Delta sleep-inducing peptide (DSIP) stimulates LH release in steroid-primed ovariectomized rats

Delta sleep inducing peptide (DSIP) has been shown to increase sleep in various animals and it is found in various parts of the brain including the hypothalamus. While intraventricular administration of DSIP (2 or 10 micrograms) failed to affect LH release in ovariectomized rats, in two separate experiments DSIP (2 or 10; 15 or 30 micrograms) promptly stimulated LH release in ovariectomized estrogen, progesterone-primed rats. However, DSIP (10(-8) or 10(-6)M) had no effect on either basal or luteinizing hormone-releasing hormone-induced in vitro LH release from the hemipituitaries of ovarian steroid-primed rats. These findings are in accord with the hypothesis that DSIP or DSIP-like peptide(s) may activate the hypothalamic neural circuitry responsible for stimulation of LH release reported to occur during sleep.     

Degradation and aggregation of delta sleep-inducing peptide (DSIP) and two analogs in plasma and serum

The biostability of DSIP (delta sleep-inducing peptide) and two analogs in blood was investigated in order to determine if rates of inactivation contribute to variable effects in vivo. Incubation of DSIP in human or rat blood led to release of products having retention times on a gel filtration column equivalent to Trp. Formation of products was dependent on temperature, time, and species. Incubation of 125I-N-Tyr-DSIP and 125I-N-Tyr-P-DSIP, a phosphorylated analog, revealed slower degradation and, in contrast to DSIP, produced complex formation. An excess of unlabeled material did not displace the radioactivity supporting the assumption of non-specific binding/aggregation. It was concluded that the rapid disappearance of injected DSIP in blood was due to degradation, whereas complex formation together with slower degradation resulted in longer persistence of apparently intact analogs. Whether this could explain the sometimes stronger and more consistent effects of DSIP-analogs remains to be examined.     

Delta-sleep-inducing peptide (DSIP): An update

The isolation and characterization of delta-sleep-inducing peptide (DSIP) achieved from 1963 to 1977 were reviewed in 1984. The first reports describing sleep as well as extra-sleep effects of DSIP also were included in that work. Only two years later, much additional literature concerning DSIP has accumulated. Besides further sleep-inducing and/or-supporting effects of DSIP in animals, considerable work has been carried out to evaluate the potential use of the peptide for therapeutic purposes such as treatment of insomnia, pain, and withdrawal. Immunohistochemical as well as radioimmunochemical studies provided further insights into the natural occurrence of the nonapeptide and the distribution of DSIP-like material in the body, suggesting possible relations of the peptide to certain diseases. Various physiological functions of DSIP and a possible mechanism of action involving the modulation of adrenergic transmission remain to be established.     

Amphetamine-induced locomotor behavior of mice is influenced by DSIP

The delta sleep-inducing peptide (DSIP) has been shown to induce effects other than only delta sleep. One of these effects was the paradoxical thermoregulatory and locomotor response of rats to amphetamine after DSIP administration. In the present investigation we found similar effects of DSIP on the locomotor activity in mice. However, two different doses of DSIP (30 and 120 nmol/kg) and 3 doses of amphetamine (4, 10, and 15 mg/kg) produced a complex pattern of effects in mice tested at 22 degrees C. In general, DSIP-treated mice showed lower locomotor activity after amphetamine than controls, but under two conditions, both using 15 mg/kg amphetamine, DSIP produced higher scores; this occurred in the first two hours after amphetamine for the 30 nmol/kg DSIP group and in the third hour for mice given 120 nmol/kg DSIP. The results indicate that the effects of DSIP on locomotor behavior were dependent on the dosage of the peptide and the time of measurement as well as the level of amphetamine stimulation.     

Delta sleep inducing peptide (DSIP): effect on respiration activity in rat brain mitochondria and stress protective potency under experimental hypoxia

Neuromodulatory delta sleep inducing peptide (DSIP) seems to be implicated in the attenuation of stress-induced pathological metabolic disturbances in various animal species and human beings. Mitochondria, as cell organelles, are considered especially sensitive to stress conditions. In this work, the influence of DSIP and Deltaran((R))-a recently developed product based upon DSIP-on processes of oxidative phosphorylation and ATP production in rat brain mitochondria and rat brain homogenates was studied. A polarographic measurement of oxygen consumption was applied to evaluate the impact of DSIP on maximal rates of mitochondrial respiration and coupling of respiration to ATP production. We provide evidence that DSIP affected the efficiency of oxidative phosphorylation on isolated rat brain mitochondria. This peptide significantly increased the rate of phosphorylated respiration V3, while the rate of uncoupled respiration V(DNP) remaining unchanged. It enhanced the respiratory control ratio RCR and the rate of ADP phosphorylation. DSIP and Deltaran exhibited the same action in rat brain homogenates. We also examined the influence of DSIP under hypoxia when mitochondrial respiratory activity is altered. In rats subjected to hypoxia, we detected a significant stress-mediated reduction of V3 and ADP/t values. Pretreatment of rats with DSIP at the dose of 120 microgram/kg (i.p.) prior to their subjection to hypoxia completely inhibited hypoxia-induced reduction of mitochondrial respiratory activity. The revealed capacity of DSIP to enhance the efficiency of oxidative phosphorylation found in vitro experiments could contribute to understanding pronounced stress protective and antioxidant action of this peptide in vivo.     

Delta sleep-inducing peptide (DSIP): a still unresolved riddle

Delta sleep-inducing peptide (DSIP) was isolated from rabbit cerebral venous blood by Schoenenberger-Monnier group from Basel in 1977 and initially regarded as a candidate sleep-promoting factor. However, the link between DSIP and sleep has never been further characterized, in part because of the lack of isolation of the DSIP gene, protein and possible related receptor. Thus the hypothesis regarding DSIP as a sleep factor is extremely poorly documented and still weak. Although DSIP itself presented a focus of study for a number of researchers, its natural occurrence and biological activity still remains obscure. DSIP structure is different from any other known representative of the various peptide families. In this mini-review we hypothesize the existence of a DSIP-like peptide(s) that is responsible (at least partly) for DSIP-like immunoreactivity and DSIP biological activity. This assumption is based on: (i) a highly specific distribution of DSIP-like immunoreactivity in the neurosecretory hypothalamic nuclei of various vertebrate species that are not particularly relevant for sleep regulation, as revealed by the histochemical studies of the Geneva group (Charnay et al.); (ii) a large spectrum of DSIP biological activity revealed by biochemical and physiological studies in vitro; (iii) significant slow-wave sleep (SWS) promoting activity of certain artificial DSIP structural analogues (but not DSIP itself!) in rabbits and rats revealed by our early studies; and (iv) significant SWS-promoting activity of a naturally occurring dermorphin-decapeptide that is structurally similar to DSIP (in five of the nine positions) and the sleep-suppressing effect of its optical isomer, as revealed in rabbits. Potential future studies are outlined, including natural synthesis and release of this DSIP-like peptide and its role in neuroendocrine regulation.     

Entrapment and in vitro release of delta-sleep inducing peptide from polymer hydrogels based on modified polyvinyl alcohol

The aim of this study was to entrap delta-sleep inducing peptide (DSIP) in cross-linked poly(vinyl alcohol)-based hydrogels of different structures and to determine kinetics of the peptide release from these hydrogels using an in vitro model. Isotropic and macroporous hydrogels based on poly(vinyl alcohol) acrylic derivative (Acr-PVA) and also macroporous epoxy groups containing hydrogels synthesized by copolymerization of this macromer and glycidyl methacrylate, have been used in this study. Isotropic hydrogels were prepared at positive temperatures while macroporous ones were obtained by formation in cryo-conditions. The peptide was entrapped into macroporous PVA hydrogels by adding the peptide solution onto preformed matrices, while peptide immobilization on PVA-GMA hydrogels, containing free epoxy groups, was carried out by sorption of peptide from its aqueous solution. In the case of DSIP entrapment into isotropic PVA gel the peptide solution was added into the polymer mixture at hydrogel formation. The kinetics of peptide release from hydrogels was studied by incubating matrices in PBS solution (pH 7.4), in physiological solution (0.9% NaCl) and in water. DSIP concentration in supernatants was determined by reverse-phase HPLC. Incubation of macroporous PVA gels in PBS, 0.9% NaCl, and water for 30 min caused release of 74, 70, and 64% DSIP, respectively, and this processes completed within 3 h. From hydrogel containing epoxy groups the release of neither peptide nor its degradation products was observed even after incubation for 48 h. For freshly prepared isotropic hydrogel the release kinetics was as follows: 27 and 78% DSIP were released within first 30 min and 33 h, relatively. For the lyophilized hydrogel samples the peptide release was 63% after incubation for 30 min, while drying of samples at room temperature for 3 days caused significant peptide loss because of its structure damage.     

Delta Sleep-Inducing Peptide Modulates the Stimulation of Rat Pineal N-Acetyltransferase Activity by Involving the α1 -Adrenergic Receptor

Delta sleep-inducing peptide (DSIP) has been isolated and characterized by its capacity to enhance delta sleep in rabbits. Up to now, sleep was the main target of DSIP research, but different extra-sleep effects of the peptide have been reported as well. Several mechanisms of action have been proposed, though no convincing evidence for any of them has been obtained so far. We recently detected that DSIP reduced the nocturnal increase of N-acetyltransferase (NAT) activity in rat pineal in a dose-dependent manner. The activity of this enzyme is known to be induced by adrenergic agonists and several studies have suggested that stimulation of alpha 1-adrenergic receptors potentiates the "basic" effect of beta-receptors. DSIP in the range between 20 and 300 nM significantly enhanced NAT activity induced by 10(-6) M norepinephrine in vitro, and a similar effect was observed with 2nMP-DSIP, a phosphorylated analog. Incubation with prazosin eliminated the enhancement, whereas propranolol reduced norepinephrine stimulation that was still increased by P-DSIP and probably DSIP. It was concluded that the sleep-peptide and its analog modulate the alpha 1-adrenergic receptor of rat pineal in its response to adrenergic agonists. The same mechanism may also be responsible for other biological activities of DSIP such as sleep-induction and stress-tolerance.     

DSIP affects adrenergic stimulation of rat pineal N-acetyltransferase in vivo and in vitro

The natural occurrence, sleep, and extra-sleep effects of delta sleep-inducing peptide (DSIP) have been shown by different laboratories. However, neither an in vitro assay system nor a probable mechanism of action of the peptide have been conclusively demonstrated so far. The recent finding that DSIP influences the nocturnal rise of N-acetyltransferase (NAT) activity in rat pineal led us to investigate a possible effect on pharmacologically induced NAT activity in vivo and in vitro. Stimulation of the enzyme with adrenergic drugs such as isoproterenol and phenylephrine was reduced by DSIP at doses of 150 and 300 μg/kg injected subcutaneously. In vitro, 6, 150 and 300 nM DSIP attenuated isoproterenol stimulation of the enzyme in cultured pineals, whereas 150 nM DSIP effectively reduced stimulation induced by a combination of the two drugs. The peptide alone did not influence NAT activity in vitro, but produced a slight stimulation in vivo. To our knowledge, these results represent the first report of a direct interaction of DSIP with adrenergic transmission. The in vitro system could prove useful for establishing possible mechanism(s) of action of the ‘sleep peptide.’     

Radioimmunoassay of delta sleep-inducing peptide using an iodinated p-hydroxyphenylpropionic acid derivative as tracer

A highly sensitive radioimmunoassay for delta sleep-inducing peptide (DSIP) has been developed. A p-hydroxyphenylpropionic acid conjugate of DSIP was used for radioiodination. Using reversed-phase high performance liquid chromatography the labelled DSIP derivative was isolated in a high yield and with a high specific activity. The assay allows measurement of DSIP-like material in body fluids with a minimum detectable concentration of 0.1 ng/ml standard DSIP (10 pg/tube).     

Effects of delta-sleep-inducing peptide during ischemic injury of the rat brain

An anti-ischemic effect of the delta-sleep-inducing peptide (DSIP) was found in rats. The DSIP effect was more obvious than that of the MK-801. The data obtained is discussed considering a possible use of the DSIP for brain stroke prophylaxis.     

Effect of the delta sleep peptide on epileptic activity in the cerebral cortex of rats and cats

In free behaviour experiments on rats it has been shown that the intraperitoneal injection of delta sleep-inducing peptide (DSIP) (100 micrograms/kg) suppressed penicillin-induced relatively moderate epileptic foci which generated spike potentials as well as severe foci with ictal epileptic discharges. In the experiments on cats it was shown that intravenous DSIP injection (100 micrograms/kg) suppressed strychnine-induced epileptic focus and complexes of epileptic foci.     

Extraction and immunochemical characterization of delta sleep-inducing peptide-like material from the porcine pituitary and adrenal gland

The naturally occurring forms of delta sleep-inducing peptide (DSIP) are not fully identified. In the present study, porcine pituitaries and adrenal glands were extracted in water, saline or acid under various conditions and immunoreactive DSIP (IR-DSIP) quantified by radioimmunoassay. The highest concentrations were measured in anterior pituitary extracts (40.8 +/- 2.6 ng/g tissue weight) recovered using water with aprotinin. However, high performance liquid chromatography (HPLC) indicated degradation of hydrophobic forms of IR-DSIP in water extracts. Extraction in acetic acid including C18 Sep-Pak purification resulted in an elution profile of IR-DSIP in adrenal extracts with a major peak coeluting with synthetic DSIP [DSIP(1-9)], whereas anterior pituitary extract showed material of higher hydrophobicity. Approximately 30% of IR-DSIP in anterior pituitary as well as in adrenal gland extracts seemed to be glucosylated, as based on concanavalin A chromatography. One of the DSIP-immunoreactive components by immunoblotting (molecular mass 25 kDa) was identified in both pituitary and adrenal gland extracts. In conclusion, several chromatographically distinct forms of IR-DSIP are present in the porcine pituitary and adrenal gland. IR material eluting as DSIP(1-9) is present in adrenal gland extract. The procedure and solution used for tissue extraction seem to be essential in order to obtain reliable elution positions on HPLC.     

Delta sleep-inducing peptide (DSIP)-like material exists in peripheral organs of rats in large dissociable forms

The presence of delta sleep-inducing peptide (DSIP) in brain has been shown by radioimmunoassay (RIA) and by immunocytochemistry. We now describe the occurrence of DSIP-like material in the peripheral organs of the rat as measured by RIA. Tissue from 12 areas was extracted with water, and the amounts of immunoreactive material found to be between 86 pg/mg tissue (muscle) and 849 pg/mg (stomach). Recoveries of about 80% of added DSIP were achieved at tissue concentrations of 1 mg/ml or less. This percentage was reduced in liver at higher concentrations. The percentage of small peptide adsorbed by charcoal was greatly increased at lower tissue concentrations in all organs. This effect was significant and linear. Chromatography on columns of Sephadex G-15 and G-25 showed immunoreactive material mostly larger than DSIP. Digestion with trypsin, however, produced small immunoreactive peptides with only a minimal reduction in total immunoreactivity. Thus, DSIP-like material is widespread in peripheral tissues and appears to exist mainly in a large form, probably bound to protein, that can be reduced in size by tryptic digestion and can be dissociated at lower concentrations of tissue to yield small immunoreactive peptides.     

Features of regulating delta sleep-inducing peptide by free radical processes in tissue and erythrocyte membranes in intact animals and under stress

In activity the comparative analysis of metabolic effects delta--sleep inducing peptide (DSIP) in tissues and erythrocytes of intact rats and under cold stress is conducted. The regulation effect of DSIP in attitude of free radical processes will be realised through modulation the prooxidant--antioxidant balance: both for intact animal, and at stress. Exogenous DSIP increases the antioxidant system activity in tissues of brain, liver and blood in standard conditions and under cold stress. The anti-stress effect of DSIP is directed as on increase of power endogenic enzymatic antioxidant system activity, specially glutathione peroxidase activity, and not enzymatic of antioxidant protection. The DSIP renders different influence on activity of prooxidant enzymes: for intact animal boosts the myeloperoxidase activity in blood neutrophils, not rendering essential influencing on the xanthine oxidase activity in tissues of brain, liver and activates the myeloperoxidase activity, depresses the xanthine oxidase activity for rats at stress. The membranotropic effect of DSIP in the norm and under stress is connected to increase of stability of protein--lipid interplays. The membranostabilizing effect of DSIP in conditions of stress is characterized decrease of polarity of lipid phase and negative surface charge of erythrocyte membranes, modified in course of lipid peroxidation.     

Conformations of yeast alpha-mating factor and analog peptides as bound to phospholipid bilayer. Correlation of membrane-bound conformation with physiological activity

The transferred nuclear Overhauser effects of yeast alpha-mating factor [(1-13)peptide] in the presence of various spin-labeled phosphatidylcholines in small unilamellar vesicles of perdeuterated phosphatidylcholine have been analyzed. From the analysis of the quenching effect by spin-labels, the depth of amino acid side chains of the mating factor in phospholipid bilayer has been elucidated. The Leu4 and Leu6 residues are buried deeply in the apolar region of the phospholipid bilayer while the hydrophilic residues such as Gln5 and Lys7 are in the shallow region of the bilayer. The interaction of the side chains of Trp1 and Trp3 residues of alpha-mating factor with the hydrophobic interior of the bilayer contributes to the binding of this peptide with the phosphatidylcholine bilayer. The conformation of des-Trp1-alpha-mating-factor [(2-13)peptide] in the membrane-bound state has been found to be similar to that of (1-13)peptide from the analysis of transferred nuclear Overhauser effects in the presence of mixed vesicles of perdeuterated phosphatidylcholine and perdeuterated phosphatidylserine. The incorporation of this acidic phospholipid in the vesicle remarkably enhances the binding of (1-13)peptide and analog peptides. However, such modifications that weaken the interaction with phospholipid bilayer (deletion of Trp1 and substitution of Trp3 by Gly or Ala) appreciably lower the physiological activity. Transferred nuclear Overhauser effect analyses have also been made of [DHis2]peptide, [DLeu6]peptide and [DLys7]peptide in the presence of the vesicles of perdeuterated phosphatidylcholine. The main-chain conformations of these three analogs in the membrane-bound state have been found to be similar to that of (1-13)peptide, although the side-chain conformations of the D-amino acid residues are naturally different from those of the L-amino acid ones. Thus, the physiological activities of the (1-13)peptide and a variety of analog peptides are found to correlate with the affinities to the phosphatidylcholine/phosphatidylserine membrane and with the molecular conformations in the membrane-bound state.     

Human pheochromocytoma cells studied in culture contain large amounts of DSIP-like material.

Delta sleep-inducing peptide (DSIP)-like immunoreactive (LI) material has been detected in nine different human pheochromocytoma tumors by immunocytochemistry. In primary tumors subjected to indirect immunofluorescence a variable number of tumor cells (25-75%) showed positive cytoplasmic labeling after incubation with DSIP antiserum. Tumor cells grown in culture were strongly labeled by the DSIP antiserum with DSIP-LI concentrated to cell bodies. Electron microscopic immunocytochemistry (immunogold labeling) of pheochromocytoma cells demonstrated DSIP-LI over the dense core of secretory granules. The presence of DSIP-LI in several HPLC fractions from conditioned culture media indicates secretion of DSIP-LI from cultured pheochromocytoma cells. The observations suggest that DSIP-LI is synthesized and stored in secretory granules before release. The different HPLC profiles from each of the tumors may reflect differences in processing or turnover of DSIP-LI in pheochromocytoma cells.     

The effect of delta sleep-inducing peptide on the convulsive activity in corasol kindling

The influence of intraperitoneal delta-sleep inducing peptide (DSIP) injection (100 micrograms/kg) on the epileptic activity was investigated in the experiments on Wistar rats and (CBA X C57B1/6)F1 mice. The model of chronically developing epileptic activity--the model of pharmacological kindling--was created by daily repeated corasole injections in subconvulsive doses (30 mg/kg). It has been shown that DSIP injection delayed the manifestation of generalized seizures during kindling, led to the suppression of seizure activity and reduced the mortality rate of animals that developed kindled seizures. The antiepileptic effect of DSIP was observed throughout the period of 5 minutes to 24 hours after the injection. Naloxone (2.5 mg/kg) did not change the antiepileptic effect of DSIP.     

Role of lysine and tryptophan residues in the biological activity of toxin VII (Ts gamma) from the scorpion Tityus serrulatus.

Toxin VII (TsVII), also known as Ts gamma, is the most potent neurotoxin in the venom of the Brazilian scorpion Tityus serrulatus. It has been purified to homogeneity using a new fast and efficient method. Chemical modification of TsVII with the tryptophan-specific reagent o-nitrophenylsulfenyl chloride yielded three modified derivatives (residues Trp39, Trp50 and Trp54). Acetylation of TsVII mostly generated the monoacetylated Lys12 derivative. No side reactions were detected, as indicated by endoproteinase Lys-C peptide mapping, Edman degradation and electrospray mass spectrometry. Circular dichroism and fluorimetric measurements showed that none of the chemical modifications altered the overall structure of the derivatives. The acetylation of Lys12 or the sulfenylation of Trp39 or Trp54 led to a loss of both toxicity in mice and apparent binding affinity for rat brain and cockroach synaptosomal preparations. Sulfenylation of Trp50, however, moderately affected the toxicity of TsVII in mice and had almost no effect on its binding properties. A 3-dimensional model of TsVII was constructed by homology modeling. It suggests that the most reactive residues (Lys12 and Trp39 and Trp54) are all important in the functional disruption of neuronal sodium channels by TsVII, and are close to each other in the hydrophobic conserved region.     

Biosynthesis and processing of delta sleep-inducing peptide-like precursors in primary cultures of mouse anterior pituitary cells

The biosynthesis and processing of material resembling delta sleep-inducing peptide (DSIP) have been studied in mouse anterior pituitary primary cell cultures. Cells were pulse/chase incubated with 3H-labelled amino acids (Gly, Arg or Ala) and cell extracts were immunoprecipitated with DSIP antiserum. Labelled DSIP-related proteins were resolved by SDS/PAGE. Multiple forms of DSIP-immunoprecipitable material were observed, including three precursors of molecular mass 50-60 kDa which were processed to two major groups of intermediates of 35-45 kDa and 9-16.5 kDa. These intermediates appear to be processed to a DSIP-related peptide (molecular mass less than 3 kDa), which co-ran on reversed-phase HPLC with an endogenous form of DSIP in mouse anterior pituitary, but not with rabbit DSIP. This less than 3-kDa peptide incorporated [3H]Gly, but not [3H]Arg or [3H]Ala. In addition, it incorporated [3H]glucosamine, indicating that it was a glycopeptide. Secretion studies showed release of the less than 3-kDa DSIP-like glycopeptide and the 9-16.5-kDa group of intermediates into the medium. The present study demonstrates the biosynthesis of a small DSIP-like glycopeptide in mouse anterior pituitary cells, which is not identical with, but has similarities to, rabbit DSIP.