Rainer Spessert

Diabetic Goto Kakizaki rats as well as type 2 diabetic patients show a decreased diurnal serum melatonin level and an increased pancreatic melatonin-receptor status.

Abstract:  There are functional inter‐relationships between the beta cells of the endocrine pancreas and the pineal gland, where the synchronizing circadian molecule melatonin originates. The aim of this study was to elucidate a putative interaction between insulin and melatonin in diabetic patients and a diabetic rat model. We analyzed glucose, insulin, and melatonin levels of type 2 patients, as well as type 2 diabetic Goto Kakizaki (GK) rats by radioimmunoassay. Expression of pancreatic melatonin and pineal insulin receptors, as well as arylalkylamine‐N‐acetyltransferase (AANAT), was determined by real‐time reverse transcriptase polymerase chain reaction (RT‐PCR). The AANAT enzyme activity was measured in pineal homogenates. Diabetic patients showed a decrease in melatonin levels, while in the pancreas of GK rats an upregulation of the melatonin‐receptor mRNA was determined. The pancreatic islets of GK rats showed expression of the mRNA for the pancreatic melatonin (MT1) receptor, which had previously been identified in rats and insulinoma (INS1) cells. Besides their presence in animal cells, the MT1‐receptor transcript was also detected in human pancreas by RT‐PCR. Whereas the rat pancreatic mRNA expression of the MT1‐receptor was significantly increased, the activity of the pineal AANAT enzyme was reduced. The latter observation was in accordance with plasma melatonin levels. The insulin‐receptor mRNA of the pineal gland was found to be reduced in GK rats. Our observations suggest a functional inter‐relationship between melatonin and insulin, and may indicate a reduction of melatonin in the genesis of diabetes.

Proper synaptic vesicle formation and neuronal network activity critically rely on syndapin I.

Synaptic transmission relies on effective and accurate compensatory endocytosis. F‐BAR proteins may serve as membrane curvature sensors and/or inducers and thereby support membrane remodelling processes; yet, their in vivo functions urgently await disclosure. We demonstrate that the F‐BAR protein syndapin I is crucial for proper brain function. Syndapin I knockout (KO) mice suffer from seizures, a phenotype consistent with excessive hippocampal network activity. Loss of syndapin I causes defects in presynaptic membrane trafficking processes, which are especially evident under high‐capacity retrieval conditions, accumulation of endocytic intermediates, loss of synaptic vesicle (SV) size control, impaired activity‐dependent SV retrieval and defective synaptic activity. Detailed molecular analyses demonstrate that syndapin I plays an important role in the recruitment of all dynamin isoforms, central players in vesicle fission reactions, to the membrane. Consistently, syndapin I KO mice share phenotypes with dynamin I KO mice, whereas their seizure phenotype is very reminiscent of fitful mice expressing a mutant dynamin. Thus, syndapin I acts as pivotal membrane anchoring factor for dynamins during regeneration of SVs.

Nitric oxide synthase in the hypothalamic suprachiasmatic nucleus of rat: evidence from histochemistry, immunohistochemistry and Western blot; and colocalization with VIP

Nitric oxide (NO) is a neuroactive substance of high potency. Physiological results revealed the involvement of NO in circadian regulation of rats. Since neuronal structures containing NO-synthase (NOS) were previously not found in the circadian oscillator, the hypothalamic suprachiasmatic nucleus (SCN), in this species but are present in the hamster, we investigated the distribution of NO-producing structures in the rat SCN by Western blot analysis, immunohistochemistry of NOS, and by histochemistry (NADPH-diaphorase (NADPH-d) activity of NOS). Western blot analysis of SCN homogenates from rat (and, for comparison, hamster) showed a NOS-like immunoreactive (-LI) protein band of apparent molecular mass of 150 kDa, consistent with the neuronal NOS molecule. In the rat SCN, perikarya exhibiting NADPH-d staining of NOS-LI with a complete overlapping of both were found. Double-immunofluorescence experiments revealed that NOS cells are a subgroup of the neuronal SCN population that is characterized by immunoreactivity to vasoactive intestinal polypeptide. These data provide evidence for the existence of neuronal nitric oxide synthase in the rat SCN and may explain the involvement of NO in the mediation of photic information.

Adrenergic Stimulation of Cyclic GMP Formation Requires NO‐Dependent Activation of Cytosolic Guanylate Cyclase in Rat Pinealocytes

Abstract: Cyclic GMP (cGMP) formation in rat pinealocytes is regulated through a synergistic dual receptor mechanism involving β‐and α1‐adrenergic receptors. The effects of N‐monomethyl‐l‐arginine (NMMA), which inhibits nitric oxide (NO) synthase and NO‐mediated activation of cytosolic guanylate cyclase, and methylene blue (MB), which inhibits cytosolic guanylate cyclase, were investigated in an attempt to understand the role of NO in adrenergic cGMP formation. Both NMMA and MB inhibited β‐adrenergic stimulation of cGMP formation as well as α1‐adrenergic potentiation of β‐adrenergic stimulation of cGMP formation, whereas they had no effect in unstimulated pinealocytes. The inhibitory action of NMMA was antagonized by addition of l‐arginine. On the basis of these findings it can be concluded that the adrenergic stimulation of cGMP formation involves NO synthesis followed by activation of cytosolic guanylate cyclase.

Involvement of cyclic guanosine monophosphosphate (cGMP) and cytosolic guanylate cyclase in the regulation of synaptic ribbon numbers in rat pineal gland

In the rat pineal gland N-acetyltransferase (NAT) activity and synaptic ribbon (SR) numbers display a circadian rhythm. It is well-known that NAT activity is regulated by adrenergic mechanisms involving cyclic adenosine monophosphate (cAMP) as a second messenger. However, the mechanism involved in the regulation of SR numbers has not been established so far. In the present in vitro study, we have investigated the effects of 8-bromo-cyclic guanosine monophosphate (8-bromo-cGMP), a cyclic guanosine monophosphate (cGMP) analog, and stimulation of guanylate cyclase on SR numbers. Incubation with 8-bromo-cGMP increased SR numbers in a dose- and time-dependent manner. Further, stimulation of the cytosolic guanylate cyclase also resulted in increased SR numbers. Adrenergic agonists stimulated cGMP but did not alter SR numbers. These findings suggest that cGMP is involved as a second messenger in the regulation of SR numbers. Since the adrenergically stimulated increase in cGMP did not influence SR numbers, a non-adrenergic cGMP metabolic pathway seems to be involved in the regulation of SR numbers in the rat pineal gland.

Daily oscillation of gene expression in the retina is phase-advanced with respect to the pineal gland.

The photoreceptive retina and the non-photoreceptive pineal gland are components of the circadian and the melatonin forming system in mammals. To contribute to our understanding of the functional integrity of the circadian system and the melatonin forming system we have compared the daily oscillation of the two tissues under various seasonal lighting conditions. For this purpose, the 24-h profiles of the expression of the genes coding for arylalkylamine N-acetyltransferase (AA-NAT), nerve growth factor inducible gene-A (NGFI-A), nerve growth factor inducible gene-B (NGFI-B), retinoic acid related orphan receptor beta (RORbeta), dopamine D4 receptor, and period2 (Per2) have been simultaneously recorded in the retina and the pineal gland of rats under short day (light/dark 8:16) and long day (light/dark 16:8) conditions. We have found that the cyclical patterns of all genes are phase-advanced in the retina, often with a lengthened temporal interval under short day conditions. In both tissues, the AA-NAT gene expression represents an indication of the output of the relevant pacemakers. The temporal phasing in the AA-NAT transcript amount between the retina and the pineal gland is retained under constant darkness suggesting that the intrinsic self-cycling clock of the retina oscillates in a phase-advanced manner with respect to the self-cycling clock in the suprachiasmatic nucleus, which controls the pineal gland. We therefore conclude that daily rhythms in gene expression in the retina are phase-advanced with respect to the pineal gland, and that the same temporal relationship appears to be valid for the self-cycling clocks influencing the tissues.

Melatonin Signaling Modulates Clock Genes Expression in the Mouse Retina

Previous studies have shown that retinal melatonin plays an important role in the regulation of retinal daily and circadian rhythms. Melatonin exerts its influence by binding to G-protein coupled receptors named melatonin receptor type 1 and type 2 and both receptors are present in the mouse retina. Earlier studies have shown that clock genes are rhythmically expressed in the mouse retina and melatonin signaling may be implicated in the modulation of clock gene expression in this tissue. In this study we determined the daily and circadian expression patterns of Per1, Per2, Bmal1, Dbp, Nampt and c-fos in the retina and in the photoreceptor layer (using laser capture microdissection) in C3H-f+/+ and in melatonin receptors of knockout (MT1 and MT2) of the same genetic background using real-time quantitative RT-PCR. Our data indicated that clock and clock-controlled genes are rhythmically expressed in the retina and in the photoreceptor layer. Removal of melatonin signaling significantly affected the pattern of expression in the retina whereas in the photoreceptor layer only the Bmal1 circadian pattern of expression was affected by melatonin signaling removal. In conclusion, our data further support the notion that melatonin signaling may be important for the regulation of clock gene expression in the inner or ganglion cells layer, but not in photoreceptors.

Daily Profile in Melanopsin Transcripts Depends on Seasonal Lighting Conditions in the Rat Retina

The retinal photopigment melanopsin (Opn4) mediates photoentrainment of the circadian system. In the present study, seasonal regulation of the melanopsin gene was investigated in comparison with the arylalkylamine N‐acetyltransferase (AA‐NAT) gene as an indicator of retinal pacemaker output. For this purpose, the daily profiles in the amount of melanopsin mRNA and AA‐NAT mRNA were monitored under 8 : 16 h light/dark, 12 : 12 h light/dark and 16 : 8 h light/dark photoperiods using real‐time polymerase chain reaction analysis. We found that, under all of the lighting regimes, melanopsin and AA‐NAT expression oscillated with a peak around dark onset and the middle of the dark phase, respectively. The lighting regime influenced both genes, but in an opposing manner. Under long photoperiods, the duration of peak expression was prolonged for melanopsin, whereas it was shortened for AA‐NAT. Under constant darkness, the rhythm of mRNA was abolished for melanopsin, but persisted for AA‐NAT whereas, under constant light, the rhythm of mRNA was abolished for both genes. Our findings suggest that, in contrast to the AA‐NAT gene, the daily and photoperiod‐dependent regulation of the melanopsin gene does not rely on a circadian oscillator but is directly illumination‐dependent.

Unique clockwork in photoreceptor of rat.

J. Neurochem. (2010) 115, 585–594.

Histochemical differentiation between nitric oxide synthase-related and -unrelated diaphorase activity in the rat olfactory bulb

The widely used NADPH-diaphorase reaction for demonstrating neuronal nitric oxide synthase is not as specific as previously thought, as it visualizes both a nitric oxide synthase-related activity and a nitric oxide synthase-unrelated diaphorase. In the present study, we used the rat olfactory bulb as a model to characterize the NADPH-diaphorase activity of neuronal nitric oxide synthase histochemically in comparison with neuronal nitric oxide-unrelated diaphorase activity. The NADPH-diaphorase activity of nitric oxide synthase peaked at pH 8 and at Triton X-100 concentrations of 1--2.5%. It was stable in an acidic environment but was reduced in the presence of Triton X-100 and was inactivated by the flavoprotein inhibitor, diphenyleneiodonium. It preferred beta-NADPH as the co-substrate to alpha-NADPH and alpha-NADH. In contrast, nitric oxide synthase-unrelated diaphorase peaked at pH 10, displayed a Triton X-100 optimum at a concentration of 1%, was unstable in an acidic environment and used beta-NADPH, alpha-NADPH and alpha-NADH to similar extents. Differences in the characteristics between neuronal nitric oxide synthase-related and nitric oxide synthase-unrelated NADPH-diaphorase can be used to increase the specificity of the histochemical nitric oxide synthase marker reaction.