New diketopiperazines as vectors for peptide protection and brain delivery: Synthesis and biological evaluation.

New strategies allowing the transfer of molecules, especially peptides, through the blood-brain barriers are a major pharmacological challenge for the treatment of brain diseases. The present study aims at evaluating in vivo the cerebral bioavailability of carrier systems, based on small and functionalizable 2,5-diketopiperazine (DKP) motifs. We studied 2 different cyclo(Lys-Lys) DKP scaffolds alone and a cyclo(Lys-Gly) DKP carrier bearing as peptide model, the tau protein hexapeptide VQIVYK sequence. The different carrier systems were synthesized and radiolabeled using one of the free domains. The stability, biodistribution, and ability to cross blood-brain barrier were investigated in vivo in mice for 99m Tc-DKP scaffolds, 99m Tc-HVQIVYK peptide alone, and 99m Tc-DKP-VQIVYK. 125 I-labelled bovine serum albumin was used as negative control for brain uptake. Both radiolabeled DKPs scaffolds and 99m Tc-DKP-VQIVYK showed a high stability, while peptide 99m Tc-HVQIVYK alone was quickly degraded in vivo. The presence of 99m Tc-DKPs scaffolds and 99m Tc-DKP-VQIVYK was observed in the ventricular and subarachnoid spaces and to a lower extent in the brain parenchyma up to 45 minutes post-injection in mice. This work highlights the potentiality of DKP scaffolds as vectors to transport peptides into the brain by limiting proteolysis and favoring cerebral bioavailability.

Identification of a Kin nuclear protein immunologically related to RecA protein in the rat CNS.

A polypeptide, called Kin, has been identified in cells of the central nervous system (CNS) by using antibodies raised against RecA protein of E. coli and by in situ hybridization with identified cDNA. RecA protein is a recombination enzyme associated with DNA repair. The RecA cross-reacting polypeptide was immunocytochemically demonstrated in the nuclei of various cells of adult rats. Following Western blot analysis using anti-RecA antibodies, the Kin protein showed a band with an apparent molecular weight of 41 kDa. Double labelling experiments, using in situ hybridization of Kin-17 mRNA with serotonin immunocytochemistry, demonstrated a cytoplasmic distribution of radiolabelling indicating the translation of this messenger RNA in serotonergic neurons. These data indicate the presence of a Kin nuclear protein in the CNS and suggest that neurons may possess some DNA-repair pathways analogous to those described in bacteria.

Paradoxical sleep deprivation increases glutamine synthetase in rat brain.

The modifications of glutamine synthetase (GS) level, an enzyme mainly located in astrocytes, were investigated in rat after paradoxical sleep deprivation and during recovery. An immunotitration method was used to evaluate the relative level of GS in brain tissue. At the end of a 24 hrs. paradoxical sleep deprivation, a significant increase in GS level was observed both in the frontoparietal cortex and the locus coeruleus area. 4 hrs. later, during recovery, the GS level returned to control level in the cortex but was lower in the locus coeruleus area.

The posterior hypothalamus is responsible for the increase of brain temperature during paradoxical sleep.

Electroencephalogram, caudate nucleus temperature (Tc), ear skin temperature (Te) as well as cerebral blood flow (CBF) measured by a thermal clearance method, were recorded simultaneously and continuously in cats. After baseline recording in which we confirmed the increase of Tc during paradoxical sleep (PS), neuronal cell bodies of the mesencephalic reticular formation and/or the posterior hypothalamus (PH) were destroyed with ibotenic acid. Only PH lesions were followed by either a suppression of the increase or even a decrease of Tc during PS while Te variations were not modified. The decrease in CBF, which was always associated with Tc increase, was suppressed after the PH lesion. These results led us to the conclusion that the increase of Tc at the onset of PS is due to a decrease in CBF. Furthermore, it may be hypothesized that the decrease in CBF depend upon an active vasoconstriction process originating in the PH.

Neurotoxic lesion of the mesencephalic reticular formation and/or the posterior hypothalamus does not alter waking in the cat.

In order to re-evaluate the role of two putative waking systems, we injected a neural cell body toxin, ibotenic acid (IA) (45 micrograms/microliters), into the mesencephalic reticular formation (MRF) and/or the posterior hypothalamus (PH). On the one hand, when the cell body destruction was only restricted to the MRF, the IA microinjection was followed by a temporary high voltage and slow neocortical electroencephalogram (EEG) during the first 24 postoperative hours and by a subsequent long term increase in waking which lasted 8-12 h. After the first postoperative day, there were no motor disturbances, no aphagia nor adypsia, no alteration of cortical activation and no modification of thermoregulation or of the sleep-waking cycle. On the other hand, the IA microinjection into the PH induced a hypothermia during the first postoperative night and a dramatic transient hypersomnia immediately after the disappearance of the anesthesia (14-24 h after the IA injection). On the third day, all cats recovered control level of paradoxical sleep (PS), slow wave sleep (SWS) and cerebral temperature. They presented normal motor behavior but they were not able to eat by themselves during the first postoperative week. Finally, when the lesions of the MRF and the PH were realized in one single operation, the cats were first motionless in a comatose state for 2-3 days. This state was accompanied by a transitory hypothermia and the suppression of a spontaneous or evoked cortical low voltage fast activity. However, from the 2nd postoperative week, both behavioral and EEG waking re-occurred. By contrast, the two successive operations (MRF followed by PH) did not induce a comatose state. We did not observe any deficit in motor behavior, and the sleep-waking cycle was quite normal as from the second postlesion day. In the MRF-PH-lesioned cats, the injection of alpha-methyl-p-tyrosine (150 mg/kg) induced a large decrease in waking and a moderate increase in PS. In the MRF-lesioned cats, IA produced a large area of cell body loss, centered in the MRF, that extended from levels A2 to A6 of stereotaxic planes and sometimes encroached upon the red nucleus and the substantia nigra. In the PH-lesioned cats, the histological analysis revealed a great loss of cell bodies in the PH extended from levels A8 to A12.5. The damage included the lateral and posterior hypothalamic areas and sometimes the tuberomamillary nucleus. In MRF- and PH-lesioned cats, the cell body loss extended from levels A2 to A12.5.(ABSTRACT TRUNCATED AT 400 WORDS)

Immunohistochemical mapping of delta sleep-inducing peptide in the cat brain and hypophysis. Relationships with the LHRH system and corticotropes.

Using the indirect immunofluorescence method, the distribution of the delta sleep-inducing peptide was studied in the cat brain and hypophysis. Delta sleep-inducing peptide-like-immunoreactive cell bodies mostly visualized in colchicine-pretreated animals were mainly found scattered throughout the diagonal band of Broca, the ventral septum and the anterior hypothalamic areas. A few immunoreactive cell somata were also seen in the ventrolateral hypothalamic area and more occasionally in the triangular septal nucleus. The heaviest concentrations of delta sleep-inducing peptide-like-immunoreactive varicose fibres and terminal-like structures were observed in the septo-preoptic region, in the median eminence and pituitary stalk. Some other brain regions supplied with few delta sleep-inducing peptide-immunoreactive fibres included the fimbria-fornix, the dorsal part of the subfornical organ, the medial habenular nucleus and more caudally, the periaqueductal gray. Elution-restaining experiments revealed that delta sleep-inducing peptide-like immunoreactivity frequently occurred in luteinizing hormone-releasing hormone-immunoreactive neurons and vice versa. At the pituitary level, delta sleep-inducing peptide-like immunoreactivity was detected in most, if not all, melanocorticotropes of the pars intermedia and further in a large subpopulation of corticotropes mainly located in the zona tuberalis of the pars distalis. Taken together these anatomical findings support the view that delta sleep-inducing peptide (or a closely related molecular form) could play a modulatory role at various levels of the hypothalamo-pituitary system.

Comparative marker analysis of the ependymocytes of the subcommissural organ in four different mammalian species.

The subcommissural organ (SCO), classified as one of the circumventricular organs, is composed mainly of modified ependymal cells, attributable to a glial lineage. Nevertheless, in the rat, these cells do not possess glial markers such as glial fibrillary acidic protein (GFAP), protein S100, or the enzyme glutamine synthetase (GS). They receive a synaptic 5-HT input and show pharmacological properties for uptake of GABA resembling the uptake mechanism of neurons. In this study, we examine the phenotype of several mammalian SCO (cat, mouse, rabbit) and compare them with the corresponding features of the rat SCO. In all these species, the SCO ependymocytes possess vimentin as an intermediate filament, but never express GFAP or neurofilament proteins. They do not contain GS as do glial cells involved in GABA metabolism, and when they contain protein S100 (rabbit, mouse), its rate is low in comparison to classical glial or ependymal cells. Thus, these ependymocytes display characteristics that differentiate them from other types of glial cells (astrocytes, epithelial ependymocytes and tanycytes). Striking interspecies differences in the capacity of SCO-ependymocytes for uptake of GABA might be related to their innervation and suggest a species-dependent plasticity in their function.

Type B monoamine-oxidase-containing cells and fibers in the cat hypothalamus demonstrated by an improved enzyme histochemical method.

The present study, using a diaminobenzidine (DAB)-coupled peroxidation method, examined the distribution and morphological characteristics of neuronal structures containing type B monoamine oxidase (MAO-B) in the cat hypothalamus. Large and intensely stained, distinctive MAO-B-positive cells, multipolar and with long dendritic arbors, were principally distributed in the ventral hypothalamus extending from A7 to A12.5 of the Horsley-Clarke plane. These cells were located caudally in the ventral surface of the brain including the tuberomamillary nucleus (TM) and the region surrounding the mamillary nuclei. Rostrally, they were aggregated in the area surrounding the fornix, particularly in the lateral perifornical region, and dispersed in the anterior mamillary nucleus, lateral hypothalamic area (HLA), and the medial tip of the entopeduncular nucleus. The most rostral positive cell group was identified in a narrow space between the optic tract and the entopeduncular nucleus at the A12.5 level. In addition to these large cells, the present study disclosed the presence of "small" to "very small" MAO-B-positive cells in the area surrounding the mamillary recess and the lateral part of the caudal arcuate nucleus. Distinct MAO-B-stained fibers were identified in all regions of the hypothalamus. A large number of thick labeled fibers were observed in the ventral hypothalamus including the TM and premamillary nucleus and posterior and lateral hypothalamic areas. A dense network of MAO-B-positive terminal-like fibers was observed in the dorsomedial nucleus where very small labeled cells were scattered. Many intensely stained thick and straight fibers were seen running ventrolaterally in the anterior part of the HLA and in the narrow space between the entopeduncular nucleus and optic tract. In the area of the tuber cinereum and the ventral part of the HLA, there were many positive fibers cut transversely, possibly projecting to the more anterior parts of the brain such as the diagonal band of Broca or septal nuclei.

[Cells presenting GABA immunoreactivity in the hypothalamus of the cat]. / Cellules présentant une immunoréactivité au GABA dans l'hypothalamus du Chat.

The distribution of GABA-immunoreactive (IR) cells was studied by immunohistochemistry in conjunction with highly specific antiserum GABA in the cat hypothalamus. Colchicine pretreatment made it possible to visualize a large number of labeled cells in the medial preoptic and dorsal hypothalamic areas. In contrast, the ventromedial and anterior hypothalamic nuclei contained only a few labeled cells, and the paraventricular and supraoptic nuclei were devoid of them. A very dense network of GABA-IR presumptive terminals was seen in the ventrolateral posterior hypothalamus where labeled cells could be recognized. The possibility of an involvement of the GABAergic neuronal system in the regulation of sleep-waking cycle is discussed.

Reversibility of para-chlorophenylalanine-induced insomnia by intrahypothalamic microinjection of L-5-hydroxytryptophan.

Para-chlorophenylalanine, a blocker of serotonin biosynthesis by inhibiting tryptophan hydroxylase, induced total insomnia which was accompanied in cat by a permanent discharge of ponto-geniculo-occipital activity. L-5-Hydroxytryptophan microinjection (1-4 micrograms/0.5 microliters) in the anterior hypothalamus 72 h after para-chlorophenylalanine administration, restored both slow wave sleep and paradoxical sleep with variable latencies for each state of sleep. On the contrary, ponto-geniculo-occipital activity was never suppressed. The hypnogenic effects of L-5-hydroxytryptophan were always followed by a return of the para-chlorophenylalanine-induced insomnia. On the other hand, the temperature recording did not show any alteration of the cerebral temperature after para-chlorophenylalanine treatment but the subsequent L-5-hydroxytryptophan microinjection was followed by hyperthermia. Using immunohistochemistry for serotonin after intrahypothalamic L-5-hydroxytryptophan microinjection in parachlorophenylalanine-pretreated cat, we defined a restricted region of the anterior hypothalamus possibly responsible for the hypnogenic effect. This region included the lateral hypothalamus and the anterior hypothalamic area. It is suggested that the reversible hypersomnia after L-5-hydroxytryptophan microinjection in the anterior hypothalamus in para-chlorophenylalanine-pretreated cat is due to a neurohormonal action of serotonin: serotonin could act upon the anterior hypothalamus which secondarily inhibits a waking system located in the ventrolateral hypothalamus leading to the appearance of paradoxical sleep.

Long-lasting insomnia induced by preoptic neuron lesions and its transient reversal by muscimol injection into the posterior hypothalamus in the cat.

In order to analyse the role of the anterior hypothalamus in the regulation of the sleep-waking cycle we made bilateral neuronal lesions at different levels of the anterior hypothalamus in cats, by means of microinjections of a cell-specific neurotoxin:ibotenic acid. These lesions resulted in severe insomnia in eight cats. This insomnia was characterized by a large decrease or even disappearance of paradoxical sleep and deep slow wave sleep and, to a lesser extent, by a decrease of light slow wave sleep, for 2-3 weeks. In the other five animals, we observed a large reduction of deep slow wave sleep (0-40% of control level), but a less intensive decrease of time spent in paradoxical sleep (50-75% of control level) and no marked effect on light slow wave sleep. During the first 3-6 postoperative days we also noticed hyperthermia in all cats; thereafter, the animals presented only a slight increase in brain temperature which did not appear to trigger the sleep impairment. Histological analysis of the different lesions revealed that the insomnia could be attributed to neuronal cell body destruction in the mediobasal part of the anterior hypothalamus covering; the medial preoptic area and a narrow portion of the lateral preoptic area as well as a restricted part of the anterior hypothalamic nucleus. In order to investigate the putative role of the posterior hypothalamic structures in the mechanism of insomnia after lesion of the mediobasal preoptic area neurons we injected an agonist of GABA into the ventrolateral part of the posterior hypothalamus to locally depress the neuronal activity. The bilateral intracerebral microinjection of muscimol (0.5-5 micrograms) induced a transient intensive hypersomnia (slow wave sleep and paradoxical sleep). These findings indicate that neuronal cell loss in the mediobasal preoptic area induced a long lasting insomnia. Thus, it may be hypothesized that the integrity of this structure is necessary for sleep appearance. Finally, our data are in keeping with an intrahypothalamic regulation of the sleep-waking cycle.

5-Hydroxytryptophan uptake and decarboxylating neurons in the cat hypothalamus.

Parachlorophenylalanine, an inhibitor of tryptophan hydroxylase, induced a virtually total disappearance of serotonin-immunoreactivity in the hypothalamus of the cat. After intrahypothalamic injection of 5-hydroxytryptophan, an immediate precursor of serotonin in cats pretreated with parachlorophenylalanine, serotonin-immunoreactivity was detected in many fibers surrounding the injection site. Furthermore, when 5-hydroxytryptophan was injected with inhibitor of monoamine oxidase, a large number of small neurons immunoreactive to serotonin was identified in many discrete regions: the anterior and lateral hypothalamic areas, preoptic area, suprachiasmatic nucleus, dorsal hypothalamic area, dorsomedial nucleus, posterior hypothalamic area and nucleus of the fields of Forel. Serotonin-immunoreactivity was also evident in the thick axon bundles in the lateral hypothalamus. The distribution pattern of these cells was quite similar to that of aromatic L-amino acid decarboxylase, which catalyses the conversion of 5-hydroxytryptophan to serotonin and that of L-3,4-dihydroxyphenylalanine to dopamine. However, we failed to demonstrate serotonin-immunoreactivity in these parvocellular neurons without monoamine oxidase inhibitor. It is possible that 5-hydroxytryptophan is decarboxylated to serotonin by aromatic L-amino acid decarboxylase but rapidly degraded by monoamine oxidase-A, the enzyme which preferentially deaminates serotonin. In contrast, serotonin-immunostaining was always demonstrable after intrahypothalamic injection of 5-hydroxytryptophan without monoamine oxidase inhibitor in magnocellular neurons located in the ventrolateral posterior hypothalamus and which contain exclusively monoamine oxidase-B and histidine decarboxylase. It appears that in these cells and axons, serotonin, possibly formed by histidine decarboxylase, is not rapidly oxidized by monoamine oxidase-B. Possible roles of serotonin as a neurohormone in sleep-waking regulation and of trace amines in the brain are discussed.

Hypophysectomy does not disturb the sleep-waking cycle in the cat.

The ablation of the hypophysis does not disturb the basic waking-sleep cycle. Further, this intervention fails to modify the recovery of sleep after instrumental paradoxical sleep deprivation as well as after injection of 5-hydroxytryptophan in parachlorophenylalanine-pretreated insomniac cats. These results demonstrate that the hypophysis does not play a significant role in sleep mechanisms. We discuss these data in view of a possible regulation of the sleep-waking cycle by hypothalamo-hypophyseal hormones.

Topography of neurophysin-immunoreactive neurons projecting to the neurohypophysis: direct evidence as revealed by a double staining method.

The topographic distribution of neurophysin-immunoreactive (NP-IR) cells projecting to the posterior pituitary gland has been studied in the cat using a double staining method: immunohistochemistry of neurophysin in conjunction with horseradish peroxidase (HRP) retrograde tracer technique. We found that almost all the hypothalamic NP-IR cells project directly to the neurohypophysis except those localized in the suprachiasmatic nucleus and in the caudal part of the paraventricular nucleus.

Increase of paradoxical sleep induced by microinjections of ibotenic acid into the ventrolateral part of the posterior hypothalamus in the cat.

In order to study putative hypothalamic mechanisms of sleep-waking cycle regulation we injected a neural cell body toxin--ibotenic acid (IBO), 40 to 200 micrograms--into the ventrolateral part of the posterior hypothalamus (HVL). This injection induced a dramatic biphasic and transient hypersomnia immediately after the disappearance of the anesthesia (14 to 24 hours after the injection). The duration of hypersomnia was dose dependent. Its first period was characterized by an increase in paradoxical sleep (PS) (300%). Then, during the second phase, PS disappeared and there was a subsequent increase of slow sleep (SWS) (60%). Finally, on the third day, all cats recovered control level of PS and SWS while, 3 weeks later, the histological analysis revealed the great loss of cell bodies in the HVL in all cats.

Effects of electrolytic lesion of hypothalamic paraventricular nucleus and its related areas on the sleep waking cycle in the cat.

In order to study putative hypothalamic mechanisms of sleep waking cycle regulation we destroyed, by electrolytic coagulation, a large part of the medial hypothalamus overlapping the paraventricular nucleus in 6 adult cats. We never observed any modification of light slow wave sleep. Three of the six cats presented no paradoxical sleep (PS) impairment, despite an almost total destruction of neurophysin-immunoreactive cells of PVN in two cats and marked signs of diabetes insipidus in the third. Further, in the other three animals a statistically significant decrease of daily quantities of PS and deep slow wave sleep (SWS2) were related to an extensive destruction of the anterior hypothalamic area. These results suggest lack of influence of the PVN in sleep regulation and an involvement of the anterior hypothalamus in the onset of SWS2 and PS.

[Insomnia following a lesion of the paramedial preoptic area is reversible by inactivation of the posterior hypothalamus in the cat]. / L'insomnie consécutive à la lésion de la région préoptique paramédiane est réversible par inactivation de l'hypothalamus postérieur chez le chat.

The bilateral intratissular injection of muscimol, an agonist of gamma amino butyric acid (GABA), induced a transient hypersomnia (slow wave sleep and paradoxical sleep) in an insomniac cat whose paramedial preoptic area had been previously bilaterally destroyed.

ACTH-immunoreactive neurons and their projections in the cat forebrain.

The organization of adrenocorticotropin (ACTH)-immunoreactive (IR) cell bodies and fibers in the cat forebrain is described. ACTH-IR cell bodies are found only in and around the arcuate nucleus of the hypothalamus (ARH). They are not detected elsewhere even after pretreatment with colchicine. ACTH-IR fibers are present in discrete areas of the hypothalamus, the septo-limbic areas and in the paraventricular thalamic nucleus. Complete electrolytic lesions of the ARH destroy ACTH-IR cell bodies as well as fibers in all parts of the brain. These results suggest that, in the cat forebrain, the ARH is the only source of ACTH-IR fibers.

[Increase of paradoxical sleep, induced by injection of ibotenic acid in the ventrolateral posterior hypothalamus in the cat]. / Augmentation du sommeil paradoxal, induite par l'injection d'acide iboténique dans l'hypothalamus ventrolatéral postérieur, chez le chat.

The intratissular injection of ibotenic acid into the ventrolateral part of the posterior hypothalamus induced a dramatic biphasic and transient hypersomnia immediately after disappearance of the anaesthesia (14 to 24 hrs. after injection). The duration of hypersomnia was related to the dose of neurotoxin injected. Its first period was characterized by an increase in paradoxical sleep (PS) (300%). Then, during the second phase, PS disappeared and there was a subsequent increase of slow wave sleep (SWS) (60%). Finally, on the third day, all cats recovered control level of PS and SWS.

[Long-duration insomnia after lesions of the perikaryons of the paramedian preoptic area in cats]. / Insomnie de longue durée après lésions des pérykarions de l'aire préoptique paramédiane chez le chat.

The destruction of paramedian preoptic neurons by intra-tissue injection of ibotenic acid induces, in the cat, the disappearance of deep slow wave sleep and paradoxical sleep for 2 to 4 weeks, while light slow wave sleep is slightly disturbed. This insomnia, well tolerated, is not secondarily associated with central temperature disturbance.