Search for Leptonic Decays of Dark Photons at NA62.

The NA62 experiment at CERN, configured in beam-dump mode, has searched for dark photon decays in flight to electron-positron pairs using a sample of 1.4×10^{17} protons on dump collected in 2021. No evidence for a dark photon signal is observed. The combined result for dark photon searches in lepton-antilepton final states is presented and a region of the parameter space is excluded at 90% confidence level, improving on previous experimental limits for dark photon mass values between 50 and 600 MeV/c^{2} and coupling values in the range 10^{-6} to 4×10^{-5}. An interpretation of the e^{+}e^{-} search result in terms of the emission and decay of an axionlike particle is also presented.

Axo-axonal coupling. a novel mechanism for ultrafast neuronal communication.

We provide physiological, pharmacological, and structural evidence that axons of hippocampal principal cells are electrically coupled, with prepotentials or spikelets forming the physiological substrate of electrical coupling as observed in cell somata. Antidromic activation of neighboring axons induced somatic spikelet potentials in neurons of CA3, CA1, and dentate gyrus areas of rat hippocampal slices. Somatic invasion by these spikelets was dependent on the activation of fast Na(+) channels in the postjunctional neuron. Antidromically elicited spikelets were suppressed by gap junction blockers and low intracellular pH. Paired axo-somatic and somato-dendritic recordings revealed that the coupling potentials appeared in the axon before invading the soma and the dendrite. Using confocal laser scanning microscopy we found that putative axons of principal cells were dye coupled. Our data thus suggest that hippocampal neurons are coupled by axo-axonal junctions, providing a novel mechanism for very fast electrical communication.

Effects of dexamethasone and celecoxib on calcium homeostasis and expression of cyclooxygenase-2 mRNA in MG-63 human osteosarcoma cells.

OBJECTIVE: Glucocorticoids and selective COX-2 inhibitors are potent anti-inflammatory agents. They are also suggested to influence bone physiology and remodeling. Here we searched for effects of dexamethasone and celecoxib on crucial parameters of bone physiology that could be therapeutically relevant. METHODS: The human osteosarcoma cell line MG-63 was used to measure effects of these drugs on (i) intracellular calcium concentration ([Ca2+]i) using a microfluorometric technique, (ii) alkaline phosphatase and osteocalcin levels (EIA) and (iii) the expression of cox-2 mRNA (quantitative real time PCR). Measurements were performed in Vitamine D-incubated quiescent cells and in cells stimulated with TNF-alpha and IL-1beta. RESULTS: We found the cytokine-stimulation to increase [Ca2+]i which was prevented by dexamethasone already after 30 min and still after 48 h. Dexamethasone was without any effect on [Ca2+]i in quiescent cells. Celecoxib had no measurable short-term or long-term effects neither in quiescent nor in stimulated cells. Vitamin D stimulated the expression of cox-2 mRNA which was further enhanced by TNF-alpha/IL-1beta. Dexamethasone did not have any measurable effects on COX-2 expression after 30 min, but a pronounced inhibition was seen after 48 h. In contrast, celecoxib had no effect on COX-2 expression. Neither of the drugs had any effect on the secretion of alkaline phosphatase and osteocalcin. CONCLUSION: We found dexamethasone to inhibit the [Ca2+]i increase in MG-63 cells following stimulation and to reduce considerably COX-2 expression via the genomic pathway. In contrast, celecoxib did not show any measurable short-term or long-term effects on the parameters of bone physiology measured.

Increased mitochondrial superoxide generation in neurons from trisomy 16 mice: a model of Down's syndrome.

Increased neuronal cell death in neurodegenerative diseases has been suggested to result from an increased mitochondrial generation of radical oxygen species (ROS). To test this hypothesis, we investigated superoxide formation in cultured hippocampal neurons from diploid and trisomy 16 mice (Ts16), a model of Down's syndrome. Microflurometric techniques were used to measure superoxide-induced oxidation rate of hydroethidine (HEt) to ethidium and reduced nicotinamide adenine dinucleotide (NADH) and reduced nicotinamide adenine dinucleotide phosphate (NADPH) autofluorescence signal to monitor changes in neuronal energy metabolism. We found an increase in superoxide formation by more than 50% in Ts16 neurons in comparison with diploid control neurons. In the presence of the mitochondrial respiratory chain complex I inhibitor rotenone superoxide production was blocked in diploid neurons, but the increased superoxide generation in Ts16 neurons remained. Uncoupling of mitochondrial oxidative phosphorylation using carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) caused irreversible deficiency in the energy metabolism, monitored by NAD(P)H autofluorescence in Ts16 neurons, but not in diploid control neurons. These results suggest an increased basal generation of superoxide in Ts16 neurons, probably caused by a deficient complex I of mitochondrial electron transport chain, which leads to an impaired mitochondrial energy metabolism and finally neuronal cell death.

Coupling of neuronal activity and mitochondrial metabolism as revealed by NAD(P)H fluorescence signals in organotypic hippocampal slice cultures of the rat.

During physiological activity neurons may experience localised energy demands which require intracellular signals for stimulation of mitochondrial NADH generation and subsequent delivery of ATP. To elucidate these mechanisms, we applied microfluorimetric monitoring of cytoplasmic (Fluo-3) and mitochondrial (Rhod-2) calcium concentration ([Ca(2+)](c), [Ca(2+)](m)), as well as of mitochondrial oxidative metabolism (NAD(P)H), whilst simultaneously measuring changes in extracellular potassium concentration ([K(+)](o)), as an indicator of neuronal activity in hippocampal slice cultures. Changes in neuronal activity were induced by repetitive stimulation at different frequencies (5, 20, 100 Hz) and intensities. Stimulation parameters were chosen to elicit rises in [K(+)](o) of less than 3 mM which is comparable to physiologically occurring rises in [K(+)](o). The mitochondrial uncoupler carbonyl cyanide m-chlorophenyl hydrazone (CCCP) reduced stimulus-induced changes in Rhod-2 fluorescence by 79%, indicating that Rhod-2 signals were primarily of mitochondrial origin. Repetitive stimulation at 20 Hz applied to areas CA1 or CA3 resulted in moderate rises in [K(+)](o) which were associated with stimulus-dependent elevations in [Ca(2+)](c) and [Ca(2+)](m) of up to 15%. The same stimuli also elicited biphasic changes in NAD(P)H fluorescence characterised by an initial decline and a subsequent prolonged elevation of up to 10%. Variation of stimulus parameters revealed close correlations between rises in [K(+)](o), in [Ca(2+)](m) and changes in NAD(P)H fluorescence. To elucidate the role of intracellular Ca(2+) accumulation in induction of NAD(P)H fluorescence signals, the effect of application of Ca(2+)-free solution on these signals evoked by repetitive antidromic stimulation of the alveus during recordings in area CA1 was studied. Lowering extracellular Ca(2+) led to complete blockade of postsynaptic field potential components as well as of rises in [Ca(2+)](c) and [Ca(2+)](m). Amplitudes of NAD(P)H signals were reduced by 59%, though rises in [K(+)](o) were comparable in presence and absence of extracellular Ca(2+). The results suggest i) that mitochondrial oxidative metabolism is fine-tuned to graded physiological activity in neurons and ii) that rapid mitochondrial Ca(2+) signalling represents one of the main determinants for stimulation of oxidative metabolism under physiological conditions.

Cell death and metabolic activity during epileptiform discharges and status epilepticus in the hippocampus.

Mechanisms of seizure-induced cell death were studied in organotypic hippocampal slice cultures. These develop after withdrawal of magnesium recurrent seizure-like events (SLE), which lead to intracellular and intramitochondrial calcium accumulation. The intramitochondrial Ca accumulation seems to be involved in causing increased production of NADH, measured as NAD(P)H autofluorescence. During SLEs, depolarization of mitochondria and increased production of free radicals is indicated by fluorescence measurements with appropriate dyes. During recurrent seizures, an increased failure to produce NADH is noted while at the same time free radical production seems to increase. This increase and the decline in NADH production could be involved in transition to late recurrent discharges, a phase in which status epilepticus becomes pharmacoresistant. It also coincides with increased cell death as determined with propidium iodide fluorescence. Interestingly, some of these changes can be prevented by application of alpha-tocopherol, a free radical scavenger, which also has neuroprotective effects under our experimental conditions. The results suggest that free radical-induced mitochondrial impairment is involved in seizure-induced cell death.

Optical imaging of low Mg(2+)-induced spontaneous epileptiform activity in combined rat entorhinal cortex-hippocampal slices.

A reproducible increase in transmission of infrared light was observed during spontaneous seizure-like events (SLEs) induced by low Mg2+ solutions in combined rat entorhinal cortex-hippocampal slices. Comparison of half maxima of transmission change in different regions indicated propagation of SLEs from the medial entorhinal cortex towards the temporal cortex suggesting spread along existing anatomical pathways. Thus, optical imaging of spontaneous epileptiform activity is possible and may improve the assessment of spread patterns. The optical signal outlasted both SLEs and associated K+ signals. In contrast, the tetraethylammonium signal, indicating changes of the extracellular space (ECS) volume, had a longer time course than the transmission changes. ECS volume changes are widely held to be responsible for transmission change. Our data suggest that other mechanisms may also contribute to increased light transmission during epileptiform activity.

Acute cell damage after low Mg2+-induced epileptiform activity in organotypic hippocampal slice cultures.

Upon perfusion with Mg2+-free artificial cerebrospinal fluid (ACSF) organotypic hippocampal slice cultures develop seizure-like events and tonic recurrent discharges in which areas CA3 and CA1 and, in contrast to acute slices, also the dentate gyrus (DG) participate. Using the fluorescent dye propidium iodide (PI) we show that sustained epileptic activity causes cell death in the DG and pyramidal cell layer particularly evident in the granule cell layer of the DG. This correlates with the decrease of the electrophysiological responses to hilar stimulation. Interestingly, perfusion with carbogenated serum-free ACSF also induces some cell death which is, however, mild compared with low magnesium treated slice cultures.

Epileptiform activity induced by low Mg2+ in cultured rat hippocampal slices.

Organotypic cultured slices of the rat hippocampus undergo synaptic reorganization. Besides the establishment of reciprocal connections between area CA1 and the dentate gyrus (DG), collateral excitatory connections between granule cells are formed which are similar to those appearing in several epilepsy models and in the DG from patients with temporal lobe epilepsy. We studied the characteristics of epileptiform activity induced by low Mg2+ perfusion in cultured hippocampal slices using extra- and intracellular recordings. With low Mg2+ perfusion synchronous seizure like events (SLEs) were readily observed in the DG and areas CA3 and CA1. Also, the isolated DG was able to display seizure like activity. Intracellular recordings revealed long lasting depolarization shifts in granule cells of the DG and pyramidal cells of areas CA3 and CA1. The SLEs, lasting 2-3 s, could be recorded for at least 3 h in areas CA1 and CA3. However, approximately an hour after perfusion with low Mg2+, the epileptiform activity disappeared in the DG and responses to single pulse hilar stimulation progressively deteriorated. These responses returned to control values 1 week after reincubating the cultures. Interestingly, no deterioration of stimulus induced responses was observed in the isolated DG after exposure to low Mg2+.

Glutathione levels and nerve cell loss in hippocampal cultures from trisomy 16 mouse--a model of Down syndrome.

The tripeptide glutathione (reduced state, GSH) is an important intracellular free radical scavenger protecting cells against oxidative stress. The trisomy 16 mouse is a model of the human trisomy 21 (Down syndrome). Here we demonstrate that cultured hippocampal neurons from trisomy 16 mouse exhibit decreased GSH levels and augmented cell death when compared to diploid cells. Additional lowering of GSH levels led to enhanced cell death in trisomy 16 cells. Based on these results we suggest that a GSH level which is decreased under a specific threshold by increased consumption, reduced synthesis or lack in precursor contributes to cell loss and neurodegeneration in Down syndrome.

Impaired Ca-signaling in astrocytes from the Ts16 mouse model of Down syndrome.

The trisomy 16 mouse model of Down syndrome has been used to compare calcium (Ca)-homeostasis and Ca-signaling in astrocytes from trisomic mice and from diploid littermates. Ratio calcium-imaging of Fura-2/AM loaded primary astroglial cultures prepared from the hippocampus shows that resting Ca levels are on average significantly higher in trisomic than in the control astrocytes (280 vs. 120 nM). Serotonin (3 microM) and glutamate (30-300 microM) evoked transient Ca-increases from 400 to 600 nM in euploid but from only 20 to 150 nM in trisomic astrocytes. Imaging of ATP-driven Ca-accumulation in cellular organelles revealed a significantly stronger uptake of Ca in trisomic astrocytes that might buffer cytosolic Ca-increases. Our results demonstrate major disturbances in Ca-signaling in trisomic astrocytes that are likely to be of pathophysiological relevance.

Monitoring NAD(P)H autofluorescence to assess mitochondrial metabolic functions in rat hippocampal-entorhinal cortex slices.

Changes in neuronal energy metabolism, mitochondrial functions and homeostasis of reactive oxygen species are often supposed to induce alterations in neuronal activity in hippocampal slice models. In order to investigate the NAD(P)H autofluorescence signal in brain slice models, methods to monitor NAD(P)H signal in isolated mitochondria as described by Chance et al. [J. Biol. Chem. 254 (1979) 4764] and dissociated neurons as described by Duchen [Biochem. J. 283 (1992) 41] were adapted to recording conditions required for brain slices. Considering different experimental questions, we established an approach to monitor NAD(P)H autofluorescence signals from hippocampal slices of 400 microm thickness under either submerged or interface conditions. Therefore the procedure described here allows the measurement of NAD(P)H autofluorescence under conditions typically required in electrophysiological experiments. Depolarization of plasma membrane caused by electrical stimulation or application of glutamate (100 microM) resulted in a characteristic initial decrease followed by a long-lasting increase in the NAD(P)H autofluorescence signal. H(2)O(2) (100 microM) evoked a strong NAD(P)H signal decrease indicating direct oxidation to the nonfluorescencend NAD(P)(+). In contrast, the increase in NAD(P)H signal that followed a brief inhibition of mitochondrial respiratory chain complex I using rotenone (1 microM) indicated an accumulation of NAD(P)H. However, in presence of rotenone (1 microM) electrically evoked long-lasting NAD(P)H signal overshoot decreased progressively, due to a negative feedback of accumulated NAD(P)H to the citrate cycle. A comparable reduction in NAD(P)H signal increase were observed during low-Mg(2+) induced epileptiform activity, indicating a relative energy failure. In conclusion, the method presented here allows to monitor NAD(P)H autofluorescence signals to gain insight into the coupling of neuronal activity, energy metabolism and mitochondrial function in brain slice models.

Modulation of intracellular calcium signaling and mitochondrial function in cultured osteoblastic cells by dexamethasone and celecoxib during mechanical stimulation.

OBJECTIVE: Evaluation of potentially therapeutically relevant effects of dexamethasone and celecoxib on crucial parameters of bone physiology during and following mechanical stimulation in cultured osteoblasts. METHODS: An in vitro mechanical stimulation model based on the rat osteogenic cell line UMR-106 was developed to investigate glucocorticoid (dexamethasone) and selective COX-2 inhibitor (celecoxib) induced changes in the intracellular calcium concentration ([Ca2+]i) and mitochondrial membrane potential (deltapsi(m)). Microfluorometric techniques were applied to monitor [Ca2+]i (Fura-2 AM) and deltapsi(m) (rhodamine 123) online as the main parameters of the actual cellular metabolism. RESULTS: Basal [Ca2+] was found to be 92.2 +/- 3.7 nM and increased tip to 711 +/- 27 nM during mechanical stimulation under controlled conditions. Addition of 100 nM dexamethasone or 10 microM celecoxib for 24 h suppressed the increase in [Ca2+]i significantly to 530 +/- 33 nM and 546 +/- 39 nM, respectively. Dexamethasone significantly reduced, but celecoxib significantly increased the spread velocity of the mechanically induced intracellular calcium wave. Furthermore, the effects induced by dexamethasone were amplified during the inhibition of gap junction coupling and diminished following enlarged gap junction coupling. In contrast, the modulation of gap junction coupling exerted only a minor influence on the celecoxib-induced effects. Short-term application of dexamethasone (5 min) caused significantly reduced mechanically induced depolarization of the mitochondrial membrane, but long-term application (24 h) did not. In contrast, only the long-term application (24 h) of celecoxib caused such depolarization. CONCLUSION: The observed effects of dexamethasone and celecoxib on mechanically induced changes in [Ca2+] and deltapsi(m) are suggested to result from short-term changes in membrane characteristics and long-term changes in protein synthesis. This indicates an influence of these drugs on cell-to-cell communication and metabolism that may be therapeutically relevant.

[Antiphospholipid syndrome 2007. Current aspects of laboratory diagnostics and their therapeutic consequences]. / Antiphospholipid-Syndrom 2007. Aktuelle Aspekte in der Labordiagnostik und deren therapeutische Konsequenzen.

Antiphospholipid syndrome (APS) is an autoimmune disorder characterized by recurrent vascular thrombosis and loss of pregnancy in association with the presence of antiphospholipid antibodies (APA) detectable as lupus anticoagulants, anticardiolipin antibodies or anti-beta2 glycoprotein I antibodies. The pathophysiological importance of APA in APS is accepted, however, the mechanisms leading to thrombosis are likely to be multifactorial and are so far unclear. Without a prior thrombosis, the risk of developing a new thrombosis in healthy patients with APA is slightly increased (<1% per year). However, the risk of a recurrent thrombosis increases considerably (>10% per year) in patients with a history of thrombosis without anticoagulation. The careful and correct identification of patients with APS is important because prophylactic anticoagulation can reduce the risk of recurrent thrombotic events, and during pregnancy can improve fetal and maternal outcome.

Diminished glutathione levels cause spontaneous and mitochondria-mediated cell death in neurons from trisomy 16 mice: a model of Down's syndrome.

It has been suggested that the increased neuronal death in cultures from trisomy 16 (Ts16) mice, a model of Down's syndrome, might result from a diminished concentration of reduced glutathione (GSH). In this study we used microfluorometric techniques to investigate the effect of GSH levels on neuronal survival in diploid and Ts16 cultures. Addition of the GSH precursors cysteine and cystine and the antioxidant tocopherol to the culture medium increased the GSH concentration up to 126.0% in diploid and up to 111.9% in Ts16 neurons. Moreover, we observed a reduced spontaneous neuronal death rate in diploid and Ts16 cultures. Following the application of 50-100 microM glutamate to culture medium, we found a GSH increase in the presence of cysteine, cystine, tocopherol, and cyclosporin A, an inhibitor of mitochondrial permeability transition (diploid, 105.8-110.8%; Ts16, 83.1-96.3%). However, only tocopherol and cyclosporin A had a protective effect on glutamate-induced neuronal death. The results suggest that reduced GSH levels affect the increase of a spontaneous and a mitochondria-mediated, cyclosporin A-sensitive type of neuronal cell death. Therefore, elevating intracellular GSH concentration may have neuroprotective effects in Down's syndrome and Alzheimer's disease.

Altered Ca2+ signaling and mitochondrial deficiencies in hippocampal neurons of trisomy 16 mice: a model of Down's syndrome.

It has been suggested that augmented nerve cell death in neurodegenerative diseases might result from an impairment of mitochondrial function. To test this hypothesis, we investigated age-dependent changes in neuronal survival and glutamate effects on Ca2+ homeostasis and mitochondrial energy metabolism in cultured hippocampal neurons from diploid and trisomy 16 (Ts16) mice, a model of Down's syndrome. Microfluorometric techniques were used to measure survival rate, [Ca2+]i level, mitochondrial membrane potential, and NAD(P)H autofluorescence. We found that Ts16 neurons die more than twice as fast as diploid neurons under otherwise identical culture conditions. Basal [Ca2+]i levels were elevated in Ts16 neurons. Moreover, in comparison to diploid neurons, Ts16 neurons showed a prolonged recovery of [Ca2+]i and mitochondrial membrane potential after brief glutamate application. Glutamate evoked an initial NAD(P)H decrease that was found to be extended in Ts16 neurons in comparison to diploid neurons. Furthermore, for all age groups tested, glutamate failed to cause a subsequent NAD(P)H overshoot in Ts16 cultures in contrast to diploid cultures. In the presence of cyclosporin A, an inhibitor of the mitochondrial membrane permeability transition, NAD(P)H increase was observed in both diploid and Ts16 neurons. The results support the hypothesis that Ca2+ impairs mitochondrial energy metabolism and may play a role in the pathogenesis of neurodegenerative changes in neurons from Ts16 mice.

A relative energy failure is associated with low-Mg2+ but not with 4-aminopyridine induced seizure-like events in entorhinal cortex.

During seizure-like events (SLEs), intracellular Ca2+ concentration ([Ca2+]i) increases causing depolarization of the mitochondrial membrane and subsequent intramitochondrial accumulation of Ca2+. Mitochondrial depolarization results in an interruption of oxidative phosphorylation and increase in reactive oxygen species. Calcium activates enzymes of the citrate cycle. A characteristic feature of the low-Mg2+-induced SLEs is that they are transformed to a late activity refractory to anticonvulsant drugs, which may be regarded as a model system of difficult to treat status epilepticus. In contrast, 4-aminopyridine (4-AP)-induced activity rarely evolves to such late activity. The autofluorescence of NAD(P)H was used to monitor changes in cellular energy metabolism in the entorhinal cortex in two in vitro models of focal epilepsy. During repetitive 4-AP-induced SLEs there was a short decrease followed by a long-lasting overshoot of the NAD(P)H signal. This sequence remained unaltered during recurring SLEs. In contrast, during recurrent low-Mg2+-induced SLEs, the brief initial NADH signal reduction was unchanged but the following overshoot of NADH displayed a continuous decrease. This indicates a relative energy failure, which may contribute to the transformation to late activity in the low-Mg2+ model.

Coupling of electrical and metabolic activity during epileptiform discharges.

Changes in electrical activity, ionic microenvironments, and intracellular Ca concentration were measured during recurrent seizures induced by low Mg in slices and slice cultures. In both preparations, initial seizure-like events (SLEs) changed after some time into drug-refractory late recurrent discharges. In slice cultures, there was considerable cell loss in all hippocampal areas after 2 h of status epilepticus. During recurrent SLEs, the NAD(P)H autofluorescence declined, as did intramitochondrial calcium signals, indicating mitochondrial damage. At the same time, ethidium signals indicated increased radical oxygen species production. These alterations could be reduced by alpha-tocopherol, which also protected slice cultures against status epilepticus-induced cell death.

Comparison of intrinsic optical signals associated with low Mg2+-and 4-aminopyridine-induced seizure-like events reveals characteristic features in adult rat limbic system.

PURPOSE: To analyze the intrinsic optical signal change associated with seizure-like events in two frequently used in vitro models-the low-Mg2+ and the 4-aminopyridine (4-AP) models-and to monitor regions of onset and spread patterns of these discharges by using imaging of intrinsic optical signals (IOS). METHODS: Combined hippocampal-entorhinal-cortex slices of adult rats were exposed to two different treatments: lowering extracellular Mg2+ concentrations or application of 100 microM 4-AP. The electrographic features of the discharges were monitored using extracellular microelectrodes. Optical imaging was achieved by infrared transillumination of the slice and analysis of changes in light transmission using a subtraction approach. The electrographic features were compared with the optical changes. Regions of onset and spread patterns were analyzed in relevant anatomic regions of the slice. RESULTS: Both lowering extracellular Mg2+ concentrations and application of 4-AP induced seizure-like events. The relative duration of the intrinsic optical signal change associated with seizure-like events in the low-Mg2+ model was significantly longer compared with that seen with those occurring in the 4-AP model, although duration of field potentials did not differ significantly in the two models. Seizure-like events of the low-Mg2+ model originated predominantly in the entorhinal cortex, with subsequent propagation toward the subiculum and neocortical structures. In contrast, no consistent region of onset or spread patterns were seen in the 4-AP model, indicating that the seizure initiation is not confined to a particular region in this model. CONCLUSIONS: We conclude that different forms of spontaneous epileptiform activity are associated with characteristic optical signal changes and that optical imaging represents an excellent method to assess regions of seizure onset and spread patterns.