Lack of Usefulness of DN-1417 for Characterization of a CNS Receptor for Thyrotropin-Releasing Hormone

CNS receptors for thyrotropin-releasing hormone (TRH) and its analogs are likely to mediate the experimentally and clinically observed net excitatory effect of these peptides on lower motor neurons. Previous findings suggest that several types of TRH receptors with distinct TRH analog specificities may be present in rat CNS. In particular, based on competition isotherm assays with unlabeled analog gamma-butyrolactone-gamma-carbonyl-L-histidyl-L-prolineamide (DN-1417). Funatsu et al. claim the existence of a limbic forebrain site that binds this peptide and TRH with high affinity but that does not bind [3-methyl-histidyl2]-TRH (MeTRH). Using saturation and competition isotherm experiments, we have examined the binding of [3H]TRH and [3H]DN-1417 in three regions of rat CNS: pyriform cortex/amygdala, limbic forebrain, and lumbosacral spinal cord. In all three regions, saturation assays with [3H]TRH (0.4-100 nM) resolved only a single, saturable receptor with high affinity (KD = 12-14 nM) for TRH; in no case could more than one saturable site be identified. When [3H]DN-1417 was substituted as the assay ligand, no high-affinity binding component for this analog could be detected in the three regions. Competition curves for the binding of unlabeled DN-1417 to limbic forebrain and lumbosacral spinal cord ([3H]TRH as assay ligand) were monophasic (not biphasic like those of Funatsu et al.) and indicative of low-affinity binding of DN-1417 in these regions (Ki values = 2-3 microM; in agreement with values obtained in similar assays with [3H]MeTRH).(ABSTRACT TRUNCATED AT 250 WORDS)     

Histidyl-proline diketopiperazine: its biological role as a regulatory peptide

Summary Histidyl-proline diketopiperazine [cyclo(His-Pro)] is a metabolic of thyrotropin releasing hormone (TRH). This review summarizes the literature concerning cyclo (His-Pro) and, in addition, some studies dealing with TRH and other peptides that are considered of interest. The enzymes concerned with the metabolism of TRH are discussed. Distribution studies of peptides by immunological methods show that, while TRH is concentrated in synaptosomes, cyclo (His-Pro) is not, suggesting that cyclo (His-Pro) is not a classical neurotransmitter. Rat brain contains approximately three times as much cyclo (His-Pro) as TRH, mainly localized in the pituitary and hypothalamus. While the TRH is found in a free form, the cyclo (His-Pro) is bound to a carrier of molecular weight approximately 70 000. While specific membrane receptors for TRH have been detected in pituitary cells, no such receptors for cyclo (His-Pro) have yet been found in brain or pituitary; however, there is a specific binding of cyclo (His-Pro) to adrenal cortex membranes, Both TRH and cyclo (His-Pro) have effects in the central nervous system or pituitary. These include effects on prolactin release, thermoregulation, CNS depression, stereotypic behavior and cyclic nucleotide levels. Possible mechanisms and interrelations of these effects are discussed.     

Effect of DN-1417, a thyrotropin releasing hormone analog, on dopaminergic neurons in rat brain

Acute and chronic effects of γ-butyrolactone-γ-carbonyl-histidyl-prolinamide (DN-1417) were investigated on motor activity, dopamine (DA) metabolites and DA receptors in various brain regions of rats. The motor activity, as measured with Automex recorder, was enhanced after a single injection with DN-1417 (20 mg/kg, IP), and the motor stimulating action persisted during 21 daily injections. Acute DN-1417 elevated both homovanillic acid (HVA) and 3,4-dihydroxyphenylacetic acid (DOPAC) levels in 7 brain regions, prefrontal cortex polar, medial and lateral fields, nucleus accumbens, olfactory tubercles, amygdala and striatum. After chronic treatment for 7 days, the acute effect of DN-1417 on DA metabolites disappeared in all regions except for the striatum in which DN-1417 still increased HVA and DOPAC. The response of striatal DA metabolites was also observed after chronic treatment for 21 days. Chronic DN-1417 produced no significant change in ³H-spiperone binding in the prefrontal cortex, nucleus accumbens, olfactory tubercles and striatum, while striatal ³H-DA binding displaced by 30 nM spiperone was enhanced after chronic treatment. These results indicate that DN-1417 interacts with mesocortical, mesolimbic and nigrostriatal DA systems in the different modes of action. The lack of tolerance to motor hyperactivity, however, raises the question as to whether DN-1417-induced hyperactivity may be mediated by the activation of mesolimbic DA neurons. The involvement of nigrostriatal neurons in DN-1417-induced motor hyperactivity is suggested.     

Properties of histidyl-proline diketopiperazine [cyclo(His-Pro)] binding sites in rat liver

Characteristics of cyclo(His-Pro) binding sites in the rat liver were studied using 3H-labeled cyclo(His-Pro). Scatchard analysis suggested that the rat liver membrane had a single binding site with an apparent dissociation constant (Kd) of 7 X 10(-8) M. Pretreatment of membrane preparations with soybean trypsin inhibitor increased cyclo(His-Pro) binding, and the binding activity was sensitive to trypsin and phospholipase A digestion, suggesting that protein and phospholipid moieties are essential for cyclo(His-Pro) binding. Thiol reagents reduced binding activity, suggesting that the thiol group might be an important constituent of the cyclo(His-Pro) binding site. Cross-reactivities of TRH, TRH analogues, L-His and L-Pro were very low (0.2-9%). These findings indicate that specific binding sites for cyclo(His-Pro) in the rat liver have similar properties to the receptors for other polypeptides.     

Unresponsiveness of GH cells to cyclo(histidyl-proline), a metabolite of thyrotropin releasing hormone

Cyclo(Histidyl-Proline) is a metabolite of thyrotropin-releasing hormone. It has been suggested that this peptide plays a role in regulating prolactin secretion in GH cells. An investigation of the effect of cyclo(His-Pro) on GH cells indicated that it does not affect basal prolactin release or accumulation or the levels stimulated by TRH. cAMP levels in GH cells are elevated by TRH or VIP, but not influenced by cyclo(His-Pro). cGMP levels in GH cells are not affected by either TRH or cyclo(His-Pro). While there is specific binding of TRH to receptors in GH cells, no such receptors for cyclo(His-Pro) are detectable. It is suggested that GH cells are unresponsive to cyclo(His-Pro).     

Effects of thyrotropin releasing hormone and its analogues on unconsciousness following head injury in mice.

We examined the effects of thyrotropin releasing hormone (TRH) and its analogues (DN-1417: gamma-butyrolactone-gamma-carbonyl-histidyl-prolinamide citrate; MK-771: L-pyro-2-aminoadipyl-histidyl-thiazolidine-4-carboxamide; TSII-37: H-Lys-Gln-His-Pro-Gly-Ser-OH) on arousal in head injured mice, an animal model of unconsciousness. TRH, DN-1417, MK-771 and TSII-37 were injected 10 min before the head injury. TRH, DN-1417 and MK-771 caused dose-dependent decreases in the time required for recovery of the righting reflex time and in the time from the head injury to the onset of spontaneous movement. TSII-37 had no effect, when compared with the control group. In terms of the minimum effective dose, TRH and DN-1417 were of similar potency, but MK-771 was about 30-fold stronger than TRH. Measurement of the cross-reactivities of these TRH analogues by radiolabeled receptor assay suggest that the structure-binding relationship is proportional to the structure-activity relationship.     

Is all cyclo(His-Pro) derived from thyrotropin-releasing hormone?

Cyclo(His-Pro), or histidyl-proline diketopiperazine, is an endogenous cyclic dipeptide that is ubiquitously distributed in tissues and body fluids of both man and animals. This cyclic dipeptide is not only structurally related to thyrotropin-releasing hormone (TRH, pGlu-His-ProNH₂), but it can also arise from TRH by the action of the enzyme pyroglutamate amino-peptidase (pGlu-peptidase). The data on the distribution of TRH, cyclo(His-Pro), and pGlu-peptidase under normal and abnormal conditions are summarized and potential relationships analyzed. We conclude that all of the cyclo(His-Pro) cannot be derived from TRH. Two additional sources of cyclo(His-Pro) are suggested. It is proposed that 29,247 molecular weight TRH prohormone, prepro TRH, which contains 5 copies of TRH sequence, can be processed to yield cyclo(His-Pro). Thus, both TRH and cyclo(His-Pro) share a common precursor, prepro[TRH/Cyclo(His-Pro)].     

On the mechanism of fasting-associated elevations in hypothalamic cyclo(His-Pro) content

Potential mechanism(s) underlying the fasting-associated rise in hypothalamic cyclo(His-Pro) content was explored by examining the effects of 24-hour fasting on: (i) cyclo(His-Pro) synthesis from TRH, (ii) cyclo(His-Pro) metabolism, and (iii) cyclo (His-Pro) secretion by hypothalamic tissue in vitro. The data presented here show that none of these three variables were altered due to fasting. Two additional potential changes that could cause cyclo(His-Pro) elevations during fasting are suggested. These include an in vivo decrease in hypothalamic cyclo(His-Pro) secretion that may not be apparent in vitro, and/or an increase in the synthesis of cyclo(His-Pro) from a precursor(s) other than TRH.     

Developmental changes in the distribution of rat brain pyroglutamate aminopeptidase,a possible determinant of endogenous cyclo(His-Pro) concentrations

The distribution of cyclo(His-Pro), thyrotropin-releasing hormone (TRH) and Pyroglutamate aminopeptidase activity in adult and developing rat brains were studied. A comparison of the subcellular distribution of Pyroglutamate aminopeptidase activity in hypothalamic and cerebral cortical extracts from adult rats exhibited remarkable differences. In hypothalamus, the enzyme activity was mainly associated with the soluble fraction whereas in cortex it was predominantly associated with the particulate fractions. During postnatal development, the brain concentrations of cyclo(His-Pro) and Pyroglutamate aminopeptidase activities declined with age. These data suggest that Pyroglutamate aminopeptidase activity, but not TRH, plays an active role in determining the levels of endogenous cyclo(His-Pro) concentrations in brain.     

Thyrotropin-releasing hormone (TRH) and its analog (DN-1417): interaction with pentobarbital in choline uptake and acetylcholine synthesis of rat brain slices

TRH or its analog DN-1417 (gamma-butyrolactone-gamma-carbonyl-L-histidyl-L-proliamide) given 15 min after intravenous (i.v.) administration of pentobarbital (30 mg/kg) markedly shortened the pentobarbital-induced sleeping time in rats. This effect was almost completely abolished by intracerebroventricular pretreatment with atropine methylbromide (20 micrograms/rat), thereby suggesting the involvement of cholinergic mechanism. The action mechanism was investigated using rat brain slices. TRH (10(-6)-10(-4)M) or DN-1417 (10(-7)-10(-5)M) caused significant increases in the uptake of [3H]-choline into striatal slices. TRH(10(-4)M) or DN-1417(10(-5)M) also stimulated the conversion of [3H]-choline to [3H]-acetylcholine in striatal slices. A 30% reduction of acetylcholine synthesis from [3H]-choline in hippocampal slices and a 40% reduction of [3H]-choline uptake in slices of cerebral cortex, hippocampus and hypothalamus were observed in rats pretreated with pentobarbital (60 mg/kg, i.v.). TRH or DN-1417 (20 mg/kg, i.v.) given 15 min after the administration of pentobarbital markedly reversed both of the pentobarbital effects. Direct application of pentobarbital (5 X 10(-4)M) to slices in vitro also caused a 20-40% reduction of [3H]-choline uptake of cerebral cortex, hippocampus and diencephalon. A concomitant application of TRH(10(-4)M) or DN-1417(10(-5)M) and pentobarbital abolished the pentobarbital effect. These results provide neurochemical evidence that the antagonistic effects of TRH and DN-1417 on pentobarbital-induced narcosis are closely related to alterations in the rat brain choline uptake and acetylcholine synthesis, which are considered to be measures of the activity of cholinergic neurons.     

Distribution and characterization of cyclo (His-Pro)-like immunoreactivity in anuran (frog) skins

The distribution of cyclo (His-Pro)-like immunoreactivity in frog skins from seven frog species was examined. The chromatographic elution profile of cyclo (His-Pro)-like immunoreactivity in amphibian skins measured by radioimmunoassay corresponded precisely to that of [³H-Pro]-cyclo (His-Pro) after DEAE-Cellulose, Sephadex G-25 and high-pressure liquid chromatography. The concentrations of cyclo (His-Pro) in frog skins were much higher than the concentrations of TRH previously observed in skin and the concentrations of cyclo (His-Pro) in both brain and gastrointestinal tract.     

Distribution and characterization of cyclo(His-Pro)-like immunoreactivity in the rat gastrointestinal tract

The distribution of cyclo(His-Pro), thyrotropin-releasing hormone (TRH) and $\text{pyroglutamate aminopeptidase}$ activity was examined in the rat gastrointestinal (GI) tract. Cyclo(His-Pro)-like immunoreactivity was present in the following order of distribution (fmoles/mg protein): caecum > colon = jejunum = ileum > stomach = duodenum = rectum, and was immunologically and chromatographically identical with the authentic cyclo(His-Pro). Cyclo(His-Pro) concentrations showed significantly positive correlations with TRH concentrations, but not with $\text{pyroglutamate aminopeptidase}$ activities, in most tissues of the GI tract, suggesting a precursor role of TRH for gut cyclo(His-Pro). These data suggest that cyclo(His-Pro) may be involved in regulating rat GI functions.     

Involvement of thyrotropin-releasing hormone (TRH) neural system of the brain in pentylenetetrazol-induced seizures

In order to study the relationship between pentylenetetrazol (PTZ)-induced seizures and the thyrotropin-releasing hormone (TRH) neural system, immunoreactive TRH (IR-TRH) and TRH receptor binding activity were determined in discrete regions of the rat brain before as well as 40 s (immediately before seizures), 150 s (during seizures) and 24 h after an intraperitoneal injection of PTZ (75 mg/kg). IR-TRH markedly increased in the septum 40 and 150 s after the injection, and also in the hippocampus and the thalamus-midbrain region 40 and 150 s after the injection, respectively. However, no significant changes were observed in the TRH receptor binding before, during or after the seizures, suggesting that the increased IR-TRH was not released into the synaptic cleft. This speculation was supported by the dose-dependent inhibition of PTZ-induced generalized seizures by the pre-treatment with TRH or its analogue DN-1417 into the cerebral ventricle.     

[3H]cyclo(Histidyl-Proline) in rat tissues: Distribution,clearance and binding

Cyclo(Histidyl-Proline), a metabolite of TRH, has been demonstrated to have a number of biological activities. The clearance, distribution and binding of the peptide in the rat was studied. Cyclo(His-Pro) was cleared from the circulation biphasically ($\text{tl}\text{2}\text{= 1.25 and 33 min}$). Unmetabolized cyclo(His-Pro) appeared rapidly in urine. Accumulation of [³H]cyclo(His-Pro) in adrenal, liver and kidney was demonstrated. Membrane preparations from adrenal and liver, but not from kidney, brain, pituitary, and other tissues were shown to bind cyclo(His-Pro) specifically.     

Various Types of Thyrotropin-Releasing Hormone Receptors in Discrete Brain Regions and the Pituitary of the Rat

Receptors for thyrotropin-releasing hormone (TRH) in the rat brain and the pituitary are heterogenous. The receptors were classified into four types according to the dissociation constant (KD). High-affinity receptors (KD less than 3 nM) are present in the pituitary, hypothalamus, amygdala, and limbic forebrain which contains the nucleus accumbens and the septum. Intermediate-affinity receptors (KD, 5-16 nM) are evidently present in the frontal cortex, hippocampus, striatum, thalamus, and the brainstem, but may also be present in other regions. Low-affinity TRH receptors (KD, 50-80 nM) are seen in the limbic forebrain, amygdala, and the hypothalamus. Very-low-affinity receptors (KD, 215 nM) exist in the pituitary. Experiments using DN-1417 (gamma-butyrolactone-gamma-carbonyl-histidyl-prolinamide citrate), a synthetic TRH analogue with a more potent central activity, indicated the presence of TRH receptors having a high affinity to DN-1417 at least in the limbic forebrain but not in the pituitary. This type of receptor is not labeled by [3H](3-methyl-histidine2)-TRH. Density of the TRH receptor is the highest in the pituitary and next highest in the amygdala.     

Influences of maternal caffeine on the neonatal rat brains vary with the nutritional states

The potential effect of maternal caffeine ingestion upon total brain protein and the concentration of two prototype neuropeptides, thyrotropin-releasing hormone (TRH) and its derivative, cyclo (His-Pro) in neonates was examined during the nursing period in the context of variable maternal protein intake. Maternal caffeine intake (2 mg/100 g body weight) significantly increased the total brain protein of neonates derived from dams fed a 6% casein diet, but not from dams fed a 12%- or 20%-casein diet. Maternal caffeine consumption significantly increased the amount of cyclo (His-Pro) in the neonatal brains in all groups. The percent increments in pups from dams fed 6%, 12%, and 20% casein diets were respectively 137%, 131%, and 120%. By contrast, no significant alterations were observed in TRH concentrations between caffeine and control groups. It is concluded that maternal caffeine can influence neonatal brain protein and cyclo (His-Pro) during nursing under conditions of protein-energy malnutrition.     

Protein-energy malnutrition during pregnancy alters caffeine's effect on brain tissue of neonate rats

We studied whether protein-energy malnutrition changed brain susceptibility to a small dose of caffeine in newborn rats. Since we had demonstrated previously that caffeine intake during lactation increased the brain neuropeptide on newborns, we investigated further the effects of the prenatal administration of caffeine on TRH and cyclo (His-Pro). From day 13 of gestation to delivery day, pregnant rats in one group were fed either a 20% or a 6% protein diet ad libitum, and those in the other group were pair-fed with each protein diet supplemented with caffeine at an effective dose of 2 mg/100 g body weight. Upon delivery, brain weight, brain protein, RNA, DNA and the neuropeptides thyrotropin-releasing hormone (TRH) and cyclo (His-Pro) were measured in the newborn rats. A 6% protein without caffeine diet caused reductions in brain weights and brain protein, RNA and DNA contents, but did not alter brain TRH and cyclo (His-Pro) concentrations in the newborn animals. In the offspring from dams fed a 6% protein diet, caffeine administration significantly elevated brain weights and brain contents of protein, RNA and DNA. In contrast, these values were similar between noncaffeine and caffeine-supplemented animals in a 20% protein diet group. Brain TRH and cyclo (His-Pro) concentrations were not changed by caffeine administration. These data suggest that caffeine augments protein synthesis in the newborn rat brain when malnourished, but that the same dose of caffeine did not affect protein synthesis in brains of newborn rats from normally nourished dams. Therefore, the present findings indicate that the nutritional status of mothers during pregnancy has important implication in the impact of caffeine on their offspring's brains.     

Valproate modulates TRH receptor, TRH and TRH-like peptide levels in rat brain

We have tested our hypothesis that alterations in the levels of TRH receptors, and the synthesis and release of tripeptide TRH, and other neurotropic TRH-like peptides mediate some of the mood stabilizing effects of valproate (Valp). We have directly compared the effect of 1 week of feeding two major mood stabilizers, Valp and lithium chloride (LiCl) on TRH binding in limbic and extra-limbic regions of male WKY rats. Valp increased TRH receptor levels in nucleus accumbens and frontal cortex. Li increased TRH receptor binding in amygdala, posterior cortex and cerebellum. The acute, chronic and withdrawal effects of Valp on brain levels of TRH (pGlu-His-Pro-NH2, His-TRH) and five other TRH-like peptides, Glu-TRH, Val-TRH, Tyr-TRH, Leu-TRH and Phe-TRH were measured by combined HPLC and RIA. Acute treatment increased TRH and TRH-like peptide levels within most brain regions, most strikingly in pyriform cortex. The fold increases (in parentheses) were: Val-TRH (58), Phe-TRH (54), Tyr-TRH (25), TRH (9), Glu-TRH (4) and Leu-TRH (3). We conclude that the mood stabilizing effects of Valp may be due, at least in part, to its ability to alter TRH and TRH-like peptide, and TRH receptor levels in the limbic system and other brain regions implicated in mood regulation and behavior.     

Potential anti-depressive effects of thyrotropin releasing hormone (TRH) and its analogues

The anti-depressive effects of thyrotropin releasing hormone (TRH) and its analogues (DN-1417: gamma-butyrolactone-gamma-carbonyl-histidyl-prolinamide citrate; MK-771: L-pyro-2-aminoadipyl-histidyl-thiazolidine-4-carboxamide) were examined in behavioral despair rats, an animal model of depression. TRH, DN-1417, MK-771, amitriptyline and diazepam were injected three times after the first forced swimming. One hr after the last injection, a 5-min swimming test was performed. Experimental animals were placed in a Hall's type open-field apparatus immediately before and after the 5-min test, and their locomotor activities were determined. No significant difference was noted in the locomotor activity immediately before the 5-min test among any group. In the 5-min swimming test, TRH, DN-1417 and MK-771 caused a dose-dependent decrease in immobility, showing an anti-depressive effect similar to amitriptyline. Diazepam showed no difference compared with the control group. After the swimming test, locomotor activity remarkably decreased in the control rats, while decreased locomotor activity was partially prevented in the TRH, DN-1417, MK-771 and amitriptyline treated rats which exhibited active movement not only during the swimming period but also after it. In terms of the minimum effective dose, TRH and DN-1417 seemed to be of similar potency, while MK-771 was 40-fold stronger than TRH. An examination of a possible correlation between the cross-reactivity of TRH analogues in a radioreceptor assay and the effects of the analogues on despair rats suggested that the structure-binding relationship was proportional to the structure-activity relationship.     

Effect of TRH analog (DN-1417) on tyrosine hydroxylase activity in mesocortical, mesolimbic and nigrostriatal dopaminergic neurons of rat brain

Tyrosine hydroxylase (TH) was assayed in eight regions of rat brain following repeated treatment with a TRH analog, DN-1417 (gamma-butyrolactone-gamma-carbonyl-histidyl-prolinamide). Repeated DN-1417 treatment (20 mg/kg/day, IP) for 7 days increased TH activity in the ventral tegmental area and decreased in the prefrontal cortex polar, medial and lateral fields and olfactory tubercles. No significant change in TH activity was found in the nucleus accumbens, striatum and substantia nigra. Kinetic analysis showed that the increased TH activity in the ventral tegmental area was due to an increase in Vmax, but not a change in the apparent Km of TH for a cofactor, 6-methyl-tetrahydropteridine. When TH was assayed at a suboptimal pH and in the presence of a subsaturating cofactor, the striatal TH was activated significantly after DN-1417. In the prefrontal cortex medial field, nucleus accumbens and olfactory tubercles, TH activity assayed under the suboptimal condition was not modified by DN-1417 treatment. These results suggest an intimate involvement of central dopaminergic systems in the actions of DN-1417.