Proteomic Profiling of Antimalarial Plasmodione Using 3-Benz(o)ylmenadione Affinity-Based Probes

Understanding the mechanisms of drug action in malarial parasites is crucial for the development of new drugs to combat infection and to counteract drug resistance. Proteomics is a widely used approach to study host-pathogen systems and to identify drug protein targets. Plasmodione is an antiplasmodial early-lead drug exerting potent activities against young asexual and sexual blood stages in vitro with low toxicity to host cells. To elucidate its molecular mechanisms, an affinity-based protein profiling (AfBPP) approach was applied to yeast and P. falciparum proteomes. New (pro-)AfBPP probes based on the 3-benz(o)yl-6-fluoro-menadione scaffold were synthesized. With optimized conditions of both photoaffinity labeling and click reaction steps, the AfBPP protocol was then applied to a yeast proteome, yielding 11 putative drug-protein targets. Among these, we found four proteins associated with oxidoreductase activities, the hypothesized type of targets for plasmodione and its metabolites, and other proteins associated with the mitochondria. In Plasmodium parasites, the MS analysis revealed 44 potential plasmodione targets that need to be validated in further studies. Finally, the localization of a 3-benzyl-6-fluoromenadione AfBPP probe was studied in the subcellular structures of the parasite at the trophozoite stage.

Click-Chemistry-Based Biomimetic Ligands Efficiently Capture G-Quadruplexes In Vitro and Help Localize Them at DNA Damage Sites in Human Cells

Interrogating G-quadruplex (G4) biology at its deepest roots in human cells relies on the design, synthesis, and use of ever smarter molecular tools. Here, we demonstrate the versatility of biomimetic G4 ligands referred to as TASQ (template assembled synthetic G-quartet) in which a biotin handle was incorporated for G4-focused chemical biology investigations. We have rethought the biotinylated TASQ design to make it readily chemically accessible via an efficient click-chemistry-based strategy. The resulting biotinylated, triazole-assembled TASQ, or BioTriazoTASQ, was thus shown to efficiently isolate both DNA and RNA G4s from solution by affinity purification protocols, for identification purposes. Its versatility was then further demonstrated by optical imaging that provided unique mechanistic insights into the actual strategic relevance of G4-targeting strategies, showing that ligand-stabilized G4 sites colocalize with and, thus, are responsible for DNA damage foci in human cells.

Mobilization of the cell adhesion glycoprotein F3/contactin to axonal surfaces is activity dependent

F3/contactin is a cell adhesion/recognition molecule of the immunoglobulin superfamily implicated in axonal growth. We examined its subcellular distribution and mobilization to the cell surface in oxytocin- (OT-) secreting neurons, which express it throughout life and the axons of which undergo activity-dependent remodelling. This was performed in hypothalamic organotypic slice cultures containing OT neurons with properties of adult neurosecretory cells. Immunocytochemistry and immunoblot analysis confirmed that OT neurons express high levels of F3/contactin in vitro. Light and confocal microscopy of cultures that underwent double immunofluorescence after fixation showed F3/contactin immunoreactivity throughout the cytoplasm of OT somata, dendrites and axons, and also in non-OT axons and in putative synaptic boutons which contacted OT neurons. By contrast, after treatment of live cultures with anti-F3/contactin antibodies followed by double immunofluorescence for the glycoprotein and OT, F3/contactin immunoreactivity was visible only on the surface of axons, whether or not OT-immunoreactivity was present. Because of its glycosylphosphatidyl-inositol (GPI) linkage, F3/contactin can occur in a membrane-bound or soluble form. As seen from immunocytochemistry of live cells and immunoblot analysis, treatment of cultures with a GPI-specific phospholipase C (GPI-PLC) resulted in loss of F3/contactin immunoreactivity from all cell surfaces. F3/contactin immunoreactivity reappeared on axonal surfaces within 5 h after enzyme washout. Such re-expression was accelerated by neuronal activity facilitation (by K+ depolarization or gamma-aminobutyric acid (GABA)-A receptor blockade with bicuculline) and inhibited by neuronal activity repression [by blockade of Ca2+ channels with Mn2+, Na+ channels with tetrodotoxin (TTX) or excitatory inputs with glutamate antagonists]. Our observations establish therefore that F3/contactin surface expression in hypothalamic neurons is polarized to the axons where it occurs mainly in a GPI-linked form. We also provide direct evidence that externalization of F3/contactin depends on Ca2+ entry and neuronal electrical activity. Taken together with our earlier finding that the glycoprotein is localized in neurosecretory granules, we demonstrate that F3/contactin is mobilized to the axonal surface via the activity-dependent regulated pathway, thus arriving at the correct place and time to intervene in activity-dependent remodelling of axons.

The polysialylated neural cell adhesion molecule reaches cell surfaces of hypothalamic neurons and astrocytes via the constitutive pathway

Understanding how neurons and glia sort and deliver cell adhesion molecules to their cell surface should provide important clues as to how such molecules participate in dynamic neuronal functions in the developing and adult brain. The present study examines translocation of polysialylated neural cell adhesion molecule (PSA-NCAM), a negative regulator of cell adhesion, in cells of the rat hypothalamo-neurohypophysial system in which it is expressed throughout life and which undergo morphological remodelling in response to stimulation. PSA-NCAM expression in this system does not vary markedly in relation to different conditions of regulated neurosecretion, suggesting that the glycoprotein reaches cell surfaces via the constitutive pathway. To study this more directly, we here used immunofluorescence for PSA on NCAM in live, unpermeabilized cells to monitor PSA-NCAM surface expression in organotypic slice cultures from postnatal rat hypothalami. Subsequent immunolabelling for oxytocin confirmed that the cultures included magnocellular oxytocinergic neurons displaying many properties of adult neurosecretory neurons in situ. In the cultures, immunoreaction for PSA-NCAM was visible on the surface of oxytocinergic and non-oxytocinergic axons. This reaction disappeared after exposure of the cultures to endoneuraminidase, an enzyme which specifically cleaves alpha-2-8-linked PSA from NCAM. PSA-NCAM reappeared on axonal surfaces 4h after enzyme washout. Such reexpression was visibly not affected by neuronal activity inhibition (blockade of Ca(2+) channels with Mn(2+), of Na(+) channels with tetrodotoxin, or of glutamate receptors with 6-cyano-7-nitroquinoxaline-2,3-dione or D-2-amino-5-phosphonopentanoic acid) or facilitation (K(+) depolarization or GABA-A receptor blockade with bicuculline). In contrast, PSA-NCAM surface translocation was inhibited reversibly by cooling the cultures at 20 degrees C, a procedure which blocks constitutive secretion and which resulted in accumulation of PSA-NCAM in the cytoplasm of oxytocinergic and non-oxytocinergic neurons. This treatment also revealed PSA-NCAM in the cytoplasm of underlying astrocytes. Our observations provide direct evidence that PSA-NCAM reaches the cell surface of hypothalamic neurons and astrocytes via the constitutive pathway, independently of Ca(2+) entry and enhanced neuronal activity. Thus, PSA-NCAM in the hypothalamo-neurohypophysial system would be continuously available to permit its cells to undergo remodelling whenever the proper stimulus intervenes.

Visualization of local afferent inputs to magnocellular oxytocin neurons in vitro

We recently showed that oxytocin (OT) neurons in organotypic slice cultures obtained from postnatal rat hypothalamus display complex patterns of electrical activity, similar to those of adult magnocellular OT neurons in vivo. Here we used such cultures to investigate the identity and, in particular, the origin of afferent inputs responsible for this activity. Multiple immunostaining with light and confocal microscopy showed that the somata and dendrites of oxytocinergic neurons were contacted by numerous synapses, visualized by their reaction to the synaptic markers, synaptophysin or synapsin. Many were GABAergic, displaying immunoreactivities for glutamic acid decarboxylase or gamma-aminobutyric acid (GABA); others were enriched in glutamate immunoreactivity. Such afferents presumably arose from GABA- or glutamate-immunoreactive neurons, respectively, with distinct and characteristic morphologies and topographies. A few dopaminergic boutons (tyrosine hydroxylase- or dopamine-immunopositive) impinged on OT neurons; they arose from dopamine-positive neurons located along the third ventricle. No noradrenergic profiles were detected. Despite the presence of choline acetyl-transferase (ChAT)-immunoreactive neurons, there were no cholinergic contacts. Lastly, we found oxytocinergic synapses, identified by immunoreaction for OT-related neurophysin and synapsin, contacting OT somata and dendrites. Our observations thus demonstrate that inhibitory and excitatory inputs to OT neurons derive from local intrahypothalamic GABA and glutamate neurons, in close proximity to the neurons. They also reveal that OT neurons are innervated by hypothalamic dopaminergic neurons. Finally, they confirm the existence of homotypic OT synaptic contacts which derive from local OT neurons.

Electrophysiological studies of oxytocin neurons in organotypic slice cultures

We have developed organotypic slice cultures derived from postnatal rat hypothalamus which contain well-differentiated oxytocin neurons. Intracellular recordings of identified neurons show that these cultured oxytocin cells exhibit basal electrical properties closely similar to those of magnocellular cells recorded in vivo and in acute in vitro preparations from adult animals. The cultures also include GABAergic and glutamatergic neurons making connections with the oxytocin cells, which strongly suggests that the rich GABAergic and glutamatergic innervations of adult oxytocin neurons in vivo derive largely from local hypothalamic sources. Pharmacological manipulations indicate that the cultured oxytocin neurons present functional GABAA (but not GABAB) receptors, and ionotropic non-NMDA and NMDA receptors, but no metabotropic receptors for glutamate. These synaptic inputs control to a great extent the electrical activity of oxytocin neurons. Of particular interest is our observation that the cultured oxytocin neurons display a recurrent bursting activity which does not appear to result from an endogenous regenerative activity, but from a patterned glutamatergic input. Our preliminary data show that oxytocin plays a facilitatory role in this bursting activity and suggest that such activity is generated within an hypothalamic circuitry.

Evidence for a hypothalamic oxytocin-sensitive pattern-generating network governing oxytocin neurons in vitro

During lactation and parturition, magnocellular oxytocin (OT) neurons display a characteristic bursting electrical activity responsible for pulsatile OT release. We investigated this activity using hypothalamic organotypic slice cultures enriched in magnocellular OT neurons. As shown here, the neurons are functional and actively secrete amidated OT into the cultures. Intracellular recordings were made from 23 spontaneously bursting and 28 slow irregular neurons, all identified as oxytocinergic with biocytin and immunocytochemistry. The bursting electrical activity was similar to that described in vivo and was characterized by bursts of action potentials (20.1 +/- 4.3 Hz) lasting approximately 6 sec, over an irregular background activity. OT (0.1-1 microM), added to the medium, increased burst frequency, reducing interburst intervals by 70%. The peptide also triggered bursting in 27% of nonbursting neurons. These effects were mimicked by the oxytocin receptor (OTR) agonist [Thr4, Gly7]-OT and inhibited by the OTR antagonist desGly-NH2d(CH2)5[D-Tyr2,Thr4]OVT. Burst rhythmicity was independent of membrane potential. Hyperpolarization of the cells unmasked volleys of afferent EPSPs underlying the bursts, which were blocked by CNQX, an AMPA/kainate receptor antagonist. Our results reveal that OT neurons are part of a hypothalamic rhythmic network in which a glutamatergic input governs burst generation. OT neurons, in turn, exert a positive feedback on their afferent drive through the release of OT.

Voltage-dependent calcium and potassium channels in Schwann cells cultured from dorsal root ganglia of the mouse

1. Whole-cell patch clamp studies were carried out on Schwann cells in organotypic cultures of dorsal root ganglia (DRG) from OF1 mice embryos (18-19 days). 2. In standard external solution, from a holding potential of -70 mV, two types of voltage-dependent K+ currents were recorded: a fast transient current and a delayed sustained current. With a holding potential of -30 mV, only the delayed sustained current could be evoked. 3. Both K+ currents were inhibited by tetraethylammonium chloride (TEA) and 4-aminopyridine (4-AP) in a dose-dependent manner. For the transient current the half-maximal effective dose was 100 mM for TEA and 1.3 mM for 4-AP. For the delayed sustained current the half-maximal effective dose was 11 mM for TEA and 4 mM for 4-AP. Both currents were insensitive to external Ca2+. 4. The delayed sustained current, isolated by use of a holding potential of -30 mV displayed a 'cumulative inactivation' which was removed by hyperpolarizing the membrane to -70 mV between each test pulse. 5. In K(+)-free external and pipette solutions, with 10 mM-external Ca2+, from a holding potential of -70 mV voltage-dependent Ca2+ channel currents were recorded. The threshold for activation was -45.3 +/- 5.4 mV (mean +/- S.D., n = 5) and the current inactivated fully at the end of the test potential. The current was unaffected by 2 microM-tetrodotoxin (TTX) and totally blocked by 5 mM-Co2+. 6. Equimolar replacement of external Ca2+ by Ba2+ did not significantly modify the voltage dependence (threshold for activation -42.8 +/- 6.4 mV, n = 7) or the magnitude of the inward current. Ca2+ and Ba2+ were equally permeant. The fully inactivating current was insensitive to both nifedipine and Bay K 8644 (1 microM each). Increasing the external Ba2+ concentration from 10 to 89 mM enhanced the Ba2+ current and shifted the voltage dependence of the current (threshold for activation, -30.5 +/- 7.3 mV, n = 9) along the voltage axis as expected for altered external surface potential. 7. In 89 mM-external Ba2+ solution, some cells displayed an additional slowly decaying current which was totally blocked by nifedipine (1 microM). 8. Ca2+ channel currents were recorded only when DRG neurons were present in the culture, as excision of explants and subsequent axonal degeneration led to loss of detectable Ca2+ channel currents. This phenomenon was never observed for K+ currents. 9. We conclude that mouse Schwann cells in organotypic culture possess voltage-dependent K+ and Ca2+ channels.(ABSTRACT TRUNCATED AT 400 WORDS)

Maturation of a transient outward potassium current in mouse fetal hypothalamic neurons in culture

The whole-cell voltage clamp technique was used to record potassium currents in mouse fetal hypothalamic neurons developing in culture medium from days 1 to 17. The neurons were derived from fetuses of IOPS/OF1 mice on the 14th day of gestation. The mature neurons (greater than six days in culture) showed both a transient potassium current and a non-inactivating delayed rectifier potassium current. These were identified pharmacologically by using the potassium channel blockers tetraethyl ammonium chloride and 4-aminopyridine, and on the basis of their kinetics and voltage sensitivities. The delayed rectifier potassium current had a threshold of-20 mV, a slow time-course of activation, and was sustained during the voltage pulse. The 4-aminopyridine-sensitive current was transient, and was activated from a holding potential more negative (-80 mV) than that required for evoking the delayed rectifier potassium current (-40 mV). The delayed rectifier potassium current was detectable from day 1 onwards, while the transient potassium current showed a distinct developmental trend. The time-constant of inactivation became faster with age in culture. The half steady-state inactivation potential showed a shift towards less negative membrane potentials with age, and the relationship was best described by a logarithmic regression equation. The developmental trend of the transient potassium current may relate functionally to the progressive morphological changes, and the appearance of synaptic connections during ontogenesis.

Excitatory effect of serotonin on pacemaker neurons in spinal cord cell culture

Intracellular recordings were made from fetal mouse spinal cord neurons in primary culture. One type of neuron, with large somata (40-50 microns diameter) and thick neurites exhibited endogenous bursting or beating pacemaker electrical activity. Noradrenaline depolarized this type of neuron by decreasing an M-like conductance. Micropressure application of serotonin (10(-5) M in the delivery pipette) onto the surface of pacemaker neurons evoked a depolarization of the membrane potential in a dose-dependent manner with an increased input resistance. No such response was observed with other types of spinal cord neurons in culture. The response to serotonin was partially voltage-dependent. The serotonin-induced depolarization reversed at holding potential close to -100 mV. However, the input resistance variation evoked by serotonin increased exponentially when membrane potential was depolarized. The reversal potential was modified by increasing extracellular K+ concentration and it was unaltered by increasing the intracellular Cl- concentration. The decrease in K+ conductance induced by serotonin was not suppressed by the application of tetraethylammonium (50 mM) or 4-aminopyridine (10 mM). Furthermore, application of Ba2+ (6 mM) or Cd2+ (0.1 mM) had no effect on this response, suggesting that the depolarization evoked by serotonin application was not calcium-dependent. The serotonin evoked increase in input resistance was mediated by activation of a 5-HT1A-like receptor site. Spiperone, a 5-HT1A antagonist reversibly blocked the response. Methiothepin, a 5-HT1-5-HT2 antagonist (10(-3) M); cocaine, a 5-HT3 antagonist (10(-3) M); ketanserin, a 5-HT2 antagonist (10(-3) M); and prazosin, an alpha 1 antagonist (10(-3) M) had no effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Excitatory effect of noradrenaline on pacemaker cells in spinal cord primary cultures

Intracellular recordings were made from dissociated fetal mouse spinal cord neurons in primary culture. One particular type of neuron, with a large cell body (40-50 micron) and three to five thick neurites, exhibited rhythmic electrical activity of two different types, consisting of either spontaneous burst discharges or tonic action potential firing. Both types of activity appeared to be triggered by an endogenous membrane potential oscillation. Micropressure application of noradrenaline (10(-5) M in the delivery pipette) onto the surface of such cells evoked, in a dose-dependent manner, an increase in the input resistance with a depolarization of the membrane potential. The response to NA was potential-dependent. The maximum change in input resistance was observed at membrane potential values between -60 mV and -45 mV and the response was suppressed at membrane potentials lower than -80 mV. No modification of the response was observed in the presence of 50 mM of tetraethylammonium. The extrapolated reversal potential, close to -90 mV, was modified by increasing extracellular K+ concentration and unaltered by increasing the intracellular Cl- concentration. The decrease in K+ conductance induced by noradrenaline was Ca2+-dependent and reversibly suppressed by Ba2+ (6 mM) and Cd2+ (0.1 mM). This response to noradrenaline was suppressed in the presence of muscarine (10 microM) suggesting that noradrenaline decreases a K+ conductance related to M current. The noradrenaline evoked increase in input resistance was mediated by activation of an alpha 1 receptor site. Prazosin, an alpha 1 antagonist and phentolamine, an alpha 1 alpha 2 antagonist, reversibly suppressed the response in a competitive manner. Yohimbine, a competitive alpha 2 antagonist, also blocked the response, but in a noncompetitive manner. Clonidine, an alpha 2 agonist, isoprenaline, a beta agonist and L-alprenolol, a beta antagonist, had no effect.

Angiotensin II inactivation process in cultured mouse spinal cord cells

The pattern of hydrolysis of [3H]angiotensin II ( [3H]AII; 20 nM) by intact cells was studied on cultured mouse spinal cord cells. Degradation products were identified by HPLC analysis after incubation for 2 h at 37 degrees C. In the absence of peptidase inhibitors, 70% of [3H]AII was degraded, and the main labeled metabolite was [3H]tyrosine (40% of total radioactivity). Minor quantities of [3H]AII1-5 and [3H]AII4-8 were formed. Results obtained in the presence of various inhibitors indicate that several enzymes were involved in the AII-hydrolyzing process. Dipeptidyl aminopeptidase III (EC 3.4.14.4) could play a critical role, as suggested by the formation of [3H]Val3-Tyr4 and [3H]-Tyr4-Ile5 in the presence of bestatin (2 X 10(-5) M). This hypothesis was confirmed by the potency of dipeptidyl amino-peptidase III inhibitors to inhibit both [3H]AII hydrolysis and formation of these 3H-labeled dipeptides. An arylamidase-like activity could also be participating in [3H]AII hydrolysis, because higher concentrations of bestatin (10(-4) M) in association with dipeptidyl aminopeptidase III inhibitors totally inhibited [3H]tyrosine formation, increased protection of [3H]AII and [3H]AII1-7 formed, and provoked a slight accumulation of [3H]AII2-8. These results suggest that the formation of [3H]AII2-8 is due to the action of a bestatin-insensitive acidic aminopeptidase and that the Pro7-Phe8 cleavage is also a step of AII hydrolysis, resulting from the action of an unidentified peptidase different from prolyl endopeptidase.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence for bursting pacemaker neurones in cultured spinal cord cells

Intracellular recordings were made from dissociated mouse spinal cord cells in primary culture. One type of spinal cord neurone, with a large cell body (40-50 micron), 3-5 short neurites, and a mean resting potential of -65 mV, was found to fire rhythmic bursts of action potentials with a phase duration of approximately 1s when the membrane potential was depolarized to -55 mV. These bursts did not arise from spontaneous synaptic input, but appeared to result from endogenous ionic conductance properties of the membrane resembling those observed in molluscan bursting pacemaker neurones. Ionic conductances underlying this bursting activity were studied pharmacologically by local application of ionic conductance blockers. Pacemaker potentials depended on Na+ conductance, since tetrodotoxin and Na-free medium were the most potent agents for blocking spontaneous rhythmic activity. However, a Ca2+ conductance was involved in the depolarizing phase of membrane potential oscillations, since Ba2+ application increased oscillation amplitude. Action potentials observed during the bursts were Na+- and Ca2+-dependent. They did not differ significantly from those observed in other spinal cord neurones in culture. Application of tetraethylammonium, CoCl2, BaCl2 and 4-aminopyridine revealed at least three different potassium conductances which controlled this bursting pacemaker activity. A delayed potassium conductance controlled spike duration, a Ca-dependent potassium conductance controlled the duration of the burst and underlay the hyperpolarizing phase terminating the burst, and finally, a transient potassium conductance appeared to be involved in the control of phase duration. The demonstration that spinal cord neurones growing in monolayer culture display typical bursting pacemaker activity raises the possibility that bursting pacemaker neurones in the mammalian spinal cord may be involved in a phasic pattern generator that could control such activities as walking and the respiratory rhythm.

Characterization of two angiotensin II binding sites in cultured mouse spinal cord neurones

Characteristics of angiotensin II (AII) binding have been determined in cultured mouse spinal cord neurones using [125I]AII and [3H]AII. The Scatchard plot of equilibrium binding was curvilinear and could be described by postulating the existence of two different classes of independent binding sites (Kd1 = 0.43 nM, Bmax1 = 12.5 fmol/1.5 X 10(6) cells; Kd2 = 25.6 nM, Bmax2 = 220 fmol/1.5 X 10(6) cells). These values are in close agreement with the Kd values obtained from kinetic studies. The high affinity binding sites appeared to be similar to the single class of sites described in other studies. The relative inhibition potency of AII-related peptides was studied. Sar1,-Leu8-AII was the most potent in inhibiting specific AII binding. The characteristics of the two AII binding sites suggest that they correspond to two receptors as described in a previous electrophysiological approach using this model in our laboratory. Taken together, these data confirm that this model of neurones in primary culture is a unique and very attractive model of receptor studies. The classical criteria necessary for positive identification of a ligand-receptor have been satisfied: saturability, reversibility, specificity and most importantly correlation of the binding parameters and biological effects of AII.