the rat cell line PC12, an established model for neuronal cell apoptosis and survival. Our results show that E2 (but not androgens or progestins) prevent growth inhibition and apoptosis of PC12 cells, induced by serum deprivation. Several mechanisms of action were investigated: 1) intracellular estrogen receptors (ERs) have been identified but do not appear to mediate the protective effect of E2. 2) The antioxidant properties of E2 cannot explain their protective actions at the concentrations used (10−12‐10−6 M). 3) Finally, membrane sites for E2 have been identified, and the underlying initial signaling cascade (2‐30 min after E2) has been tested, showing Ca2+ mobilization→PI3K activation→Akt phosporylation→NOS activation. Inhibition of PI3K or NOS completely reversed the anti‐apoptotic effect of E2. These results suggest a new mechanism of neuroprotective action of estrogen.

G protein-associated, specific membrane binding sites mediate the neuroprotective effect of dehydroepiandrosterone

The neurosteroid dehydroepiandrosterone (DHEA) at 1 nM protects NMDA‐/GABAA‐receptor negative neural crest‐derived PC12 cells from apoptosis. We now report that membrane‐impermeable DHEA‐BSA conjugate replaces unconjugated DHEA in protecting serum‐deprived PC12 cells from apoptosis (IC50=1.5 nM). Protection involves phosphorylation of the prosurvival factor Src and induction of the anti‐apoptotic protein Bcl‐2 and is sensitive to pertussis toxin. Binding assays of [3H]DHEA on isolated PC12 cell membranes revealed saturation within 30 min and binding of DHEA with a Kd of 0.9 nM. A similar binding activity was detectable in isolated membranes from rat hippocampus and from normal human adrenal chromaffin cells. The presence of DHEA‐specific membrane binding sites was confirmed by flow cytometry and confocal laser microscopy of DHEA‐BSA‐FITC stained cells. In contrast to estrogens and progestins, glucocorticoids and androgens displaced DHEA from its membrane binding sites but with a 10‐fold lower affinity than DHEA (IC50=9.3 and 13.6 nM, respectively). These agents acted as pure antagonists, blocking the antiapoptotic effect of DHEA as well as the induction of Bcl‐2 proteins and Src kinase activation. In conclusion, our findings suggest that neural crest‐derived cells possess specific DHEA membrane binding sites coupled to G proteins. Binding to these sites confers neuroprotection.

Corticotropin-Releasing Factor and the Urocortins Induce the Expression of TLR4 in Macrophages via Activation of the Transcription Factors PU.1 and AP-1

Corticotropin-releasing factor (CRF) augments LPS-induced proinflammatory cytokine production from macrophages. The aim of the present study was to determine the mechanism by which CRF and its related peptides urocortins (UCN) 1 and 2 affect LPS-induced cytokine production. We examined their role on TLR4 expression, the signal-transducing receptor of LPS. For this purpose, the murine macrophage cell line RAW 264.7 and primary murine peritoneal macrophages were used. Exposure of peritoneal macrophages and RAW 264.7 cells to CRF, UCN1, or UCN2 up-regulated TLR4 mRNA and protein levels. To study whether that effect occurred at the transcriptional level, RAW 264.7 cells were transfected with a construct containing the proximal region of the TLR4 promoter linked to the luciferase gene. CRF peptides induced activation of the TLR4 promoter, an effect abolished upon mutation of a proximal PU.1-binding consensus or upon mutation of an AP-1-binding element. Indeed, all three peptides promoted PU.1 binding to the proximal PU.1 site and increased DNA-binding activity to the AP-1 site. The effects of CRF peptides were inhibited by the CRF2 antagonist anti-sauvagine-30, but not by the CRF1 antagonist antalarmin, suggesting that CRF peptides mediated the up-regulation of TLR4 via the CRF2 receptor. Finally, CRF peptides blocked the inhibitory effect of LPS on TLR4 expression. In conclusion, our data suggest that CRF peptides play an important role on macrophage function. They augment the effect of LPS by inducing Tlr4 gene expression, through CRF2, via activation of the transcription factors PU.1 and AP-1.

Neurosteroid Dehydroepiandrosterone Interacts with Nerve Growth Factor (NGF) Receptors, Preventing Neuronal Apoptosis

The neurosteroid dehydroepiandrosterone (DHEA), produced by neurons and glia, affects multiple processes in the brain, including neuronal survival and neurogenesis during development and in aging. We provide evidence that DHEA interacts with pro-survival TrkA and pro-death p75NTR membrane receptors of neurotrophin nerve growth factor (NGF), acting as a neurotrophic factor: (1) the anti-apoptotic effects of DHEA were reversed by siRNA against TrkA or by a specific TrkA inhibitor; (2) [3H]-DHEA binding assays showed that it bound to membranes isolated from HEK293 cells transfected with the cDNAs of TrkA and p75NTR receptors (KD: 7.4±1.75 nM and 5.6±0.55 nM, respectively); (3) immobilized DHEA pulled down recombinant and naturally expressed TrkA and p75NTR receptors; (4) DHEA induced TrkA phosphorylation and NGF receptor-mediated signaling; Shc, Akt, and ERK1/2 kinases down-stream to TrkA receptors and TRAF6, RIP2, and RhoGDI interactors of p75NTR receptors; and (5) DHEA rescued from apoptosis TrkA receptor positive sensory neurons of dorsal root ganglia in NGF null embryos and compensated NGF in rescuing from apoptosis NGF receptor positive sympathetic neurons of embryonic superior cervical ganglia. Phylogenetic findings on the evolution of neurotrophins, their receptors, and CYP17, the enzyme responsible for DHEA biosynthesis, combined with our data support the hypothesis that DHEA served as a phylogenetically ancient neurotrophic factor.

Activation of membrane estrogen receptors induce pro-survival kinases.

Experimental and epidemiological data suggest a neuroprotective role for estrogen (E(2)). We have recently shown that, in PC12 cells, non-permeable estradiol conjugated to bovine serum albumin (BSA) prevent serum-deprivation induced apoptosis through activation of specific membrane estrogen receptors (mER). In the present study, we explored in detail the early signaling events involved in this anti-apoptotic action, downstream to activation of mER. Our findings suggest that mER is associated to G-proteins, and its activation with non-permeable E(2)-BSA results in the activation of the following downstream pro-survival kinases pathways: (1) the PKB/Akt pathway, (2) the Src-->MEK-->ERK kinases and finally (3) the MAPK-->ERK kinases. Activation of these pro-survival signals leads to CREB phosphorylation and NFkappaB nuclear translocation, two transcription factors controlling the expression of anti-apoptotic Bcl-2 proteins. These data suggest that major pro-survival kinases are involved in the mER-mediated anti-apoptotic effects of estrogen. This is further supported by experiments with specific kinases inhibitors, which partially but significantly reversed the mER-mediated anti-apoptotic effect of E(2)-BSA. Our findings suggest that estrogen act via mER as potent cytoprotective factors, downstream activating pro-survival kinases, assuring thus an efficient and multipotent activation of the anti-apoptotic machinery.

Rho/ROCK/actin signaling regulates membrane androgen receptor induced apoptosis in prostate cancer cells

In this study we describe a novel Rho small GTPase dependent pathway that elicits apoptotic responses controlled by actin reorganization in hormone-sensitive LNCaP- and hormone insensitive DU145-prostate cancer cells stimulated with membrane androgen receptor selective agonists. Using an albumin-conjugated steroid, testosterone-BSA, we now show significant induction of actin polymerization and apoptosis that can be reversed by actin disrupting agents in both cell lines. Testosterone-BSA triggered RhoA/B and Cdc42 activation in DU145 cells followed by stimulation of downstream effectors ROCK, LIMK2 and ADF/destrin. Furthermore, dominant-negative RhoA, RhoB or Cdc42 mutants or pharmacological inhibitors of ROCK inhibited both actin organization and apoptosis in DU145 cells. Activation of RhoA/B and ROCK was also implicated in membrane androgen receptor-dependent actin polymerization and apoptosis in LNCaP cells. Our findings suggest that Rho small GTPases are major membrane androgen receptor effectors controlling actin reorganization and apoptosis in prostate cancer cells.