Christof Schomerus

Extracellular nucleotide signaling in adult neural stem cells: synergism with growth factor-mediated cellular proliferation

We have previously shown that the extracellular nucleoside triphosphate-hydrolyzing enzyme NTPDase2 is highly expressed in situ by stem/progenitor cells of the two neurogenic regions of the adult murine brain: the subventricular zone (type B cells) and the dentate gyrus of the hippocampus (residual radial glia). We explored the possibility that adult multipotent neural stem cells express nucleotide receptors and investigated their functional properties in vitro. Neurospheres cultured from the adult mouse SVZ in the presence of epidermal growth factor and fibroblast growth factor 2 expressed the ecto-nucleotidases NTPDase2 and the tissue non-specific isoform of alkaline phosphatase, hydrolyzing extracellular ATP to adenosine. ATP, ADP and, to a lesser extent, UTP evoked rapid Ca2+ transients in neurospheres that were exclusively mediated by the metabotropic P2Y1 and P2Y2 nucleotide receptors. In addition, agonists of these receptors and low concentrations of adenosine augmented cell proliferation in the presence of growth factors. Neurosphere cell proliferation was attenuated after application of the P2Y1-receptor antagonist MRS2179 and in neurospheres from P2Y1-receptor knockout mice. In situ hybridization identified P2Y1-receptor mRNA in clusters of SVZ cells. Our results infer nucleotide receptor-mediated synergism that augments growth factor-mediated cell proliferation. Together with the in situ data, this supports the notion that extracellular nucleotides contribute to the control of adult neurogenesis.

Selective adrenergic/cyclic AMP-dependent switch-off of proteasomal proteolysis alone switches on neural signal transduction: an example from the pineal gland.

Abstract: The molecular processes underlying neural transmission are central issues in neurobiology. Here we describe a novel mechanism through which noradrenaline (NA) activates its target cells, using the mammalian pineal organ as a model. In this neuroendocrine transducer, NA stimulates arylalkylamine N‐acetyltransferase (AANAT; EC 2.3.1.87), the key enzyme regulating the nocturnal melatonin production. In rodents, AANAT protein accumulates as a result of enhanced transcription, but in primates and ungulates, the AANAT mRNA level fluctuates only marginally, indicating that other mechanisms regulate AANAT protein and activity. These were investigated in cultured bovine pinealocytes. AANAT mRNA was readily detectable in unstimulated pinealocytes, and levels did not change following NA treatment. In contrast, NA increased AANAT protein levels in parallel with AANAT activity, apparently through a cyclic AMP‐mediated mechanism. Immunocytochemistry revealed that the changes in AANAT protein levels occurred in virtually all pinealocytes. Inhibition of AANAT degradation by proteasomal proteolysis alone was found to switch‐on enzyme activity by increasing AANAT protein levels five‐ to 10‐fold. Accordingly, under unstimulated conditions AANAT protein is continually synthesized and immediately destroyed by proteasomal proteolysis. NA appears to act via cyclic AMP to protect AANAT from proteolytic destruction, resulting in accumulation of the protein. These findings show that tightly regulated control of proteasomal proteolysis of a specific protein alone can play a pivotal role in neural regulation.

Mechanisms Regulating Melatonin Synthesis in the Mammalian Pineal Organ

The day/night rhythm in melatonin production is a characteristic feature in vertebrate physiology. This hormonal signal reliably reflects the environmental light conditions and is independent of behavioral aspects. In all mammalian species, melatonin production is regulated by norepinephrine, which is released from sympathetic nerve fibers exclusively at night. Norepinephrine elevates the intracellular cAMP concentration via β‐adrenergic receptors and activates the cAMP‐dependent protein kinase A. This pathway is crucial for regulation of the penultimate enzyme in melatonin biosynthesis, the arylalkylamine N‐acetyltransferase (AANAT); cAMP/protein kinase A may, however, act in different ways. In ungulates and primates, pinealocytes constantly synthesize AANAT protein from continually available Aanat mRNA. During the day—in the absence of noradrenergic stimulation—the protein is immediately destroyed by proteasomal proteolysis. At nighttime, elevated cAMP levels cause phosphorylation of AANAT by protein kinase A. This posttranslational modification leads to interaction of phosphorylated AANAT with regulatory 14–3–3 proteins, which protect AANAT from degradation. Increases in AANAT protein are paralleled by increases in enzyme activity. Stimulation of the cAMP/protein kinase A pathway may also activate pineal gene expression. In rodents, transcriptional activation of the Aanat gene is the primary mechanism for the induction of melatonin biosynthesis and results in marked day/night fluctuations in Aanat mRNA. It involves protein kinase A‐dependent phosphorylation of the transcription factor cyclic AMP response element‐binding protein (CREB) and binding of phosphorylated CREB in the promoter region of the Aanat gene. In conclusion, a common neuroendocrine principle, the nocturnal rise in melatonin, is controlled by strikingly diverse regulatory mechanisms. This diversity has emerged in the course of evolution and reflects the high adaptive plasticity of the melatonin‐generating pineal organ.

Of Rodents and Ungulates and Melatonin: Creating a Uniform Code for Darkness by Different Signaling Mechanisms

Melatonin synthesis in the mammalian pineal gland is one of the best investigated output pathways of the circadian clock because it can be readily measured and is tightly regulated by a clearly defined input, the neurotransmitter norepinephrine. In this system, a regulatory scenario was deciphered that is centered around the cyclic AMP pathway but shows peculiar species-specific differences. In rodents, the cyclic AMP–mediated, temporally sequential up-regulation of two transcription factors, the activator CREB (cyclic AMP–responsive elementbinding protein) and the inhibitor ICER (inducible cyclic AMP–dependent early repressor), is the core mechanism to determine rhythmic accumulation of the mRNA encoding for the rate-limiting enzyme in melatonin synthesis, the arylalkylamine N-acetyltransferase (AA-NAT). Thus, in rodents, the regulation of melatonin synthesis bears an essential transcriptional component, which, however, is flanked by posttranscriptional mechanisms. In contrast, in ungulates, and possibly also in primates, AA-NAT appears to be regulated exclusively on the posttranscriptional level. Here, increasing cyclic AMP levels inhibit the breakdown of constitutively synthesized AA-NAT protein by proteasomal proteolysis, leading to an elevated enzyme activity. Thus, self-restriction of cellular responses, as a reaction to external cues, is accomplished by different mechanisms in pinealocytes of different mammalian species. In such a temporally gated cellular adaptation, transcriptionally active products of clock genes may play a supplementary role. Their recent detection in the endogenously oscillating nonmammalian pineal organ and, notably, also in the slave oscillator of the mammalian pineal gland underlines that the mammalian pineal gland will continue to serve as an excellent model system to understand mechanisms of biological timing.

Transcription factor dynamics and neuroendocrine signalling in the mouse pineal gland: a comparative analysis of melatonin-deficient C57BL mice and melatonin-proficient C3H mice

In rodents, the nocturnal rise and fall of arylalkylamine N‐acetyltransferase (AANAT) activity controls the rhythmic synthesis of melatonin, the hormone of the pineal gland. This rhythm involves the transcriptional regulation of the AANAT by two norepinephrine (NE)‐inducible transcription factors, e.g. the activator pCREB (phosphorylated Ca2+/cAMP‐response element binding protein) and the inhibitor ICER (inducible cAMP early repressor). Most inbred mouse strains do not produce melatonin under standard laboratory light/dark conditions. As melatonin‐deficient mice are often the founders for transgenic animals used for chronobiological experimentations, molecular components of neuroendocrine signalling in the pineal gland as an integral part of clock entrainment mechanisms have to be deciphered. We therefore compared calcium signalling, transcriptional events and melatonin synthesis in the melatonin‐deficient C57BL mouse and the melatonin‐proficient C3H mouse. Pineal glands and primary pinealocytes were cultured and stimulated with NE or were collected at various times of the light/dark (LD) cycle. Changes in intracellular calcium concentrations, the phosphorylation of CREB, and ICER protein levels follow similar dynamics in the pineal glands of both mouse strains. pCREB levels are high during the early night and ICER protein shows elevated levels during the late night. In the C57BL pineal gland, a low but significant increase in melatonin synthesis could be observed upon NE stimulation, and, notably, also when animals were exposed to long nights. We conclude that the commonly used C57BL mouse is not completely melatonin‐deficient and that this melatonin‐deficiency does not affect molecular details involved in regulating transcriptional events of melatonin synthesis.

Calcium responses of isolated, immunocytochemically identified rat pinealocytes to noradrenergic, cholinergic and vasopressinergic stimulations☆

Calcium responses of isolated rat pineal cells to noradrenergic, cholinergic and vasopressinergic stimulations were recorded by use of the fura-2 technique and an image analysis system. Subsequently the recorded cells were identified as pinealocytes by immunocytochemical demonstration of S-antigen, a pinealocyte-specific marker. S-antigen immunoreactive pinealocytes were shown to respond to norepinephrine stimulation with an elevation of the intracellular free calcium concentration ([Ca2+]i). This response was dose-dependent and consisted of a rapid increase in [Ca2+]i (primary phase) followed by a decrease to an elevated plateau well above the basal level (secondary phase). The plateau persisted for at least 1 h when cells were constantly exposed to norepinephrine and dropped to basal level upon removal of the stimulus. Analysis of the calcium responses of cells treated with caffeine or thapsigargin suggested that the primary phase reflects mobilization of calcium from inositol 1,4,5-trisphosphate-sensitive intracellular calcium stores. Depletion of these calcium stores was a decisive and sufficient prerequisite to evoke the secondary phase which was apparently elicited by calcium influx. These data suggest that a capacitative calcium entry is involved in pineal calcium signalling. Acetylcholine induced an increase in [Ca2+]i in rat pinealocytes. Experiments with different cholinergic agonists and antagonists provided evidence that the acetylcholine-induced calcium response was mediated via nicotinic acetylcholine receptors. Stimulation of isolated rat pineal cells with arginine-vasopressin caused a rise in [Ca2+]i in approx. 5% of the cells. However, these cells remained unidentified because they contained neither immunoreactive S-antigen nor immunoreactive glial fibrillary acidic protein, a marker for interstitial (glial) cells of the rat pineal organ. Taken together, the results underline the pivotal role of norepinephrine for the regulation of pineal signal transduction, but they also support the notion that other neurotransmitters and neuropeptides are involved in the modulation of pineal calcium signalling.

Norepinephrine-induced phosphorylation of the transcription factor CREB in isolated rat pinealocytes: an immunocytochemical study

In the present study we investigated whether norepinephrine, which stimulates melatonin biosynthesis in the mammalian pineal organ, causes phosphorylation of the cyclic AMP responsive element binding protein (CREB) in rat pinealocytes. Cells isolated from the pineal organ of adult male rats and cultured on coated coverslips were treated with norepinephrine, β- or α1 agonists for 1, 5, 10, 20, 30, 60 or 300 min and then immunocytochemically analyzed with an antibody against phosphorylated CREB (p-CREB). Treatment with norepinephrine or β-adrenergic agonists resulted in a similar, time-dependent induction of p-CREB immunoreactivity, exclusively found in cell nuclei. The α1 agonist phenylephrine did not induce p-CREB immunoreactivity at low doses (0.1 μM) or when high doses (10 μM) were applied in combination with a β-antagonist (propranolol, 0.1 μM). This indicates that induction of CREB phosphorylation is elicited by β-adrenergic receptor stimulation. The response was first seen after 10 min and reached a maximum after 30 to 60 min when more than 90% of the cells displayed p-CREB immunoreactivity. The intensity of the p-CREB immunoreactivity showed marked cell-to-cell variation, but nearly all immunoreactive cells were identified as pinealocytes by double-labeling with an antibody against the S-antigen, a pinealocyte-specific marker. The results show that norepinephrine stimulation induces p-CREB immunoreactivity by acting upon β-adrenergic receptors in virtually all rat pinealocytes. The findings support the notion that phosphorylation of CREB is a rather rapid and uniform response of pinealocytes to noradrenergic stimulation and thus is an important link between adrenoreceptor activation and subsequent gene expression in the rat pineal organ.

Vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating polypeptide (PACAP) induce phosphorylation of the transcription factor CREB in subpopulations of rat pinealocytes: immunocytochemical and immunochemical evidence.

Abstract.We investigated whether vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating polypeptide (PACAP), which stimulate melatonin biosynthesis in the mammalian pineal organ, cause phosphorylation of the cyclic AMP response element binding protein (CREB) in rat pinealocytes. Dispersed cells were treated with varying concentrations of VIP and PACAP for 10 to up to 240 min and then immunocytochemically analyzed with an antibody against phosphorylated CREB (pCREB). The experiments showed a dose- and time-dependent induction of pCREB immunoreactivity in the nuclei of subpopulations of pinealocytes identified by the S-antigen immunoreaction. Stimulation with VIP elicited pCREB immunoreaction in approximately 50–65% of the S-antigen immunoreactive pinealocytes. The number of PACAP-responsive pinealocytes was often smaller and more variable. Maximal responses to both neuropeptides were seen after 30 min. pCREB immunoreaction gradually declined within 2 h and could not be induced again by an additional stimulation. In contrast, norepinephrine (NE) elicited pCREB immunoreaction in more than 95% of the pinealocytes, and this response lasted as long as 300 min. Treatment of pinealocytes with forskolin or KCl induced pCREB immunoreaction in the vast majority of pinealocytes, showing that in principle elevation of the intracellular concentrations of both cAMP and calcium can cause the response. Immunoblotting analyses confirmed that the immunoreaction elicited by VIP, PACAP and NE is largely due to phosphorylation of a 42-kDa protein corresponding to CREB, but reflects to a minor extent also phosphorylation of two smaller proteins presumably related to ATF-1. Immunocytochemical and immunochemical investigations with an antibody against total CREB showed that stimulation with VIP, PACAP and NE did not affect the level of CREB. All findings indicate that the stimulatory effects of VIP and PACAP on rat pinealocytes involve phosphorylation of transcription factors of the CREB family as holds also true for NE. However, VIP and PACAP affected only subpopulations of pinealocytes and the reponses lasted for a shorter period of time than those to NE. This conforms to previous results showing that both neuropeptides are also less effective than NE in stimulating the melatonin biosynthesis in the rat pineal organ.

Stimulation of a nicotinic ACh receptor causes depolarization and activation of L‐type Ca2+ channels in rat pinealocytes.

1. Membrane voltage (Vm) recordings were obtained from isolated rat pinealocytes using the patch‐clamp technique. In parallel to the electrophysiological experiments, intracellular Ca2+ measurements were performed using fura‐2. 2. The resting Vm averaged ‐43 mV and replacement of extracellular NaCl by KCl completely depolarized the cells. This indicates that the resting Vm is dominated by a K+ conductance. Single‐channel recordings revealed the presence of a large conductance Ca(2+)‐activated charybdotoxin‐sensitive K+ channel. 3. Application of ACh (100 microM) depolarized the pinealocytes on average by 16 mV. The depolarizing effect of ACh was mimicked by nicotine (50 microM) and was prevented by tubocurarine (100 microM). 4. The ACh‐induced depolarization was largely abolished in the absence of extracellular Na+, but was not significantly affected by extracellular Ca2+ removal. 5. Application of ACh (100 microM) caused an increase in [Ca2+]i. This increase was completely dependent on the presence of extracellular Ca2+ and was largely reduced after extracellular Na+ removal. Nifedipine (1 microM) reduced the ACh‐induced increase in [Ca2+]i by about 50%. 6. Our findings indicate that in rat pinealocytes stimulation of a nicotinic ACh receptor (nAChR) induces depolarization mainly by Na+ influx via the nAChR. The depolarization then activates L‐type Ca2+ channels, which are responsible for the nifedipine‐sensitive portion of the intracellular Ca2+ increase. Ca2+ influx via the nAChR probably also contributes to the observed rise in [Ca2+]i.

Signal transduction molecules in the rat pineal organ: Ca2+, pCREB, and ICER.

The mammalian pineal organ transduces light-dependent neural inputs into a hormonal output. This photoneuroendocrine transduction results in a largely elevated concentration of the pineal hormone melatonin at night. The rhythm in melatonin production and secretion depends on activation and inactivation of transcriptional, translational, and posttranslational mechanisms fundamentally linked to two second messenger systems, the cAMP- and the Ca(2+)-signal transduction pathways. Here we review molecular biological, immunocytochemical, and single-cell imaging studies, which demonstrate a time- and substance-specific activation of these signaling pathways in rat pinealocytes. The data provide a framework for understanding the complex interactions between second messengers (cAMP, Ca2+), transcription factors (CREB, ICER), and their role in regulation of melatonin synthesis. The data have proven the rat pinealocyte to be an interesting model to study transmembrane signaling pathways which may be common to both neuroendocrine and neuronal cells.