Michael Hans

Glial cells are born with synapses

In postnatal rodent brain, certain NG2‐expressing oligodendroglial precursor cells (OPCs) are contacted by synaptic terminals from local neurons. However, it has remained elusive whether and when NG2+ cells are integrated into neuronal circuits. Here we use patch‐clamp recordings from mitotic cells in murine brain slices to show that, unlike any other cell in the central nervous system (CNS), cortical NG2+ cells divide and relocate while being linked to synaptic junctions. Together with bromodeoxyuridine (BrdU) labeling, our recordings imply that cellular processes that bear synaptic junctions are surprisingly kept during cytokinesis and are inherited by the daughter cells. Cell cycle time (78 h) and relocation speed (5 μm/day) are slowed, and NG2+ cells largely divide symmetrically. Inheritance of synapses enables newborn glial cells to establish synaptic connections much faster than newborn neurons and ensures that the entire population of NG2+ cells is exposed to synaptic signals from local axons. The results suggest that synapses do not only transmit neuronal activity but also act as environmental cues for the development of glial cells. Inheritance of synapses allows for the direct transfer of environmental interactions to clonal descendants of OPCs, which might be important for effective colonization and myelination of the developing brain.—Kukley, M., Kiladze, M., Tognatta, R., Hans, M., Swandulla, D., Schramm, J., Dietrich, D. Glial cells are born with synapses. FASEB J. 22, 2957–2969 (2008)

Hyperpolarizing inhibition develops without trophic support by GABA in cultured rat midbrain neurons

During a limited period of early neuronal development, GABA is depolarizing and elevates [Ca2+]i, which mediates the trophic action of GABA in neuronal maturation. We tested the attractive hypothesis that GABA itself promotes the developmental change of its response from depolarizing to hyperpolarizing ( Ganguly et al. 2001 ). In cultured midbrain neurons we found that the GABA response changed from depolarizing to hyperpolarizing, although GABAA receptors had been blocked throughout development. In immature neurons prolonged exposure of the cells to nanomolar concentrations of GABA or brief repetitive applications of GABA strongly diminished the elevation of [Ca2+]i by GABA. As revealed by gramicidin perforated‐patch recording, reduced [Ca2+]i responses were due to a diminished driving force for Cl−. This suggests that immature neurons do not have an efficient inward transport that can compensate the loss of cytosolic Cl− resulting from sustained GABAA receptor activation by ambient GABA. Transient increases in external K+, which can induce voltage‐dependent Cl− entry, restored GABA‐induced [Ca2+]i elevations. In mature neurons, GABA reduced [Ca2+]i provided that background [Ca2+]i was elevated by the application of an L‐type Ca2+ channel agonist. This was probably due to a hyperpolarization of the membrane by Cl− currents. K+‐Cl− cotransport maintained the gradient for hyperpolarizing Cl− currents. We conclude that in immature midbrain neurons an inward Cl− transport is not effective although the GABA response is depolarizing. Further, GABA itself is not required for the developmental switch of GABAergic responses from depolarizing to hyperpolarizing in cultured midbrain neurons.

Sphingosine-1-phosphate links glycosphingolipid metabolism to neurodegeneration via a calpain-mediated mechanism.

We have recently reported that the bioactive lipid sphingosine-1-phosphate (S1P), usually signaling proliferation and anti-apoptosis induces neuronal death when generated by sphingosine-kinase2 and when accumulation due to S1P-lyase deficiency occurs. In the present study, we identify the signaling cascade involved in the neurotoxic effect of sphingoid-base phosphates. We demonstrate that the calcium-dependent cysteine protease calpain mediates neurotoxicity by induction of the endoplasmic reticulum stress-specific caspase cascade and activation of cyclin-dependent kinase5 (CDK5). The latter is involved in an abortive reactivation of the cell cycle and also enhances tau phosphorylation. Neuroanatomical studies in the cerebellum document for the first time that indeed neurons with abundant S1P-lyase expression are those, which degenerate first in S1P-lyase-deficient mice. We therefore propose that an impaired metabolism of glycosphingolipids, which are prevalent in the central nervous system, might be linked via S1P, their common catabolic intermediate, to neuronal death.

Bisphenol A inhibits voltage-activated Ca 2+ channels in vitro: mechanisms and structural requirements

Bisphenol A (BPA), a high volume production chemical compound attracts growing attention as a health-relevant xenobiotic in humans. It can directly bind to hormone receptors, enzymes, and ion channels to become biologically active. In this study we show that BPA acts as a potent blocker of voltage-activated Ca2+ channels. We determined the mechanisms of block and the structural elements of BPA essential for its action. Macroscopic Ba2+/ Ca2+ currents through native L-, N-, P/Q-, T-type Ca2+ channels in rat endocrine GH3 cells, mouse dorsal root ganglion neurons or cardiac myocytes, and recombinant human R-type Ca2+ channels expressed in human embryonic kidney (HEK) 293 cells were rapidly and reversibly inhibited by BPA with similar potency (EC50 values: 26–35 μM). Pharmacological and biophysical analysis of R-type Ca2+ channels revealed that BPA interacts with the extracellular part of the channel protein. Its action does not require intracellular signaling pathways, is neither voltage- nor use-dependent, and does not affect channel gating. This indicates that BPA interacts with the channel in its resting state by directly binding to an external site outside the pore-forming region. Structure-effect analyses of various phenolic and bisphenolic compounds revealed that 1) a double-alkylated (R-C(CH3)2-R, R-C(CH3)(CH2CH3)-R), or double-trifluoromethylated sp3-hybridized carbon atom between the two aromatic rings and 2) the two aromatic moieties in angulated orientation are optimal for BPA’s effectiveness. Since BPA highly pollutes the environment and is incorporated into the human organism, our data may provide a basis for future studies relevant for human health and development.

Modulation of voltage-dependent sodium channels by the (δ-agonist SNC80 in acutely isolated rat hippocampal neurons

Following activation, voltage-gated Na+ currents (I(Na)) inactivate on two different time scales: fast inactivation takes place on a time scale of milliseconds, while slow inactivation takes place on a time scale of seconds to minutes. Both fast and slow inactivation processes govern availability of Na+ channels. In this study, the effects of the delta-opioid receptor agonist SNC80 on slow and fast inactivation of I(Na) in rat hippocampal granule cells were analyzed in detail. Following application of SNC80, a block of the peak Na+ current amplitude (EC50: 50.6 microM, Hill coefficient: 0.518) was observed. Intriguingly, SNC80 (50 microM) also caused a selective effect on slow but not fast inactivation processes, with a notable increase in the fraction of Na+ channels undergoing slow inactivation during prolonged depolarization. In addition, recovery from slow inactivation was considerably slowed. At the same time, fast recovery processes were unaffected. The effects of SNC80 were not mimicked by the peptide delta-receptor agonist DPDPE (10 microM), and were not inhibited by the opioid receptor antagonists naloxone (50-300 microM) or naltrindole (10 and 100 microM), indicating an opioid receptor independent modulation of Na+ channels. These data suggest that SNC80 not only affects delta-opioid receptors, but also voltage-gated Na+ channels. SNC80 is to our knowledge hitherto the only substance that selectively influences slow but not fast inactivation processes and could provide an important tool in unraveling the mechanism underlying these distinct biophysical processes.

CD44 and hyaluronan promote invasive growth of B35 neuroblastoma cells into the brain.

Hyaluronan and its receptor CD44 are known to contribute to the invasive growth of different tumors of the central nervous system. It is not known, however, if CD44 is sufficient to activate invasive growth into the brain tissue. This study examines how CD44 regulates the motility and invasive growth of B35 neuroblastoma cells into a hyaluronan-rich environment. A comprehensive experimental approach was used encompassing biochemical techniques, single molecule microscopy, correlative confocal and scanning electron microscopy, morphometry of cellular extensions, live-cell imaging and tracking, transplantation onto organotypic brain slices, two-photon imaging and invasion assays. We found that CD44-GFP fusion protein was localized in filopodia and in focal bleb-like protrusions where it provided binding sites for hyaluronan. Transient expression of CD44-GFP was sufficient to increase the length of filopodia, to enhance cell migration and to promote invasive growth into hyaluronan-rich brain tissue. Thus, CD44 controls molecular devices localized in filopodia and bleb-like specializations of the cell surface that enhance cell migration and invasive growth.

The dermomyotome ventrolateral lip is essential for the hypaxial myotome formation.

BackgroundThe myotome is the primitive skeletal muscle that forms within the embryonic metameric body wall. It can be subdivided into an epaxial and hypaxial domain. It has been shown that the formation of the epaxial myotome requires the dorsomedial lip of the dermomyotome (DML). Although the ventrolateral lip (VLL) of the dermomyotome is believed to be required for the formation of the hypaxial myotome, experimentally evidence for this statement still needs to be provided. Provision of such data would enable the resolution of a debate regarding the formation of the hypaxial dermomyotome. Two mechanisms have been proposed for this tissue. The first proposes that the intermediate dermomyotome undergoes cellular expansion thereby pushing the ventral lateral lip in a lateral direction (translocation). In contrast, the alternative view holds that the ventral lateral lip grows laterally.ResultsUsing time lapse confocal microscopy, we observed that the GFP-labelled ventrolateral lip (VLL) of the dermomyotome grows rather than translocates in a lateral direction. The necessity of the VLL for lateral extension of the myotome was addressed by ablation studies. We found that the hypaxial myotome did not form after VLL ablation. In contrast, the removal of an intermediate portion of the dermomyotome had very little effect of the hypaxial myotome. These results demonstrate that the VLL is required for the formation of the hypaxial myotome.ConclusionOur study demonstrates that the dermomyotome ventrolateral lip is essential for the hypaxial myotome formation and supports the lip extension model. Therefore, despite being under independent signalling controls, both the dorsomedial and ventrolateral lip fulfil the same function, i.e. they extend into adjacent regions permitting the growth of the myotome.

Nanomolar ambient ATP decelerates P2X3 receptor kinetics.

Homomeric P2X receptors differ in their electrophysiological and pharmacological profiles. The rapidly activating and desensitizing P2X3 receptors are known for their involvement in pain signalling pathways. Modulatory effects on P2X3 receptors have been reported for low concentrations of ATP ([ATP]). This includes both, enhancement and reduction of receptor currents. The first has been reported to be mediated by activation of ectoprotein kinases and high affinity desensitization (HAD), respectively. Both processes influence receptor current amplitudes. Here we describe a new phenomenon, the modulatory influence of ambient low [ATP] on P2X3 receptor kinetics. First, we studied in HEK cells whether persistent ATP affects current decay. To this end, P2X3 receptor mediated currents, elicited by pressure application of saturating [ATP], were analyzed after pre-application of low [ATP]. Second, UV-flash photolysis of ATP was employed to investigate whether submicromolar [ATP] affects receptor activation. Finally we confirmed the action of nanomolar [ATP] on native P2X3 receptors of neurons freshly isolated from rat dorsal root ganglia. We found that persistent low [ATP] caused pronounced deceleration of receptor current activation and decay. This priming effect indicates a mechanism different from HAD. It could be explained by a pre-opening receptor isomerization, induced by the occupation of a high affinity binding site already at the resting state. The observed modulation of the receptor kinetics could be considered as a physiological fine tuning mechanism of the nociceptive system, driven by the actual ambient agonist concentration.

Sphingosine 1-phosphate lyase ablation disrupts presynaptic architecture and function via an ubiquitin- proteasome mediated mechanism

The bioactive lipid sphingosine 1-phosphate (S1P) is a degradation product of sphingolipids that are particularly abundant in neurons. We have shown previously that neuronal S1P accumulation is toxic leading to ER-stress and an increase in intracellular calcium. To clarify the neuronal function of S1P, we generated brain-specific knockout mouse models in which S1P-lyase (SPL), the enzyme responsible for irreversible S1P cleavage was inactivated. Constitutive ablation of SPL in the brain (SPLfl/fl/Nes) but not postnatal neuronal forebrain-restricted SPL deletion (SPLfl/fl/CaMK) caused marked accumulation of S1P. Hence, altered presynaptic architecture including a significant decrease in number and density of synaptic vesicles, decreased expression of several presynaptic proteins, and impaired synaptic short term plasticity were observed in hippocampal neurons from SPLfl/fl/Nes mice. Accordingly, these mice displayed cognitive deficits. At the molecular level, an activation of the ubiquitin-proteasome system (UPS) was detected which resulted in a decreased expression of the deubiquitinating enzyme USP14 and several presynaptic proteins. Upon inhibition of proteasomal activity, USP14 levels, expression of presynaptic proteins and synaptic function were restored. These findings identify S1P metabolism as a novel player in modulating synaptic architecture and plasticity.

Correction: The dermomyotome ventrolateral lip is essential for the hypaxial myotome formation

Some spelling errors were discovered following the publication of this work [1]. The correct spelling of one of authors name is Dr. Dieter Swandulla and not Dr. Dieter Schwandulla. Accordingly his correct e-mail address is Dieter.Swandulla@ukb.uni-bonn.de. The correct spelling of the University of Bonn is Rheinische Friedrich-Wilhelms-University of Bonn. We apologise for any inconvenience this may have caused.